{"id":46646,"date":"2020-08-17T18:00:15","date_gmt":"2020-08-17T18:00:15","guid":{"rendered":"https:\/\/lnbr.cnpem.br\/?page_id=46646"},"modified":"2024-02-08T19:13:53","modified_gmt":"2024-02-08T19:13:53","slug":"research-highlights","status":"publish","type":"page","link":"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/","title":{"rendered":"LNBR | Research Highlights"},"content":{"rendered":"<section class=\"wpb-content-wrapper\"><p>[vc_row][vc_column width=&#8221;3\/4&#8243;][vc_row_inner][vc_column_inner][vc_column_text]<\/p>\n<p style=\"text-align: justify;\">Selected highlights of scientific publications, technology developments and partnerships.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1594988184275{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-430c7367294abca03eb3009980ba23bb.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-430c7367294abca03eb3009980ba23bb.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-430c7367294abca03eb3009980ba23bb .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-430c7367294abca03eb3009980ba23bb .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-430c7367294abca03eb3009980ba23bb alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/doi-org.ez106.periodicos.capes.gov.br\/10.1016\/j.cej.2023.148462\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img fetchpriority=\"high\" decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2024\/02\/Chemical-Engineering-Journal-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2024\/02\/Chemical-Engineering-Journal-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2024\/02\/Chemical-Engineering-Journal.jpg 576w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/chemical-engineering-journal-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/doi-org.ez106.periodicos.capes.gov.br\/10.1016\/j.cej.2023.148462\" target=\"_blank\" rel=\"noopener\"><span style=\"font-size: 12pt;\"><strong>A systematic multicriteria-based approach to support product portfolio selection in microalgae biorefineries<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>FEB-2024 <\/strong>Sustainability assessments of a supply chain can be complex. This study proposed a methodology for selecting products and biorefinery configurations, integrating technical, economic and environmental criteria in the decision-making process. As a case study, it selected portfolios of products derived from microalgae. Succinic, citric and acrylic acids were listed as the main bioproducts derived from carbohydrates. In addition, different combinations of strains and cultivation conditions were identified.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1618228239125{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-2df9afa747f99150add33743b31460be.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-2df9afa747f99150add33743b31460be.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-2df9afa747f99150add33743b31460be .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-2df9afa747f99150add33743b31460be .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-2df9afa747f99150add33743b31460be alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/journals.asm.org\/doi\/10.1128\/spectrum.02280-23\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20165%20165&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2024\/01\/microbiology-spectrum.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2024\/01\/microbiology-spectrum.jpg 165w\" loading=\"eager\" style=\"--ratio: 165 \/ 165\" sizes=\"(max-width: 165px) 100vw, 165px\" width=\"165\" height=\"165\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/microbiology-spectrum-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/journals.asm.org\/doi\/10.1128\/spectrum.02280-23\" target=\"_blank\" rel=\"noopener\"><span style=\"font-size: 12pt;\"><strong>Plant structural and storage glucans trigger distinct transcriptional responses that modulate the motility of Xanthomonas pathogens<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>NOV-2023 <\/strong><em>Xanthomonas<\/em> bacteria are pathogenic to a variety of relevant crops and possess a vast repertoire of carbohydrate-active enzymes (CAZymes) of potential industrial use. This study investigated how different plant carbohydrates regulate the motility of this bacterium, which may have implications for the infection process of the host plant. We also investigated enzymes used to release glucose from cellulose and starch, providing inspiration for the development of industrial enzyme cocktails.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1594988184275{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-ec20a68f59fffc45ea7a5e395d376216.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-ec20a68f59fffc45ea7a5e395d376216.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-ec20a68f59fffc45ea7a5e395d376216 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-ec20a68f59fffc45ea7a5e395d376216 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-ec20a68f59fffc45ea7a5e395d376216 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/doi.org\/10.1016\/j.jclepro.2023.138586\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/08\/Journal-Cleaner-prod-novo-1-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/08\/Journal-Cleaner-prod-novo-1-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/08\/Journal-Cleaner-prod-novo-1.jpg 576w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/journal-cleaner-prod-novo-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/doi.org\/10.1016\/j.jclepro.2023.138586\"><span style=\"font-size: 12pt;\"><strong>Bioenergy-livestock integration in Brazil: Unraveling potentials for energy production and climate change mitigation<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>OCT-2023 <\/strong>Meeting future food and energy demands while reducing greenhouse gas (GHG) emissions is a challenge. This paper explores the spatially explicit potentials to produce food and energy in Brazil by expanding bioenergy-livestock integrated systems under land use restrictions. Integrated systems can co-produce food, feed and energy using less land than conventional systems. There is great potential to mitigate GHG emissions profitably while preserving biomes and biodiversity.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1618228239125{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-6647b4f29df7188bdb3da2ee213504d2.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-6647b4f29df7188bdb3da2ee213504d2.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-6647b4f29df7188bdb3da2ee213504d2 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-6647b4f29df7188bdb3da2ee213504d2 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-6647b4f29df7188bdb3da2ee213504d2 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/doi.org\/10.1016\/j.cej.2023.143878\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/07\/CEJ-CHEMICAL-ENGINEERING-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/07\/CEJ-CHEMICAL-ENGINEERING-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/07\/CEJ-CHEMICAL-ENGINEERING.jpg 576w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/cej-chemical-engineering-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/doi.org\/10.1016\/j.cej.2023.143878\"><span style=\"font-size: 12pt;\"><strong>From enzyme to cell-factory: Economic and environmental assessment of biobased pathways to unlock the potential of long-haul transportation biofuels<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>JUL-2023 <\/strong>Biobased pathways are a promising alternative for the decarbonization of the long-haul transportation sector. This study evaluated the techno-economic and environmental impacts of Biobased pathways to obtain long-haul biofuels (hydrocarbons), aiming to identify opportunities for metabolic engineering. The results demonstrated that these pathways can reduce greenhouse gas emissions by up to 70%, at a competitive cost compared to fossil fuels.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1594988184275{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-f916a2129e615582d504ad53fb961288.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-f916a2129e615582d504ad53fb961288.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-f916a2129e615582d504ad53fb961288 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-f916a2129e615582d504ad53fb961288 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-f916a2129e615582d504ad53fb961288 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/doi.org\/10.1073\/pnas.2221483120\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/07\/pnas-120-22-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/07\/pnas-120-22-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/07\/pnas-120-22.jpg 807w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/pnas-120-22-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"http:\/\/dx.doi.org\/10.1016\/j.indcrop.2022.115993\"><span style=\"font-size: 12pt;\"><strong>Dimer-assisted mechanism of (un)saturated fatty acid decarboxylation for alkene production<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>JUL-2023 <\/strong>Alkene is an important chemical intermediate corresponding approximately to 70% of the petrochemicals sector. This work reports the discovery of the enzyme &#8220;OleTPRN&#8221; able to convert fatty acids of vegetal origin into alkenes. The identified enzyme opens a range of opportunities due to its compatibility with industrially relevant microorganisms and because it enables the use of a wide range of raw materials such as the ones rich in oleic acid, one of the most abundant fatty acids in nature.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1618228239125{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-46c05aa4b77a86475451d30c94426726.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-46c05aa4b77a86475451d30c94426726.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-46c05aa4b77a86475451d30c94426726 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-46c05aa4b77a86475451d30c94426726 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-46c05aa4b77a86475451d30c94426726 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"http:\/\/dx.doi.org\/10.1016\/j.cbpa.2023.102282\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/06\/CURRENT-OPINION-CHEM-BIO-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/06\/CURRENT-OPINION-CHEM-BIO-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/06\/CURRENT-OPINION-CHEM-BIO.jpg 592w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/current-opinion-chem-bio-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"http:\/\/dx.doi.org\/10.1016\/j.cbpa.2023.102282\"><span style=\"font-size: 12pt;\"><strong>Glycosidase mechanisms: Sugar conformations and reactivity in endo- and exo-acting enzymes<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>JUN-2023 <\/strong>Glycoside hydrolases are crucial enzymes for the depolymerization of complex polysaccharides and play a fundamental role in a myriad of biological and biotechnological processes involving plant biomass. In this work, we used computer simulations to determine how the topology of the active site and the mode of action influence the catalytic routes adopted by this class of enzymes, guiding the rational use of these biocatalysts for industrial processes.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1594988184275{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-b2d34050657c376757d8c87fe1fa9b24.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-b2d34050657c376757d8c87fe1fa9b24.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-b2d34050657c376757d8c87fe1fa9b24 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-b2d34050657c376757d8c87fe1fa9b24 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-b2d34050657c376757d8c87fe1fa9b24 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"http:\/\/dx.doi.org\/10.1016\/j.indcrop.2022.115993\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/06\/Industrial-Crops-and-Products-cover-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/06\/Industrial-Crops-and-Products-cover-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/06\/Industrial-Crops-and-Products-cover.jpg 576w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/industrial-crops-and-products-cover-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"http:\/\/dx.doi.org\/10.1016\/j.indcrop.2022.115993\"><span style=\"font-size: 12pt;\"><strong>Biomass yield, nutrient removal, and chemical composition of energy cane genotypes in Southeast Brazil<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>JUN-2023 <\/strong>Energy cane has been considered a promising crop for bioenergy production. However, there is limited information about this biomass&#8217;s potential production and chemical composition. In this study, it was observed that, compared to sugarcane, energy cane presents higher dry biomass yield (~25%), higher fiber (~40%), lower sucrose (~60%), lower extractives in stalks (~50%) and also uptake higher amounts of nutrients from the soil.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1618228239125{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-8972965aec13ecb9b56a85470136e814.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-8972965aec13ecb9b56a85470136e814.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-8972965aec13ecb9b56a85470136e814 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-8972965aec13ecb9b56a85470136e814 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-8972965aec13ecb9b56a85470136e814 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"http:\/\/dx.doi.org\/10.1042\/EBC20220128\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/05\/essays-in-biochemistry-500x500.png\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/05\/essays-in-biochemistry-500x500.png 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/05\/essays-in-biochemistry.png 520w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/essays-in-biochemistry-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"http:\/\/dx.doi.org\/10.1042\/EBC20220128\"><span style=\"font-size: 12pt;\"><strong>Enzymatic systems for carbohydrate utilization and biosynthesis in Xanthomonas and their role in pathogenesis and tissue specificity<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>MAY-2023 <\/strong><em>Xanthomonas<\/em> are bacteria that cause diseases in several agricultural crops important for global food security and possess a rich repertoire of enzymes of great biotechnological interest, either for the saccharification of lignocellulosic biomass as well as for the synthesis of natural emulsifiers such as xanthan gum. This review article describes the current knowledge about the enzymatic systems used by these bacteria to depolymerize and assimilate plant polysaccharides and to produce exopolysaccharides such as xanthan gum, highlighting where is the frontier of knowledge within this theme.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1594988184275{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-f5703973e8f10ee28b9ff9857914b0ac.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-f5703973e8f10ee28b9ff9857914b0ac.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-f5703973e8f10ee28b9ff9857914b0ac .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-f5703973e8f10ee28b9ff9857914b0ac .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-f5703973e8f10ee28b9ff9857914b0ac alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"http:\/\/dx.doi.org\/10.1016\/j.enconman.2022.116547\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/05\/energy-conversion-management-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/05\/energy-conversion-management-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/05\/energy-conversion-management.jpg 576w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/energy-conversion-management-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"http:\/\/dx.doi.org\/10.1016\/j.enconman.2022.116547\"><span style=\"font-size: 12pt;\"><strong>Decentralization of sustainable aviation fuel production in Brazil through Biomass-to-Liquids routes: A techno-economic and environmental evaluation<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>MAY-2023 <\/strong>By 2040 it is expected that at least 50% of the fuel used in aviation will be sustainable. The present work aims at evaluating the production of Sustainable Aviation Fuel through the gasification and Fischer-Tropsch route, by considering the main possible implementation strategies in the Brazilian sugarcane industry. The results provide insight into scenarios in which biofuels could compete and substitute fossil aviation kerosene.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1618228239125{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-960293fc38277c39fea0ed43a6e6b4f8.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-960293fc38277c39fea0ed43a6e6b4f8.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-960293fc38277c39fea0ed43a6e6b4f8 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-960293fc38277c39fea0ed43a6e6b4f8 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-960293fc38277c39fea0ed43a6e6b4f8 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"http:\/\/dx.doi.org\/10.3389\/fpls.2022.1056082\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20221%20221&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/05\/Frontiers-in-Plant-Science.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/05\/Frontiers-in-Plant-Science.jpg 221w\" loading=\"eager\" style=\"--ratio: 221 \/ 221\" sizes=\"(max-width: 221px) 100vw, 221px\" width=\"221\" height=\"221\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/frontiers-in-plant-science-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"http:\/\/dx.doi.org\/10.3389\/fpls.2022.1056082\"><span style=\"font-size: 12pt;\"><strong>Bacterial volatile organic compounds (VOCs) promote growth and induce metabolic changes in rice<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>MAY-2023 <\/strong>Agrochemicals used in crops are usually derived from non-renewable sources and can cause several environmental impacts. An environmentally friendly strategy is the use of microbial bioactive molecules. For the first time, this article shows the growth promotion of rice by bacterial volatile molecules. In addition, several metabolic pathways were identified as potentially modulate by these molecules. These results can help in the development of bioproducts aiming a more sustainable agriculture.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1594988184275{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-5770b7047d805f2ccce9b597b0f2641b.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-5770b7047d805f2ccce9b597b0f2641b.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-5770b7047d805f2ccce9b597b0f2641b .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-5770b7047d805f2ccce9b597b0f2641b .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-5770b7047d805f2ccce9b597b0f2641b alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"http:\/\/dx.doi.org\/10.1063\/5.0129324\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/05\/APPLIED-PHYSICS-REVIEW-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/05\/APPLIED-PHYSICS-REVIEW-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/05\/APPLIED-PHYSICS-REVIEW-1000x1000.jpg 1000w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/applied-physics-review\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"http:\/\/dx.doi.org\/10.1063\/5.0129324\"><span style=\"font-size: 12pt;\"><strong>From micro- to nano- and time-resolved x-ray computed tomography: Bio-based applications, synchrotron capabilities, and data-driven processing<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>MAY-2023 <\/strong>X-ray computed tomography is a versatile non-destructive technique that has been used extensively to investigate bio-based systems in multiple application areas. This review article presents applications of X-ray tomography to bio-based systems, synchrotron capabilities that are enabling nanotomography and time-resolved experiments, and the computational challenges and techniques that arise from the deluge of data generated in modern tomography beamlines.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1618228239125{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-843c9b02be2250e39d4535e7aff9e5ba.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-843c9b02be2250e39d4535e7aff9e5ba.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-843c9b02be2250e39d4535e7aff9e5ba .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-843c9b02be2250e39d4535e7aff9e5ba .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-843c9b02be2250e39d4535e7aff9e5ba alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"http:\/\/dx.doi.org\/10.1016\/j.fuel.2023.127796\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/05\/fuel-elsevier-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/05\/fuel-elsevier-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/05\/fuel-elsevier.jpg 576w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/fuel-elsevier\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"http:\/\/dx.doi.org\/10.1016\/j.fuel.2023.127796\"><span style=\"font-size: 12pt;\"><strong>Depolymerization of enzymatic hydrolysis lignin: Review of technologies and opportunities for research<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>MAY-2023 <\/strong>The advance of cellulosic ethanol, based on the enzymatic hydrolysis of cellulose, generates large volumes of lignin-rich residue. In this review article, enzymatic hydrolysis lignin is presented as a renewable feedstock with unique characteristics of cost, availability, transportability, purity, and reactivity. The depolymerization of this type of lignin opens opportunities for obtaining biochars, biochemicals, and liquid biofuels in a new platform of biorenewables.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1594988184275{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-7d307f43245e3aee2095cfc58016e755.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-7d307f43245e3aee2095cfc58016e755.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-7d307f43245e3aee2095cfc58016e755 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-7d307f43245e3aee2095cfc58016e755 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-7d307f43245e3aee2095cfc58016e755 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"http:\/\/dx.doi.org\/10.1038\/s41589-022-01202-4\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20440%20440&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/05\/NATURE-CHEM-BIO.png\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/05\/NATURE-CHEM-BIO.png 440w\" loading=\"eager\" style=\"--ratio: 440 \/ 440\" sizes=\"(max-width: 440px) 100vw, 440px\" width=\"440\" height=\"440\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/nature-chem-bio-3\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"http:\/\/dx.doi.org\/10.1038\/s41589-022-01202-4\"><span style=\"font-size: 12pt;\"><strong>Mechanism of high-mannose N-glycan breakdown and metabolism by Bifidobacterium longum<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>MAY-2023 <\/strong>This work elucidated key molecular mechanisms employed by bifidobacteria to feed on high-mannose N-glycans, complex carbohydrates found in glycoproteins from our intestinal lumen. Bifidobacteria are early colonizers of the human gut and this study expanded our knowledge on how they use complex carbohydrates as nutrients to survive in a competitive niche, bringing benefits to our health and inspiration for the development of new enzyme-based technologies.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1618228239125{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-527f9d6638eb574c1b7bd8c4bdd1930a.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-527f9d6638eb574c1b7bd8c4bdd1930a.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-527f9d6638eb574c1b7bd8c4bdd1930a .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-527f9d6638eb574c1b7bd8c4bdd1930a .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-527f9d6638eb574c1b7bd8c4bdd1930a alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"http:\/\/dx.doi.org\/10.3389\/fmicb.2022.951130\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20290%20290&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/05\/frontiers-in-microbiology.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/05\/frontiers-in-microbiology.jpg 290w\" loading=\"eager\" style=\"--ratio: 290 \/ 290\" sizes=\"(max-width: 290px) 100vw, 290px\" width=\"290\" height=\"290\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/frontiers-in-microbiology\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"http:\/\/dx.doi.org\/10.3389\/fmicb.2022.951130\"><span style=\"font-size: 12pt;\"><strong>The power of the smallest: The inhibitory activity of microbial volatile organic compounds against phytopathogens<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>MAY-2023 <\/strong>Agrochemicals used in crops are usually derived from non-renewable sources and can cause several environmental impacts. An environmentally friendly strategy is the use of bioactive molecules produced by microorganisms. This review demonstrates how some of these molecules can inhibit the growth of different phytopathogens, both in vitro and in vivo. In addition, their mechanisms of action are described, as well as some bottlenecks for the development of biological products based on these molecules.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1594988184275{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-fc925ddfd435aaa2b73a75097cea08d9.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-fc925ddfd435aaa2b73a75097cea08d9.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-fc925ddfd435aaa2b73a75097cea08d9 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-fc925ddfd435aaa2b73a75097cea08d9 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-fc925ddfd435aaa2b73a75097cea08d9 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/doi.org\/10.1016\/j.indcrop.2022.115132\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/01\/industrial-crops-products-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/01\/industrial-crops-products-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/01\/industrial-crops-products.jpg 574w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/industrial-crops-products-2-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/doi.org\/10.1016\/j.indcrop.2022.115132\"><span style=\"font-size: 12pt;\"><strong>Fate of silica phytoliths in the industrial crushing of sugarcane stalks<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>JAN-2023 <\/strong>Grasses such as sugarcane contain rigid and microscopic structures of biogenic silica (phytoliths) in their composition. This work employed imaging, fractionation, and ashing techniques to determine the fate of phytoliths in the industrial crushing of sugarcane stalks. The results show different degrees of disruption and integrity of plant tissues and phytoliths, contributing to the understanding of potential interferences in bagasse conversion processes and the potential for obtaining silica bioproducts.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1618228239125{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-6af924a1a2c5b64b69cd371412438e91.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-6af924a1a2c5b64b69cd371412438e91.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-6af924a1a2c5b64b69cd371412438e91 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-6af924a1a2c5b64b69cd371412438e91 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-6af924a1a2c5b64b69cd371412438e91 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"http:\/\/dx.doi.org\/10.1039\/d2nr05541d\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/01\/NANOSCALE-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/01\/NANOSCALE-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/01\/NANOSCALE.jpg 899w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/nanoscale-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"http:\/\/dx.doi.org\/10.1039\/d2nr05541d\"><span style=\"font-size: 12pt;\"><strong>How lignin sticks to cellulose\u2014insights from atomic force microscopy enhanced by machine-learning analysis and molecular dynamics simulations<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>JAN-2023 <\/strong>Interactions between cellulose and lignin are key to transforming biomass into biorenewables. This work developed a new approach to investigate the forces between cellulose and lignin, using atomic force microscopy, analysis of force-distance curves with machine learning techniques, and molecular dynamics simulations. The results allow proposing new strategies to destabilize the interactions and improve the separation of cellulose and lignin.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1618228239125{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-1ff7d627c484bad8397f83a8b4bbf3cf.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-1ff7d627c484bad8397f83a8b4bbf3cf.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-1ff7d627c484bad8397f83a8b4bbf3cf .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-1ff7d627c484bad8397f83a8b4bbf3cf .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-1ff7d627c484bad8397f83a8b4bbf3cf alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/scripts.iucr.org\/cgi-bin\/paper?S2059798322009561\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/01\/Acta-Crystallographica-Section-D-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/01\/Acta-Crystallographica-Section-D-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/01\/Acta-Crystallographica-Section-D.jpg 594w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/c131100-0-0-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/scripts.iucr.org\/cgi-bin\/paper?S2059798322009561\"><span style=\"font-size: 12pt;\"><strong>Glycoside hydrolase subfamily GH5_57 features a highly redesigned catalytic interface to process complex hetero-\u03b2-mannans<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>DEC-2022 <\/strong>Glycoside hydrolases (GH) are the main class of enzymes responsible for the depolymerization of the plant cell wall. In this study, the three-dimensional structure of a new enzyme, along with biochemical assays and phylogenetic analysis, enabled the establishment of a novel GH subfamily, the GH5_57. This finding opens new perspectives for the processing of an important carbohydrate by mannanases, enzymes that have several industrial applications.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1594988184275{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-bd894697e104eea7369c31f79e6e72ec.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-bd894697e104eea7369c31f79e6e72ec.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-bd894697e104eea7369c31f79e6e72ec .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-bd894697e104eea7369c31f79e6e72ec .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-bd894697e104eea7369c31f79e6e72ec alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"http:\/\/dx.doi.org\/10.1016\/j.ijbiomac.2022.10.269\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/01\/International-Journal-of-Biological-Macromolecules-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/01\/International-Journal-of-Biological-Macromolecules-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2023\/01\/International-Journal-of-Biological-Macromolecules.jpg 574w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/international-journal-of-biological-macromolecules\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/www.sciencedirect.com\/science\/article\/abs\/pii\/S0141813022025247?via%3Dihub\" target=\"_blank\" rel=\"noopener\"><span style=\"font-size: 12pt;\"><strong>Exploring the compatibility between hydrothermal depolymerization of alkaline lignin from sugarcane bagasse and metabolization of the aromatics by bacteria<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>DEC-2022 <\/strong>Lignin is an aromatic macromolecule with potential for biorenewable chemicals production. In this work, sugarcane bagasse lignin was processed under hydrothermal conditions. A resulting bio-oil, rich in aromatic monomers, promoted the growth of bacteria from 9 species, with highlight to Pseudomonas sp. LIM05 and Burkholderia sp. LIM09. These results show a promising strategy for integration between hydrothermal process and bioconversion for lignin valorization.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1618228239125{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-f8d0dcd03b19f640a1d187ad039fae99.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-f8d0dcd03b19f640a1d187ad039fae99.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-f8d0dcd03b19f640a1d187ad039fae99 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-f8d0dcd03b19f640a1d187ad039fae99 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-f8d0dcd03b19f640a1d187ad039fae99 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/www.nature.com\/articles\/s41589-022-01202-4\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20440%20440&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/12\/nature-chem-bio-18-1.png\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/12\/nature-chem-bio-18-1.png 440w\" loading=\"eager\" style=\"--ratio: 440 \/ 440\" sizes=\"(max-width: 440px) 100vw, 440px\" width=\"440\" height=\"440\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/nature-chem-bio-18-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/www.nature.com\/articles\/s41589-022-01202-4\"><span style=\"font-size: 12pt;\"><strong>Mechanism of high-mannose <em>N<\/em>-glycan breakdown and metabolism by <em>Bifidobacterium longum<\/em><\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>DEC-2022 <\/strong>This work elucidated key molecular mechanisms employed by bifidobacteria to feed on high-mannose N-glycans, complex carbohydrates found in glycoproteins from our intestinal lumen. Bifidobacteria are early colonizers of the human gut and this study expanded our knowledge on how they use complex carbohydrates as nutrients to survive in a competitive niche, bringing benefits to our health and inspiration for the development of new enzyme-based technologies.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1594988184275{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-96a1018a0aba22cf6112185a61113886.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-96a1018a0aba22cf6112185a61113886.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-96a1018a0aba22cf6112185a61113886 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-96a1018a0aba22cf6112185a61113886 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-96a1018a0aba22cf6112185a61113886 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/www.sciencedirect.com\/science\/article\/abs\/pii\/S0960852422013529?via%3Dihub\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/12\/Bioresource-Technology-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/12\/Bioresource-Technology-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/12\/Bioresource-Technology.jpg 574w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/bioresource-technology-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/www.sciencedirect.com\/science\/article\/abs\/pii\/S0960852422013529?via%3Dihub\"><span style=\"font-size: 12pt;\"><strong>Development of an economically competitive <em>Trichoderma<\/em>-based platform for enzyme production: Bioprocess optimization, pilot plant scale-up, techno-economic analysis and life cycle assessment<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>DEC-2022 <\/strong>The enzymatic cocktail for the saccharification of sugarcane bagasse is crucial for the viability of cellulosic ethanol. Therefore, the optimization of the main operational parameters for growth and enzyme production on bench and pilot scale was performed using the fungal strain previously developed by LNBR\/CNPEM. The assessment results showed that the platform is economically and environmentally competitive in comparison with literature and commercial alternatives.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1618228239125{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-91ffd48a5edebf06674fbfde0c66d90f.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-91ffd48a5edebf06674fbfde0c66d90f.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-91ffd48a5edebf06674fbfde0c66d90f .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-91ffd48a5edebf06674fbfde0c66d90f .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-91ffd48a5edebf06674fbfde0c66d90f alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/www-sciencedirect.ez106.periodicos.capes.gov.br\/science\/article\/pii\/S0921344922005572\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/11\/Resources-Conservation-and-Recycling-2-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/11\/Resources-Conservation-and-Recycling-2-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/11\/Resources-Conservation-and-Recycling-2-1000x1000.jpg 1000w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/resources-conservation-and-recycling-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/www-sciencedirect.ez106.periodicos.capes.gov.br\/science\/article\/pii\/S0921344922005572\"><span style=\"font-size: 12pt;\"><strong>Integrating carbon footprint to spatialized modeling: The mitigation potential of sugarcane ethanol production in the Brazilian Center-South<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>NOV-2022 <\/strong>This study demonstrates the use of an economic and environmental impact assessment platform, developed at CNPEM, which considers regional aspects in ethanol production, revealing potential environmental gains and revenue from Decarbonization Credits (CBIOS). The proposed georeferenced framework showed significant spatial variations that should be accounted for in future assessments in order to ensure the production of bio-renewables in a sustainable way.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1594988184275{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-aad4dd98a70e20c87e90e089076324af.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-aad4dd98a70e20c87e90e089076324af.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-aad4dd98a70e20c87e90e089076324af .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-aad4dd98a70e20c87e90e089076324af .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-aad4dd98a70e20c87e90e089076324af alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/www.nature.com\/articles\/s41929-022-00823-1\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20439%20439&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/11\/nature-catalysis.png\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/11\/nature-catalysis.png 439w\" loading=\"eager\" style=\"--ratio: 439 \/ 439\" sizes=\"(max-width: 439px) 100vw, 439px\" width=\"439\" height=\"439\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/nature-catalysis\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/www.nature.com\/articles\/s41929-022-00823-1\"><span style=\"font-size: 12pt;\"><strong>Site-selective proteolytic cleavage of plant viruses by photoactive chiral nanoparticles<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>NOV-2022 <\/strong>Chiral nanoparticles can be used to reduce crop losses caused by tobacco mosaic virus with reduced environmental impacts when compared to common pesticides. The chemical developed is practically innocuous for the plant and the environment. This work proposes that it is possible to fight diseases specifically and efficiently by controlling the size and chirality of nanomaterials through their functionalization with chiral organic molecules.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1618228239125{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-1f9b4581d8b0a27c343026b52a15ece5.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-1f9b4581d8b0a27c343026b52a15ece5.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-1f9b4581d8b0a27c343026b52a15ece5 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-1f9b4581d8b0a27c343026b52a15ece5 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-1f9b4581d8b0a27c343026b52a15ece5 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/www.sciencedirect.com\/science\/article\/abs\/pii\/S096014812201610X?via%3Dihub\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/08\/X09601481-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/08\/X09601481-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/08\/X09601481.jpg 574w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/x09601481-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/www.sciencedirect.com\/science\/article\/abs\/pii\/S096014812201610X?via%3Dihub\"><span style=\"font-size: 12pt;\"><strong>RNA-seq based transcriptomic analysis of the non-conventional yeast <em>Spathaspora passalidarum<\/em> during Melle-boinot cell recycle in xylose-glucose mixtures<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>NOV-2022 <\/strong>Xylose-fermenting non-conventional yeasts are promising alternatives for second-generation ethanol production. Here, we evaluated the impact of the Melle-Boinot process on the physiology of the non-conventional yeast Spathaspora passalidarum. A metabolic reprogramming was observed which resulted in an increase in both ethanol yield and productivity. These results can guide future development of novel microorganisms to enable the production of renewable energy from lignocellulosic biomass.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1594988184275{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-d606cc31f8715b1748fe1be849aced4d.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-d606cc31f8715b1748fe1be849aced4d.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-d606cc31f8715b1748fe1be849aced4d .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-d606cc31f8715b1748fe1be849aced4d .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-d606cc31f8715b1748fe1be849aced4d alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"http:\/\/dx.doi.org\/10.1016\/j.spc.2022.09.009\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20313%20313&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/09\/sustainable-cover.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/09\/sustainable-cover.jpg 313w\" loading=\"eager\" style=\"--ratio: 313 \/ 313\" sizes=\"(max-width: 313px) 100vw, 313px\" width=\"313\" height=\"313\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/sustainable-cover-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/doi.org\/10.1016\/j.spc.2022.09.009\"><span style=\"font-size: 12pt;\"><strong>Techno-economic and environmental assessment of polylactic acid production integrated with the sugarcane value chain<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>SEP-2022 <\/strong>Bio-based plastics can contribute to climate change mitigation. However, their use is still limited by the high cost compared to traditional fossil-based polymers. In this study, the production process of polylactic acid (PLA) derived from sugarcane juice is evaluated from the techno-economic and environmental perspectives. Its integration with the Brazilian sugarcane production chain is strategic to reduce production costs and improve PLA\u2019s competitiveness.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1618228239125{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-82e1e0cc43281a848ae9ea97283f3056.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-82e1e0cc43281a848ae9ea97283f3056.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-82e1e0cc43281a848ae9ea97283f3056 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-82e1e0cc43281a848ae9ea97283f3056 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-82e1e0cc43281a848ae9ea97283f3056 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/www.sciencedirect.com\/science\/article\/abs\/pii\/S0960148122005626\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/08\/X09601481-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/08\/X09601481-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/08\/X09601481.jpg 574w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/x09601481-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/www.sciencedirect.com\/science\/article\/abs\/pii\/S0960148122005626\"><span style=\"font-size: 12pt;\"><strong>Integration of first- and second-generation ethanol production: Evaluation of a mathematical model to describe sucrose and xylose co-fermentation by recombinant <em>Saccharomyces cerevisiae<\/em><\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>AUG-2022 <\/strong>Recombinant yeasts are valuable to optimize the development of bioprocesses for second-generation biofuels production. This work proposes kinetic models to describe the recombinant yeast metabolism in a co-fermentation of sugars (sucrose, glucose, fructose and xylose) from sugarcane. The model allowed to evaluate the impact of cell concentration and different carbon sources on ethanol production in an integrated biorefinery.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1594988184275{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-33e4ef8bf0f6ac97a4bd48007909fa4b.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-33e4ef8bf0f6ac97a4bd48007909fa4b.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-33e4ef8bf0f6ac97a4bd48007909fa4b .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-33e4ef8bf0f6ac97a4bd48007909fa4b .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-33e4ef8bf0f6ac97a4bd48007909fa4b alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/pubs.acs.org\/doi\/pdf\/10.1021\/acssuschemeng.2c02462\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20292%20292&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/08\/acs-sustainable-22.png\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/08\/acs-sustainable-22.png 292w\" loading=\"eager\" style=\"--ratio: 292 \/ 292\" sizes=\"(max-width: 292px) 100vw, 292px\" width=\"292\" height=\"292\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/acs-sustainable-22-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/pubs.acs.org\/doi\/pdf\/10.1021\/acssuschemeng.2c02462\"><span style=\"font-size: 12pt;\"><strong>Density Functional Theory with Implicit Solvents for Accurate Estimation of Aqueous and Organic Solvation Free Energies of Lignin Fragments<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>AUG-2022 <\/strong>Lignin is the main potential source of renewable aromatic chemicals, but solvation properties of lignin depolymerization fragments are not yet accurately and comprehensively described. This work modeled the solvation of lignin fragments in water and organic solvents using a quantum chemistry method. Unprecedented accuracy was achieved for a large set of lignin depolymerization fragments, a key advancement toward accurate computer modeling of lignin processing into renewable fuels and chemicals.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1618228239125{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-bd3a6c68e8173b155a6d6f6e6eaba8bd.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-bd3a6c68e8173b155a6d6f6e6eaba8bd.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-bd3a6c68e8173b155a6d6f6e6eaba8bd .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-bd3a6c68e8173b155a6d6f6e6eaba8bd .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-bd3a6c68e8173b155a6d6f6e6eaba8bd alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/www.sciencedirect.com\/science\/article\/abs\/pii\/S0960148121014804\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/08\/X09601481-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/08\/X09601481-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/08\/X09601481.jpg 574w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/x09601481-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/www.sciencedirect.com\/science\/article\/abs\/pii\/S0960148121014804\"><span style=\"font-size: 12pt;\"><strong>Simultaneous saccharification isomerization and Co-fermentation \u2013 SSICF: A new process concept for second-generation ethanol biorefineries combining immobilized recombinant enzymes and non-GMO <em>Saccharomyces<\/em><\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>AUG-2022 <\/strong>Integrated bioprocess strategies may facilitate ethanol production from both C5 and C6 fractions of lignocellulosic feedstocks. This work proposes a new process concept (SSICF), where sugarcane bagasse is hydrolyzed simultaneously with xylose isomerization and co-fermentation of C5 and C6 sugars. This is the first successful proof-of-concept of SSICF with enzyme recycling and non-GMO yeast, an innovative process with high potential for industrial use. Patent: BR1020200111221.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1594988184275{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-204ba3a9a728f817cbd1ce562484da3f.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-204ba3a9a728f817cbd1ce562484da3f.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-204ba3a9a728f817cbd1ce562484da3f .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-204ba3a9a728f817cbd1ce562484da3f .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-204ba3a9a728f817cbd1ce562484da3f alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/pubmed.ncbi.nlm.nih.gov\/34641740\/\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/08\/Critical-Reviews-Biotech-500x500.png\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/08\/Critical-Reviews-Biotech-500x500.png 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/08\/Critical-Reviews-Biotech.png 524w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/critical-reviews-biotech-2-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/pubmed.ncbi.nlm.nih.gov\/34641740\/\"><span style=\"font-size: 12pt;\"><strong>Paradigm shift in xylose isomerase usage: a novel scenario with distinct applications<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>AUG-2022 <\/strong>The development of renewable materials requires adequate use of renewable carbon sources. In this context, D-xylose usage is crucial as it is the second-most abundant sugar in nature. This review provides an overview of xylose isomerases, enzymes that enable the xylose metabolism by several microorganisms. It covers from their primary sources to the biochemical and structural features that influence their mechanisms of action.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1618228239125{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-44f7adb076ded05ba0a7236fce146f14.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-44f7adb076ded05ba0a7236fce146f14.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-44f7adb076ded05ba0a7236fce146f14 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-44f7adb076ded05ba0a7236fce146f14 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-44f7adb076ded05ba0a7236fce146f14 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/www.sciencedirect.com\/science\/article\/abs\/pii\/S2352550922001336\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/08\/X23525509-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/08\/X23525509-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/08\/X23525509.jpg 579w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/x23525509-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/www.sciencedirect.com\/science\/article\/abs\/pii\/S2352550922001336\"><span style=\"font-size: 12pt;\"><strong>Techno-economic and environmental assessment of bioenergy and livestock integrated systems in Brazil<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>AUG-2022 <\/strong>The integration of bioenergy and livestock production is a promising option to alleviate the pressure on land use. This study evaluated integrated systems, based on pasture intensification and use of biofuel subproducts as animal feed supplement. The results showed that integration contributes to improved greenhouse gas mitigation and to multiple Sustainable Development Goals (SDGs) and is technically and economically feasible.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1594988184275{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-d706fd34f3039804532b98743b937fc6.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-d706fd34f3039804532b98743b937fc6.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-d706fd34f3039804532b98743b937fc6 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-d706fd34f3039804532b98743b937fc6 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-d706fd34f3039804532b98743b937fc6 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/doi.org\/10.1007\/s10113-022-01907-1\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20218%20218&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/04\/reg-environ-change.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/04\/reg-environ-change.jpg 218w\" loading=\"eager\" style=\"--ratio: 218 \/ 218\" sizes=\"(max-width: 218px) 100vw, 218px\" width=\"218\" height=\"218\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/reg-environ-change\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/doi.org\/10.1007\/s10113-022-01907-1\"><span style=\"font-size: 12pt;\"><strong>Implications of regional agricultural land use dynamics and deforestation associated with sugarcane expansion for soil carbon stocks in Brazil<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>APR-2022 <\/strong>The sugarcane sector in Brazil has contributed to energy security and climate change mitigation. This study evaluated the direct effects of sugarcane cultivation (2002 to 2016) on deforestation and soil carbon stocks, both nationally and in two watersheds. The evaluation showed little direct impact of cultivation on deforestation, and dynamics of land use change dependent on regional aspects, as well as the maintenance of carbon stocks in the watersheds evaluated.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1618228239125{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-0cb7eed70e5a460e7eec2b74d0fb4c16.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-0cb7eed70e5a460e7eec2b74d0fb4c16.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-0cb7eed70e5a460e7eec2b74d0fb4c16 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-0cb7eed70e5a460e7eec2b74d0fb4c16 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-0cb7eed70e5a460e7eec2b74d0fb4c16 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/www.nature.com\/articles\/s41566-022-00969-1\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20200%20200&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/05\/nature-photonics-16.png\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/05\/nature-photonics-16.png 200w\" loading=\"eager\" style=\"--ratio: 200 \/ 200\" sizes=\"(max-width: 200px) 100vw, 200px\" width=\"200\" height=\"200\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/nature-photonics-16-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/www.nature.com\/articles\/s41566-022-00969-1\"><span style=\"font-size: 12pt;\"><strong>Chiral phonons in microcrystals and nanofibrils of biomolecules<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>MAR-2022 <\/strong>Differences in tridimentional arrangement of some molecules can significantly modify their function and even cause harmful health effects. This work shows how chiral radiation at the Terahertz domain can help us to identify the composition and arrangement of proteins or aminoacid crystals, with applications in nutritional supplement quality control and also in the identification of harmful accumulation of biomolecules, such as insulin fibrils and kidney stones.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1594988184275{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-8da4345cbc34a1c528fb6f3ddaa49fdb.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-8da4345cbc34a1c528fb6f3ddaa49fdb.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-8da4345cbc34a1c528fb6f3ddaa49fdb .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-8da4345cbc34a1c528fb6f3ddaa49fdb .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-8da4345cbc34a1c528fb6f3ddaa49fdb alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/www.nature.com\/articles\/s41565-022-01079-3\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20200%20200&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/05\/nature-nanotech-17.png\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/05\/nature-nanotech-17.png 200w\" loading=\"eager\" style=\"--ratio: 200 \/ 200\" sizes=\"(max-width: 200px) 100vw, 200px\" width=\"200\" height=\"200\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/nature-nanotech-17-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/www.nature.com\/articles\/s41565-022-01079-3\"><span style=\"font-size: 12pt;\"><strong>Polarization-sensitive optoionic membranes from chiral plasmonic nanoparticles<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>MAR-2022 <\/strong>The association of aminoacids and nanostructures can bring significant impacts on the development of optical devices. This work shows the development of a device, a nanomembrane covered wth gold nanoparticles modified with the aminoacid phenylalanine, capable of converting circularly polarized light into information. Besides helping the understanding of some natural optical processes, the sensitivity of this technique can be useful in the development of advanced semicondutors.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1618228239125{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-9ea44015b394c5cd988865e8373623b0.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-9ea44015b394c5cd988865e8373623b0.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-9ea44015b394c5cd988865e8373623b0 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-9ea44015b394c5cd988865e8373623b0 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-9ea44015b394c5cd988865e8373623b0 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/onlinelibrary.wiley.com\/doi\/10.1111\/jiec.13242\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/02\/journal-industrial-ecology-1-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/02\/journal-industrial-ecology-1-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/02\/journal-industrial-ecology-1.jpg 761w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/journal-industrial-ecology\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/onlinelibrary.wiley.com\/doi\/10.1111\/jiec.13242\"><span style=\"font-size: 12pt;\"><strong>Addressing the contributions of electricity from biomass in Brazil in the context of the Sustainable Development Goals using life cycle assessment methods<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>FEB-2022 <\/strong>Achieving the goals of the Sustainable Development Goals (SDGs) is essential for the future of our planet. This study proposes a methodology and uses it to compare the impacts on the SDGs of electricity from sugarcane biomass (EBC) with other technological options in the Brazilian electricity matrix. The results indicate, for example, that EBC performs better on the SDGs compared to electricity produced from coal and oil. The study also demonstrates key areas in EBC production that need to be improved to better contribute to achieving SDG targets, such as female participation in the workforce and better wages.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1594988184275{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-ede70e88a4ac8354075dced085856742.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-ede70e88a4ac8354075dced085856742.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-ede70e88a4ac8354075dced085856742 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-ede70e88a4ac8354075dced085856742 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-ede70e88a4ac8354075dced085856742 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/www.nature.com\/articles\/s41467-022-28310-y\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20326%20326&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/02\/NATURE-COMMS-22.png\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/02\/NATURE-COMMS-22.png 326w\" loading=\"eager\" style=\"--ratio: 326 \/ 326\" sizes=\"(max-width: 326px) 100vw, 326px\" width=\"326\" height=\"326\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/nature-comms-22-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/www.nature.com\/articles\/s41467-022-28310-y\"><span style=\"font-size: 12pt;\"><strong>Gut microbiome of the largest living rodent harbors unprecedented enzymatic systems to degrade plant polysaccharides<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>FEB-2022 <\/strong>The microbial biodiversity present in the digestive tract of capybara, the largest living rodent, is an unexplored reservoir of enzymatic mechanisms for the breakdown of lignocellulosic biomass. Exploring this environment, by multi-omics strategies combined with carbohydrate enzymology, a new glycoside hydrolase family of \u03b2-galactosidases and a novel carbohydrate-binding module family involved in xylan binding were unveiled. These discoveries have potential applications for the production of biofuels, biochemicals, biomaterials and food.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1618228239125{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-500f3d31185d28078f090522c1941626.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-500f3d31185d28078f090522c1941626.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-500f3d31185d28078f090522c1941626 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-500f3d31185d28078f090522c1941626 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-500f3d31185d28078f090522c1941626 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/link.springer.com\/article\/10.1007%2Fs12649-021-01655-z\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20471%20471&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/02\/waste-biomass-valor-1.png\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/02\/waste-biomass-valor-1.png 471w\" loading=\"eager\" style=\"--ratio: 471 \/ 471\" sizes=\"(max-width: 471px) 100vw, 471px\" width=\"471\" height=\"471\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/waste-biomass-valor\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/link.springer.com\/article\/10.1007%2Fs12649-021-01655-z\"><span style=\"font-size: 12pt;\"><strong>Unveiling the Variability and Multiscale Structure of Soybean Hulls for Biotechnological Valorization<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>FEB-2022 <\/strong>Soybean hulls (SBH) are an important agroindustrial residue and potential feedstock for biorenewables. This article confirms the low recalcitrance of SBH, demonstrating high yields (e.g., 80% glucose) in enzymatic conversion without pretreatment. The article also presents a multiscale structural basis for understanding SBH variability and recalcitrance.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1594988184275{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-eb862b62f76de5d88045f6ef4367eba1.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-eb862b62f76de5d88045f6ef4367eba1.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-eb862b62f76de5d88045f6ef4367eba1 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-eb862b62f76de5d88045f6ef4367eba1 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-eb862b62f76de5d88045f6ef4367eba1 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/sfamjournals.onlinelibrary.wiley.com\/doi\/10.1111\/1462-2920.15876\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/02\/ENVIRONMENTAL-MICRO-1-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/02\/ENVIRONMENTAL-MICRO-1-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/02\/ENVIRONMENTAL-MICRO-1.jpg 595w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/environmental-micro\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/sfamjournals.onlinelibrary.wiley.com\/doi\/10.1111\/1462-2920.15876\"><span style=\"font-size: 12pt;\"><strong>Bacterial volatile organic compounds induce adverse ultrastructural changes and DNA damage to the sugarcane pathogenic fungus <em>Thielaviopsis ethacetica<\/em><\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>FEB-2022 <\/strong>The importance of biotechnology in agriculture is increasing. Therefore, this study demonstrates the potential of bacterial bioactive metabolites, known as volatile organic compounds (VOCs), to be used as an alternative to agrochemicals in the control of disease in crops. The results show that the VOCs treatment inhibit the primary metabolism, triggers morphological alterations and DNA damage in the phytopathogen, resulting in its death.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1594988184275{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-6122e791a3fcfca8391a7cc6f2a16e11.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-6122e791a3fcfca8391a7cc6f2a16e11.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-6122e791a3fcfca8391a7cc6f2a16e11 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-6122e791a3fcfca8391a7cc6f2a16e11 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-6122e791a3fcfca8391a7cc6f2a16e11 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"http:\/\/dx.doi.org\/10.1016\/j.enpol.2021.112637\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20197%20197&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/02\/energy-policy-1.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/02\/energy-policy-1.jpg 197w\" loading=\"eager\" style=\"--ratio: 197 \/ 197\" sizes=\"(max-width: 197px) 100vw, 197px\" width=\"197\" height=\"197\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/energy-policy\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"http:\/\/dx.doi.org\/10.1016\/j.enpol.2021.112637\"><span style=\"font-size: 12pt;\"><strong>Advanced technologies for electricity production in the sugarcane value chain are a strategic option in a carbon reward policy context<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>DEC-2021 <\/strong>Sustainable bioenergy production is required to meet the growing demand and environmental concerns. This study compares typical and advanced options for biomass-based electricity generation in Brazilian sugarcane mills. The assessed strategies may help to guide the feasibly deploy of advanced technologies for electricity production from biomass, meeting the future demands for sustainable electricity.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1618228239125{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-78e26220093e13261f5793647a2e8321.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-78e26220093e13261f5793647a2e8321.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-78e26220093e13261f5793647a2e8321 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-78e26220093e13261f5793647a2e8321 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-78e26220093e13261f5793647a2e8321 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/doi.org\/10.1016\/j.indcrop.2021.114139\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20197%20197&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/02\/industrial-crops-products-1.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/02\/industrial-crops-products-1.jpg 197w\" loading=\"eager\" style=\"--ratio: 197 \/ 197\" sizes=\"(max-width: 197px) 100vw, 197px\" width=\"197\" height=\"197\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/industrial-crops-products\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/doi.org\/10.1016\/j.indcrop.2021.114139\"><span style=\"font-size: 12pt;\"><strong>Techno-economic assessment of HTL integration to the Brazilian sugarcane industry: An evaluation of different scenarios<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>OCT-2021 <\/strong>The transportation sector has a lack of liquid biofuels with higher calorific value for long distances, e.g., hauls performed by airplanes, ships, and trucks. Hydrothermal liquefaction (HTL) has been identified as one of the most promising thermochemical technologies to produce liquid biofuels. The present study carried out a techno-economic analysis to understand the economic performance of HTL in the Brazilian context, indicating its potential to be economically viable if integrated into a sugarcane mill.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1594988184275{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-1ce8784e0ea33731806c2590f1fc6aa9.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-1ce8784e0ea33731806c2590f1fc6aa9.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-1ce8784e0ea33731806c2590f1fc6aa9 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-1ce8784e0ea33731806c2590f1fc6aa9 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-1ce8784e0ea33731806c2590f1fc6aa9 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/doi.org\/10.1007\/s11367-021-01936-8\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20152%20152&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/02\/1-1.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2022\/02\/1-1.jpg 152w\" loading=\"eager\" style=\"--ratio: 152 \/ 152\" sizes=\"(max-width: 152px) 100vw, 152px\" width=\"152\" height=\"152\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/1-3\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/doi.org\/10.1007\/s11367-021-01936-8\"><span style=\"font-size: 12pt;\"><strong>A novel social life cycle assessment method for determining workers\u2019 human development: a case study of the sugarcane biorefineries in Brazil<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>OCT-2021 <\/strong>The social life cycle assessment (S-LCA) methodology is important for sustainability analysis but needs to advance in its methodological development. This study proposes an indicator, inspired by the Human Development Index (HDI), which can be applied in many sectors and production chains. The proposed metric for measuring social impacts, was tested by performing a case study from the sugarcane industry in Brazil.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1618228239125{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-ef2117da0b5b13c994dd09b65ccf0c4f.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-ef2117da0b5b13c994dd09b65ccf0c4f.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-ef2117da0b5b13c994dd09b65ccf0c4f .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-ef2117da0b5b13c994dd09b65ccf0c4f .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-ef2117da0b5b13c994dd09b65ccf0c4f alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/pubmed.ncbi.nlm.nih.gov\/34641740\/\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/10\/CRITICAL-REVIEWS-BIOTECH-500x500.png\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/10\/CRITICAL-REVIEWS-BIOTECH-500x500.png 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/10\/CRITICAL-REVIEWS-BIOTECH.png 676w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/critical-reviews-biotech-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/pubmed.ncbi.nlm.nih.gov\/34641740\/\"><span style=\"font-size: 12pt;\"><strong>Paradigm shift in xylose isomerase usage: a novel scenario with distinct applications<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>OCT-2021 <\/strong>Xylose isomerases are enzymes that induce chemical changes in sugars such as xylose without affecting the original molecular formula. This paper provides a comprehensive review on the biological, biochemical, structural and thermodynamic aspects of known xylose isomerases. This paper also discusses the enzymes use in synergy with the development of bioprocess engineering and synthetic biology strategies, expanding the portfolio of biorenewables that can be obtained from xylose.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1594988184275{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-c294da7ef6c68bff4588aa8a05d6e8b2.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-c294da7ef6c68bff4588aa8a05d6e8b2.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-c294da7ef6c68bff4588aa8a05d6e8b2 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-c294da7ef6c68bff4588aa8a05d6e8b2 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-c294da7ef6c68bff4588aa8a05d6e8b2 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/www.sciencedirect.com\/science\/article\/abs\/pii\/S0960148121014804\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/10\/Renewable-Energy-160-nov-2020-QUADRADO-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/10\/Renewable-Energy-160-nov-2020-QUADRADO-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/10\/Renewable-Energy-160-nov-2020-QUADRADO.jpg 574w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/renewable-energy-160-nov-2020-quadrado-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/www.sciencedirect.com\/science\/article\/abs\/pii\/S0960148121014804\"><span style=\"font-size: 12pt;\"><strong>Simultaneous saccharification isomerization and Co-fermentation \u2013 SSICF: A new process concept for second-generation ethanol biorefineries combining immobilized recombinant enzymes and non-GMO <em>Saccharomyces<\/em><\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>OCT-2021 <\/strong>Integrated bioprocess strategies can facilitate ethanol production from the sugars glucose and xylose, present in lignocellulosic material. This paper proposes a new concept of simultaneous saccharification, isomerization and co-fermentation (SSCIF) of sugarcane bagasse. The process involves a multi-enzyme system immobilized on iron nanoparticles, and the use of yeast without genetic modification, allowing the reuse of recombinant enzymes that are attracted by a magnet. The process has a patent application (INPI &#8211; BR 1020200111221).<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1618228239125{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-e508565e63b2520c18b0f0cfd0dc8b93.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-e508565e63b2520c18b0f0cfd0dc8b93.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-e508565e63b2520c18b0f0cfd0dc8b93 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-e508565e63b2520c18b0f0cfd0dc8b93 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-e508565e63b2520c18b0f0cfd0dc8b93 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/doi.org\/10.1016\/j.resconrec.2021.105878\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/09\/resources-conservation-2021-1-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/09\/resources-conservation-2021-1-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/09\/resources-conservation-2021-1.jpg 574w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/resources-conservation-2021\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/doi.org\/10.1016\/j.resconrec.2021.105878\"><span style=\"font-size: 12pt;\"><strong>Unraveling the potential of sugarcane electricity for climate change mitigation in Brazil<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>SEP-2021 <\/strong>The integral use of biomass is essential in the search for sustainable development. In this study, we mapped the potential for harvesting sugarcane straw in the Center-South of Brazil for energy use, while keeping a minimum amount on the ground for its conservation and for the benefit of sugarcane yields. The mapping showed that without increasing any hectare of sugarcane, 62% of the straw can be strategically harvested, which could potentially generate more than 100 TWh of electricity, enough to supply more than 80% of the residential demand in the country. In addition, this electricity would annually mitigate about 13% of the Brazilian energy sector&#8217;s greenhouse gas emissions.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1594988184275{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-5323520b76498aeb7e9a91fc42bcf76f.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-5323520b76498aeb7e9a91fc42bcf76f.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-5323520b76498aeb7e9a91fc42bcf76f .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-5323520b76498aeb7e9a91fc42bcf76f .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-5323520b76498aeb7e9a91fc42bcf76f alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/www.pnas.org\/content\/118\/27\/e2026152118\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20359%20359&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/08\/PNAS-2021.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/08\/PNAS-2021.jpg 359w\" loading=\"eager\" style=\"--ratio: 359 \/ 359\" sizes=\"(max-width: 359px) 100vw, 359px\" width=\"359\" height=\"359\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/pnas-2021\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/www.pnas.org\/content\/118\/27\/e2026152118\"><span style=\"font-size: 12pt;\"><strong>Loss of function of a DMR6 ortholog in tomato confers broad-spectrum disease resistance<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>AUG-2021 <\/strong>Worldwide, plant diseases are the main cause of yield loss in the agricultural sector. In this work, headed by collaborators from the University of California, the inactivation of a tomato susceptibility gene was explored as an approach to increase its resistance against phytopathogens. Besides presenting a promising strategy for engineering agricultural crops resistant to various diseases, this work also contributed to elucidate the role of the susceptibility gene in the homeostasis of salicylic acid, a central modulator of immunity in plants.<\/p>\n<div id=\"gtx-trans\" style=\"position: absolute; left: 474px; top: 51.6px;\">\n<div class=\"gtx-trans-icon\"><\/div>\n<\/div>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1618228239125{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-847e1782b442b36fde79235df8c7b2bf.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-847e1782b442b36fde79235df8c7b2bf.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-847e1782b442b36fde79235df8c7b2bf .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-847e1782b442b36fde79235df8c7b2bf .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-847e1782b442b36fde79235df8c7b2bf alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/doi.org\/10.1016\/j.still.2021.105122\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20378%20378&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/05\/soil-tillage-2.png\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/05\/soil-tillage-2.png 378w\" loading=\"eager\" style=\"--ratio: 378 \/ 378\" sizes=\"(max-width: 378px) 100vw, 378px\" width=\"378\" height=\"378\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/soil-tillage-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/doi.org\/10.1016\/j.still.2021.105122\"><span style=\"font-size: 12pt;\"><strong>Machinery traffic in sugarcane straw removal operation: Stress transmitted and soil compaction<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>AUG-2021 <\/strong>The productive potential of biomass in Brazil, such as sugarcane, is impacted by intense machine traffic during harvest operations. This study measured the impacts on soil physical indicators by estimating the stress transmitted by a set of machines for sugarcane straw removal. Straw baling, along with raking and transport operations, resulted in higher levels of stress transmitted into the soil, thus intensifying the soil physical degradation that may compromise the sustainability of biomass production.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1594988184275{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-87508e33c6d30fe19839eb6194874ab9.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-87508e33c6d30fe19839eb6194874ab9.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-87508e33c6d30fe19839eb6194874ab9 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-87508e33c6d30fe19839eb6194874ab9 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-87508e33c6d30fe19839eb6194874ab9 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/doi.org\/10.1111\/1751-7915.13887\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/08\/microbial-biotechnology-2021-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/08\/microbial-biotechnology-2021-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/08\/microbial-biotechnology-2021.jpg 759w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/microbial-biotechnology-2021\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/doi.org\/10.1111\/1751-7915.13887\"><span style=\"font-size: 12pt;\"><strong>Exploring metal ion metabolisms to improve xylose fermentation in <em>Saccharomyces cerevisiae<\/em><\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>AUG-2021 <\/strong>Synthetic biology and metabolic engineering approaches allow the rational design of microorganisms capable of converting renewable raw material to produce biochemicals and biofuels. This study explores the rational engineering of metabolisms involved in metal homeostasis in the yeast S. cerevisiae, resulting in a 10X increase in xylose consumption rate, a component of biomass. Two genes were identified as new targets for rational engineering procedures. In this study, a detailed temporal profile of gene expression is explored, pointing unique aspects of xylose fermentation.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1618228239125{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-1dfed9e9e2eb15684f5df3bcfa6471f9.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-1dfed9e9e2eb15684f5df3bcfa6471f9.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-1dfed9e9e2eb15684f5df3bcfa6471f9 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-1dfed9e9e2eb15684f5df3bcfa6471f9 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-1dfed9e9e2eb15684f5df3bcfa6471f9 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/www.nature.com\/articles\/s41467-021-24277-4\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20300%20300&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/07\/Nature-Communications-2.png\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/07\/Nature-Communications-2.png 300w\" loading=\"eager\" style=\"--ratio: 300 \/ 300\" sizes=\"(max-width: 300px) 100vw, 300px\" width=\"300\" height=\"300\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/nature-communications-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/www.nature.com\/articles\/s41467-021-24277-4\"><span style=\"font-size: 12pt;\"><strong>Xyloglucan processing machinery in <em>Xanthomonas<\/em> pathogens and its role in the transcriptional activation of virulence factors<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>JUL-2021 <\/strong>Among the hemicellulose polysaccharides, xyloglucan is a significant fraction in most terrestrial plants, with great biotechnological potential. The bacteria Xanthomonas possess dozens of enzymes that degrade different polysaccharides, and this paper describes the discovery of a family of enzymes, a carbohydrate esterase (CE20), which is one of the links in the xyloglucan depolymerization and uptake machinery. Normally sugars are carbon sources for microorganisms, but in this case, the bacterium went further, using the sugars from xyloglucan depolymerization as inducers of protein expression that assist the microorganism to break the cell wall and modulate the plant&#8217;s natural defense mechanisms.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1594988184275{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-748c22b1a653f5e91a5bf47b028f2510.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-748c22b1a653f5e91a5bf47b028f2510.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-748c22b1a653f5e91a5bf47b028f2510 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-748c22b1a653f5e91a5bf47b028f2510 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-748c22b1a653f5e91a5bf47b028f2510 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/www.sciencedirect.com\/science\/article\/abs\/pii\/S1364032121007061\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/06\/Elsevier_Cover_Jun_2021-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/06\/Elsevier_Cover_Jun_2021-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/06\/Elsevier_Cover_Jun_2021.jpg 574w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/elsevier_cover_jun_2021\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/www.sciencedirect.com\/science\/article\/abs\/pii\/S1364032121007061\"><span style=\"font-size: 12pt;\"><strong>Implications of regional N2O\u2013N emission factors on sugarcane ethanol emissions and granted decarbonization certificates<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>JUL-2021 <\/strong>Nitrous oxide (N<sub>2<\/sub>O) emissions from N fertilizers are the main sources of greenhouse gases (GHG) emitted from sugarcane ethanol. This study derived regional N<sub>2<\/sub>O emission factors (EFs) from N fertilizers and evaluated how the use of such EFs affects ethanol emissions and the earning of decarbonization certificates (CBIOs). Regional N<sub>2<\/sub>O EFs reduced by 19% the GHG emissions from sugarcane ethanol compared with those using the IPCC default value. Regional-specific data provide more realistic indicators to account for GHG emissions of sugarcane ethanol and generate economic benefits with extra CBIOs for biofuel producers.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1618228239125{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-d4a10266ec676af60639ff0437a900ff.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-d4a10266ec676af60639ff0437a900ff.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-d4a10266ec676af60639ff0437a900ff .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-d4a10266ec676af60639ff0437a900ff .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-d4a10266ec676af60639ff0437a900ff alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/www.sciencedirect.com\/science\/article\/abs\/pii\/S0360544221013049?via%3Dihub\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/11\/Energy-quadrada-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/11\/Energy-quadrada-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/11\/Energy-quadrada.jpg 576w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/energy-quadrada\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"http:\/\/dx.doi.org\/10.1016\/j.energy.2021.121056\"><span style=\"font-size: 12pt;\"><strong>Sustainability analysis of bioethanol production in Mexico by a retrofitted sugarcane industry based on the Brazilian expertise<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>JUL-2021 <\/strong>In 2012, Mexico began a transition to the use of renewable energy with the strategy of adopting a 10% blend of ethanol in gasoline, with an estimated annual demand of 3 billion liters to be produced mainly from sugarcane. This article analyzes how it is possible to use part of the experience acquired by Brazil during its transition from sugar mills to advanced biorefineries for the Mexican case, presenting technical-economic, social, and environmental analysis for retrofit scenarios of Mexican sugar mills.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1594988184275{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-7cd42f2cecbd9996ee9ee93f0baf7748.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-7cd42f2cecbd9996ee9ee93f0baf7748.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-7cd42f2cecbd9996ee9ee93f0baf7748 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-7cd42f2cecbd9996ee9ee93f0baf7748 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-7cd42f2cecbd9996ee9ee93f0baf7748 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/www.mdpi.com\/2076-0817\/10\/6\/682\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/06\/PATHOGENS_cover-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/06\/PATHOGENS_cover-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/06\/PATHOGENS_cover.jpg 869w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/pathogens_cover\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/www.mdpi.com\/2076-0817\/10\/6\/682\"><span style=\"font-size: 12pt;\"><strong>C4 Bacterial Volatiles Improve Plant Health<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>JUN-2021 <\/strong>The search for sustainable agriculture also involves the study of microorganisms with the potential to improve plant growth and health. This review involves small metabolites produced by bacteria, the bacterial volatile compounds (BVC), that are able to activate the plant immune system, to promote plant growth and to act as biological control agents. The review also covers the positive action of BVC-conjugant on plants and the potential of some BVC as substrate for production of bioproducts.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1618228239125{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-60a758dc373223044d14e7edb9dc5904.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-60a758dc373223044d14e7edb9dc5904.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-60a758dc373223044d14e7edb9dc5904 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-60a758dc373223044d14e7edb9dc5904 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-60a758dc373223044d14e7edb9dc5904 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/www.sciencedirect.com\/science\/article\/abs\/pii\/S1364032121005554\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/06\/Elsevier_Cover_Jun_2021-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/06\/Elsevier_Cover_Jun_2021-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/06\/Elsevier_Cover_Jun_2021.jpg 574w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/elsevier_cover_jun_2021\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/www.sciencedirect.com\/science\/article\/abs\/pii\/S1364032121005554\"><span style=\"font-size: 12pt;\"><strong>Inorganics in sugarcane bagasse and straw and their impacts for bioenergy and biorefining: A review<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>JUN-2021 <\/strong>Valorization of sugarcane bagasse and straw has been hampered by the quality of these biomasses, mainly regarding their inorganic content. This paper reviews the types of inorganics and their variability, and the impacts of inorganics in several biorefinery processes and products. In the article&#8217;s view, understanding the role of inorganics is key for the design of biorefineries of grasses such as sugarcane.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1594988184275{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-73c0c01dc0c2b7183a9473b738550d2a.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-73c0c01dc0c2b7183a9473b738550d2a.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-73c0c01dc0c2b7183a9473b738550d2a .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-73c0c01dc0c2b7183a9473b738550d2a .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-73c0c01dc0c2b7183a9473b738550d2a alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/doi.org\/10.1016\/j.still.2021.104999\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20378%20378&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/05\/soil-tillage-2.png\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/05\/soil-tillage-2.png 378w\" loading=\"eager\" style=\"--ratio: 378 \/ 378\" sizes=\"(max-width: 378px) 100vw, 378px\" width=\"378\" height=\"378\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/soil-tillage-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/doi.org\/10.1016\/j.still.2021.104999\"><span style=\"font-size: 12pt;\"><strong>How do nitrogen fertilization and cover crop influence soil C-N stocks and subsequent yields of sugarcane?<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>APR-2021 <\/strong>Legumes fix nitrogen (N) from the atmosphere, making them excellent options for providing N to the agricultural system and indirectly mitigating greenhouse gas emissions by reducing the demand for synthetic fertilizers. Sugarcane cultivation requires N, but there are no reports of the impacts of its cultivation on C-N stocks. This paper proved that nitrogen fertilization and crop rotation with legumes increased sugarcane yield by 12%, increased N stocks and soil microbial biomass, but did not affect soil carbon (C) stocks.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1618228239125{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-b70ab9313ca082d7bb934c32d233eb25.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-b70ab9313ca082d7bb934c32d233eb25.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-b70ab9313ca082d7bb934c32d233eb25 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-b70ab9313ca082d7bb934c32d233eb25 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-b70ab9313ca082d7bb934c32d233eb25 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/onlinelibrary.wiley.com\/doi\/10.1111\/gcbb.12832\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/05\/gcbb.v13.6.cover_-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/05\/gcbb.v13.6.cover_-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/05\/gcbb.v13.6.cover_.jpg 758w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/gcbb-v13-6-cover\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/doi.org\/10.1111\/gcbb.12832\"><span style=\"font-size: 12pt;\"><strong>Multilocation changes in soil carbon stocks from sugarcane straw removal for bioenergy production in Brazil<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>APR-2021 <\/strong>The soil is the main carbon (C) pool of the terrestrial ecosystem and, depending on the land use, it can act as a source or drain of atmospheric CO2. The sugarcane straw is an important C input for soils and also has a high potential for bioenergy production. This study evaluated the impacts of straw removal on soil C stocks under different soil and climate conditions in Brazil. It has been confirmed that excessive straw removal decreases soil C stocks, and these impacts are more negative on sandy soils. It is concluded that the adverse impacts on the soil must be included in life cycle assessment of bioenergy produced from straw.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1594988184275{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-16a32b71f626fc6337362093a5928dc1.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-16a32b71f626fc6337362093a5928dc1.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-16a32b71f626fc6337362093a5928dc1 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-16a32b71f626fc6337362093a5928dc1 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-16a32b71f626fc6337362093a5928dc1 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/www.sciencedirect.com\/science\/article\/abs\/pii\/S0006349521002915#!\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/04\/Biophysycal-Journal-abril-2021-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/04\/Biophysycal-Journal-abril-2021-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/04\/Biophysycal-Journal-abril-2021.jpg 591w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/biophysycal-journal-abril-2021-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/www.sciencedirect.com\/science\/article\/abs\/pii\/S0006349521002915#!\"><span style=\"font-size: 12pt;\"><strong>Electrostatic Interactions Optimization Improves Catalytic Rates and Thermotolerance on Xylanases<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>APR-2021 <\/strong>Designing enzymes with more sophisticated catalytic machineries than those found in nature streamline the generation of new enzymes and its use for diverse biotechnological applications. This work describes a novel and efficient computation-guided method capable of rationally &#8216;customizing&#8217; enzymes with improved catalytic rates and thermotolerance. This new technology has potential impact on the development of industrially relevant products.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1618228239125{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-e337376ead78cd3831a4263e37283c82.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-e337376ead78cd3831a4263e37283c82.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-e337376ead78cd3831a4263e37283c82 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-e337376ead78cd3831a4263e37283c82 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-e337376ead78cd3831a4263e37283c82 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/scripts.iucr.org\/cgi-bin\/paper?S2059798321001583\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20167%20167&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/04\/Acta-Section-D.png\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/04\/Acta-Section-D.png 167w\" loading=\"eager\" style=\"--ratio: 167 \/ 167\" sizes=\"(max-width: 167px) 100vw, 167px\" width=\"167\" height=\"167\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/acta-section-d-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/scripts.iucr.org\/cgi-bin\/paper?S2059798321001583\"><span style=\"font-size: 12pt;\"><strong>Structure of the class XI myosin globular tail reveals evolutionary hallmarks for cargo recognition in plants<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>APR-2021 <\/strong>Understanding the molecular mechanisms for the transport of cellular components is important in the production of biorenewables, as they are involved from the secretion of fungal enzyme to plant growth. This work unveils the high-resolution structure of an important protein domain that determines what type of components will be transported by the molecular motor myosin. The work also applied a new method of experimental phasing based on libraries of short fragments, which broadened the spectrum of experimental approaches to elucidate new protein structures.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1618228272621{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-8c9ed47db3aac23c27a2e601a06b6058.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-8c9ed47db3aac23c27a2e601a06b6058.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-8c9ed47db3aac23c27a2e601a06b6058 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-8c9ed47db3aac23c27a2e601a06b6058 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-8c9ed47db3aac23c27a2e601a06b6058 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/doi.org\/10.1016\/j.jclepro.2020.125318\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/08\/Journal-Cleaner-prod-novo-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/08\/Journal-Cleaner-prod-novo-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/08\/Journal-Cleaner-prod-novo.jpg 576w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/journal-cleaner-prod-novo\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/doi.org\/10.1016\/j.jclepro.2020.125318\"><span style=\"font-size: 12pt;\"><strong>Identifying suitable areas for expanding sugarcane ethanol production in Brazil under conservation of environmentally relevant habitats<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>APR-2021 <\/strong>It is not enough to be renewable, it is necessary to be sustainable. This study showed that Brazil has about 20 million hectares to produce sugarcane or other biomass, intensifying the environmental advantages arising not only from the replacement of fossils, but also the rational use of natural resources, going beyond the mitigation of greenhouse gases. Areas were mapped for expansion considering the preservation of native vegetation, biodiversity and food production.<\/p>\n<div id=\"gtx-trans\" style=\"position: absolute; left: 7px; top: 38px;\">\n<div class=\"gtx-trans-icon\"><\/div>\n<\/div>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1618228239125{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-34fab6acd1132c4ed685c55e3cf1a0a2.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-34fab6acd1132c4ed685c55e3cf1a0a2.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-34fab6acd1132c4ed685c55e3cf1a0a2 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-34fab6acd1132c4ed685c55e3cf1a0a2 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-34fab6acd1132c4ed685c55e3cf1a0a2 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/onlinelibrary.wiley.com\/doi\/abs\/10.1111\/ejss.13107\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/04\/european-journal-soil-science-marco-2021-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/04\/european-journal-soil-science-marco-2021-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/04\/european-journal-soil-science-marco-2021.jpg 595w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/european-journal-soil-science-marco-2021-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/onlinelibrary.wiley.com\/doi\/abs\/10.1111\/ejss.13107\"><span style=\"font-size: 12pt;\"><strong>Untrafficked furrowed seedbed sustains soil physical quality in sugarcane mechanized fields<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>MAR-2021 <\/strong>The abundant production of biomass in Brazil suffers from the intense traffic of agricultural machinery that compact and degrade the soil structure, which reduces its productive potential. This work observed, in five years of study, that the use of seedbeds recovers the soil physical and structural quality without the need for mechanical tillage practices. The use of seedbeds system improves root growth and the biological activity of the soil and makes sugarcane production more sustainable, mainly due to the better soil physical quality.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1594988184275{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-9ef6e0dc21d7ff1c55fccb707c24171d.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-9ef6e0dc21d7ff1c55fccb707c24171d.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-9ef6e0dc21d7ff1c55fccb707c24171d .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-9ef6e0dc21d7ff1c55fccb707c24171d .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-9ef6e0dc21d7ff1c55fccb707c24171d alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/doi.org\/10.1038\/s41586-020-03167-7\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20438%20438&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/02\/Nature-5902.png\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/02\/Nature-5902.png 438w\" loading=\"eager\" style=\"--ratio: 438 \/ 438\" sizes=\"(max-width: 438px) 100vw, 438px\" width=\"438\" height=\"438\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/nature-5902\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/doi.org\/10.1038\/s41586-020-03167-7\"><span style=\"font-size: 12pt;\"><strong>Developing fibrillated cellulose as a sustainable technological material<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>FEV-2021 <\/strong>Cellulose from plant biomass can be isolated as fibrils of nanometric diameter, generating building blocks for the development of a new family of renewable technological materials. This work discusses future research directions and highlights key questions for the development of fibrillated cellulose as a platform of novel sustainable biomaterials.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1610737837883{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-cc8c6d29c99ec4bf7d7993bfcbd9f59b.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-cc8c6d29c99ec4bf7d7993bfcbd9f59b.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-cc8c6d29c99ec4bf7d7993bfcbd9f59b .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-cc8c6d29c99ec4bf7d7993bfcbd9f59b .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-cc8c6d29c99ec4bf7d7993bfcbd9f59b alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/doi.org\/10.1038\/s41467-020-20620-3\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20300%20300&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/01\/Nature-comm_2.png\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2021\/01\/Nature-comm_2.png 300w\" loading=\"eager\" style=\"--ratio: 300 \/ 300\" sizes=\"(max-width: 300px) 100vw, 300px\" width=\"300\" height=\"300\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/nature-comm_2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/doi.org\/10.1038\/s41467-020-20620-3\"><span style=\"font-size: 12pt;\"><strong>Two distinct catalytic pathways for GH43 xylanolytic enzymes unveiled by X-ray and QM\/MM simulations<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>JAN-2021 <\/strong>Glycosidases are enzymes involved in lignocellulose breakdown and are central for agro-industrial residues valorization and industrial biotechnology. To enable these enzymes to convert a substrate into the product, several conformational changes occur (catalytic itinerary). This work shows a glycosidase that operates via two distinct catalytic itineraries, breaking the paradigm of the existence of only one possible route for the substrate conversion. The discovery opens new horizons on the molecular functioning of these enzymes and immediately impacts the development of novel biocatalysts.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1594985352389{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243;][vc_column_text css=&#8221;.vc_custom_1598880903212{margin-bottom: 3px !important;border-bottom-width: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-62fd6965fa8ab3715d1bc1ad52b81d54.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-62fd6965fa8ab3715d1bc1ad52b81d54.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-62fd6965fa8ab3715d1bc1ad52b81d54 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-62fd6965fa8ab3715d1bc1ad52b81d54 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-62fd6965fa8ab3715d1bc1ad52b81d54 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/doi.org\/10.1016\/j.biortech.2020.123918\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/11\/Biores-Tech-quadrada-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/11\/Biores-Tech-quadrada-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/11\/Biores-Tech-quadrada.jpg 576w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/biores-tech-quadrada\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/doi.org\/10.1016\/j.biortech.2020.123918\"><span style=\"font-size: 14pt;\"><strong><span style=\"font-size: 12pt;\">Screening of potential endoglucanases, hydrolysis conditions and different sugarcane straws pretreatments for cello-oligosaccharides production<\/span><\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>NOV-2020<\/strong> Molecular biology linked to process development is an important tool for the sustainable use of natural resources such as sugarcane straw. This work has studied the combination of five endoglucanase enzymes for the production of cello-oligosaccharides (COS), potentially useful in the human and animal food sectors. This is the first study that combined the evaluation of different enzymes, conditions, and sugarcane straw pretreatments to optimize COS production in a single step without glucose formation.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1594988184275{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-4adb29b80297af61bd3312f41e45743e.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-4adb29b80297af61bd3312f41e45743e.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-4adb29b80297af61bd3312f41e45743e .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-4adb29b80297af61bd3312f41e45743e .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-4adb29b80297af61bd3312f41e45743e alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/doi.org\/10.1016\/j.biortech.2020.123637\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/11\/Biores-Tech-quadrada-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/11\/Biores-Tech-quadrada-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/11\/Biores-Tech-quadrada.jpg 576w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/biores-tech-quadrada\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/doi.org\/10.1016\/j.biortech.2020.123637\"><span style=\"font-size: 12pt;\"><strong>An integrated approach to obtain xylo-oligosaccharides from sugarcane straw: From lab to pilot scale<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>OCT-2020<\/strong> The use of crop residues to obtain products with high added value is an important aspect of sustainable development. This work brings new perspectives to value sugarcane straw to bioproducts other than for the production of heat and bioelectricity. It shows the potential of sugarcane straw to produce xylo-oligosaccharides (XOS), a prebiotic substance, and the use of xylanase enzymes to hydrolyze XOS. The study covered the laboratory and pilot-scale (LNBR Pilot Plant) of production.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1594985352389{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243;][vc_column_text css=&#8221;.vc_custom_1598880903212{margin-bottom: 3px !important;border-bottom-width: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-c2127cfed88b4ae3b37b70258d96de0d.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-c2127cfed88b4ae3b37b70258d96de0d.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-c2127cfed88b4ae3b37b70258d96de0d .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-c2127cfed88b4ae3b37b70258d96de0d .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-c2127cfed88b4ae3b37b70258d96de0d alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/www.sciencedirect.com\/science\/article\/abs\/pii\/S0960148120311034\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/09\/Renewable-Energy-160-nov-2020-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/09\/Renewable-Energy-160-nov-2020-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/09\/Renewable-Energy-160-nov-2020-576x576.jpg 576w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/renewable-energy-160-nov-2020\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/www.sciencedirect.com\/science\/article\/abs\/pii\/S0960148120311034\"><span style=\"font-size: 14pt;\"><strong><span style=\"font-size: 12pt;\">Impact of the Melle-Boinot process on the enhancement of second-generation ethanol production by <em>Spathaspora passalidarum<\/em><\/span><\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>AUG-2020<\/strong> Microbial biodiversity is a source of solutions in biotechnology. The non-conventional yeast <em>Spathaspora passalidarum<\/em> is a potential platform for industrial applications aiming to produce cellulosic ethanol and biochemicals due to its natural ability to ferment xylose. This study reports for the first time the use of the Melle-Boinot fermentation process using this yeast, achieving high ethanol yields, demonstrating to be a worthy strategy in the production of biofuels.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1594988184275{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-d33803db5f5346eb6b6a8a95ee548496.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-d33803db5f5346eb6b6a8a95ee548496.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-d33803db5f5346eb6b6a8a95ee548496 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-d33803db5f5346eb6b6a8a95ee548496 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-d33803db5f5346eb6b6a8a95ee548496 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/onlinelibrary.wiley.com\/doi\/abs\/10.1002\/bbb.2136?af=R\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/08\/BIOFPR-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/08\/BIOFPR-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/08\/BIOFPR-594x594.jpg 594w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/biofpr\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/onlinelibrary.wiley.com\/doi\/abs\/10.1002\/bbb.2136?af=R\"><span style=\"font-size: 12pt;\"><strong>A rationally identi\ufb01ed marine GH1 Beta-glucosidase has distinguishing functional features for simultaneous sacchari\ufb01cation and fermentation<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>AUG-2020<\/strong> New solutions to produce biofuels from sugarcane residues can come from unexpected environments, such as the marine. This work demonstrated the potential use of a marine enzyme \u03b2-glucosidase (GH1), rationally identified, in the production of cellulosic ethanol with simultaneous saccharification and fermentation. With activity in celo-oligosaccharides and efficiency in milder temperatures, this enzyme can be used in industrial biotechnological processes that involve the deconstruction of lignocellulosic material.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1594985352389{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243;][vc_column_text css=&#8221;.vc_custom_1598880903212{margin-bottom: 3px !important;border-bottom-width: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-1269ad25a02348a6a943a802152ae1fc.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-1269ad25a02348a6a943a802152ae1fc.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-1269ad25a02348a6a943a802152ae1fc .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-1269ad25a02348a6a943a802152ae1fc .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-1269ad25a02348a6a943a802152ae1fc alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/biotechnologyforbiofuels.biomedcentral.com\/articles\/10.1186\/s13068-020-01782-0\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20306%20306&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/08\/Biotech-for-biofuels-novo-1.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/08\/Biotech-for-biofuels-novo-1.jpg 306w\" loading=\"eager\" style=\"--ratio: 306 \/ 306\" sizes=\"(max-width: 306px) 100vw, 306px\" width=\"306\" height=\"306\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/biotech-for-biofuels-novo-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/biotechnologyforbiofuels.biomedcentral.com\/articles\/10.1186\/s13068-020-01782-0\"><span style=\"font-size: 14pt;\"><strong><span style=\"font-size: 12pt;\">Novel xylose transporter Cs4130 expands the sugar uptake repertoire in recombinant <em>Saccharomyces cerevisiae<\/em> strains at high xylose concentrations<\/span><\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>AUG-2020<\/strong> A major challenge on 2G technologies establishment is the inefficient assimilation of the five-carbon sugar xylose by engineered <em>S. cerevisiae<\/em> strains, increasing fermentation time. This work describes a novel and efficient xylose transporter, improving xylose uptake especially in high concentrations. The work also investigates the dynamic behavior of the transporter, pointing out residues related to xylose translocation.<\/p>\n<div id=\"gtx-trans\" style=\"position: absolute; left: -6px; top: 7px;\">\n<div class=\"gtx-trans-icon\"><\/div>\n<\/div>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_empty_space][vc_row_inner css=&#8221;.vc_custom_1594988184275{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-530352084f3948189f2553f5a07fa868.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-530352084f3948189f2553f5a07fa868.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-530352084f3948189f2553f5a07fa868 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-530352084f3948189f2553f5a07fa868 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-530352084f3948189f2553f5a07fa868 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/doi.org\/10.1038\/s41589-020-0585-y\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20300%20300&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/07\/Nature-CHEM-BIO-1.png\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/07\/Nature-CHEM-BIO-1.png 300w\" loading=\"eager\" style=\"--ratio: 300 \/ 300\" sizes=\"(max-width: 300px) 100vw, 300px\" width=\"300\" height=\"300\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/nature-chem-bio-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: left;\"><span style=\"font-size: 12pt;\"><a href=\"https:\/\/doi.org\/10.1038\/s41589-020-0585-y\"><strong>Enzymes knuckle down to the job<\/strong><\/a><\/span><\/p>\n<p style=\"text-align: justify;\"><strong>JUN-2020<\/strong> Discovery of new enzymes for health, nutrition, biofuels, and other industrial biotechnological applications. Inspired by the molecular biodiversity of microorganisms this work has deepened the knowledge about new enzymatic strategies for the polysaccharides \u03b2-1,3-glucans processing, discovering a new mechanism of polysaccharide recognition and new mode of enzymatic action.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1594985352389{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243;][vc_column_text css=&#8221;.vc_custom_1594929743601{margin-bottom: 3px !important;border-bottom-width: 3px !important;padding-bottom: 3px !important;background-color: #81d742 !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>TECHNOLOGY<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-9051df613f3a1c19da96c8e3e914d1b6.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-9051df613f3a1c19da96c8e3e914d1b6.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-9051df613f3a1c19da96c8e3e914d1b6 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-9051df613f3a1c19da96c8e3e914d1b6 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-9051df613f3a1c19da96c8e3e914d1b6 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/07\/SUCRE-Project-Final-Report.pdf\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/07\/Capa-Relat\u00f3rio-SUCRE-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/07\/Capa-Relat\u00f3rio-SUCRE-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/07\/Capa-Relat\u00f3rio-SUCRE.jpg 900w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/capa-relatorio-sucre\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243;][vc_column_text]<a href=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/07\/SUCRE-Project-Final-Report.pdf\"><span style=\"font-size: 14pt;\"><strong><span style=\"font-size: 12pt;\">SUCRE Final Report<\/span><\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>JUN-2020<\/strong> Decarbonization of the electricity sector can benefit from straw, an underutilized sugarcane residue. This report provides an integrated and in-depth analysis of straw-based electricity in Brazil, considering technical, economic, environmental, and societal impacts. Corroborating its relevance to other sugarcane producing countries, SUCRE was a highlight in the report <a href=\"https:\/\/www.unsouthsouth.org\/wp-content\/uploads\/2019\/12\/Bioeconomy-Publication_visualization-for-website.pdf\">\u201cSouth-South and Triangular Cooperation on the Bioeconomy\u201c<\/a> presented at COP-25.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_empty_space][vc_row_inner css=&#8221;.vc_custom_1594988351132{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988502782{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-921a91b0ba3d5c408d4a0b193204a1d6.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-921a91b0ba3d5c408d4a0b193204a1d6.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-921a91b0ba3d5c408d4a0b193204a1d6 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-921a91b0ba3d5c408d4a0b193204a1d6 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-921a91b0ba3d5c408d4a0b193204a1d6 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/www.pnas.org\/content\/117\/23\/12576\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20359%20359&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/07\/PNAS-1.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/07\/PNAS-1.jpg 359w\" loading=\"eager\" style=\"--ratio: 359 \/ 359\" sizes=\"(max-width: 359px) 100vw, 359px\" width=\"359\" height=\"359\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/pnas-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988362336{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><span style=\"font-size: 12pt;\"><a href=\"https:\/\/www.pnas.org\/content\/117\/23\/12576\"><strong>Technoeconomic and life-cycle analysis of single-step catalytic conversion of wet ethanol into fungible fuel blendstocks<\/strong><\/a><\/span><\/p>\n<p style=\"text-align: justify;\"><strong>JUN-2020<\/strong> Sustainable biofuels are important for decarbonization of hard-to-abate sectors such as aviation, shipping and heavy-duty road transportation. The low cost of ethanol and large production capacity make it attractive to be converted into a hydrocarbon fuel, which is typically done in three steps. This work goes further and describes an economic and environmental analysis of a renewable aviation fuel obtained from a single-step catalytic process using ethanol from biomass as raw material, reducing the need for external hydrogen.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1594985352389{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-c5068d7a605b729f904e4cada0c03278.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-c5068d7a605b729f904e4cada0c03278.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-c5068d7a605b729f904e4cada0c03278 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-c5068d7a605b729f904e4cada0c03278 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-c5068d7a605b729f904e4cada0c03278 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/pubs.acs.org\/doi\/10.1021\/acscatal.0c01257\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20299%20299&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/07\/accacs.2020.10.issue-12.largecover-1.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/07\/accacs.2020.10.issue-12.largecover-1.jpg 299w\" loading=\"eager\" style=\"--ratio: 299 \/ 299\" sizes=\"(max-width: 299px) 100vw, 299px\" width=\"299\" height=\"299\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/accacs-2020-10-issue-12-largecover-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><span style=\"font-size: 12pt;\"><a href=\"https:\/\/pubs.acs.org\/doi\/10.1021\/acscatal.0c01257\"><strong>Substrate and Product-Assisted Catalysis: Molecular Aspects behind Structural Switches along Organic Hydroperoxide Resistance Protein Catalytic Cycle<\/strong><\/a><\/span><\/p>\n<p style=\"text-align: justify;\"><strong>MAY-2020<\/strong> Quantum and classical simulations of structurally resolved proteins can further the understanding of biocatalysis in biological systems susceptible to damage by oxidants. This work provides insights on the oxidation response of bacteria cells by investigating the role of the active site and the catalytic pathways to decompose oxidants in Ohr proteins. This is relevant to the identification of inhibitors with therapeutic potential.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_empty_space][vc_row_inner css=&#8221;.vc_custom_1594988379286{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594985959418{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-e7adcf21c83b95a3e436ab477173ba03.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-e7adcf21c83b95a3e436ab477173ba03.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-e7adcf21c83b95a3e436ab477173ba03 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-e7adcf21c83b95a3e436ab477173ba03 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-e7adcf21c83b95a3e436ab477173ba03 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/doi.org\/10.1016\/j.bbagen.2020.129549\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/08\/BBA-general-subj-novo-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/08\/BBA-general-subj-novo-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/08\/BBA-general-subj-novo.jpg 576w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/bba-general-subj-novo\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988371656{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1596452618540{margin-bottom: 4px !important;border-bottom-width: 4px !important;padding-bottom: 4px !important;}&#8221;]<\/p>\n<p style=\"text-align: justify;\"><span style=\"font-size: 10pt;\"><strong><span style=\"font-size: 12pt;\"><a href=\"https:\/\/doi.org\/10.1016\/j.bbagen.2020.129549\">Crystal structure of a novel xylose isomerase from <em>Streptomyces sp<\/em>. F-1 revealed the presence of unique features that differ from conventional classes<\/a><\/span><\/strong><\/span><\/p>\n<p style=\"text-align: justify;\"><strong>MAY-2020<\/strong> Biofuels from sugarcane residues require yeasts to metabolize pentoses from xylose and to operate at mild conditions. This is a challenge to enzymatic conversion of xylose to xylulose that can be addressed by reversible changes of enzyme configurations. This work reports two new and unique xylose isomerases with amino-acid substitutions in the catalytic interface and preference for isomerization at milder conditions. Molecular understanding of enzymes can contribute to customization of fermentation processes.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1594984335537{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243;][vc_column_text css=&#8221;.vc_custom_1594986085216{margin-bottom: 3px !important;border-bottom-width: 3px !important;padding-bottom: 3px !important;background-color: #81d742 !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>TECHNOLOGY<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-3de45f757c0e1efefa9fe93f1350b7f5.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-3de45f757c0e1efefa9fe93f1350b7f5.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-3de45f757c0e1efefa9fe93f1350b7f5 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-3de45f757c0e1efefa9fe93f1350b7f5 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-3de45f757c0e1efefa9fe93f1350b7f5 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/doi.org\/10.1016\/j.jclepro.2020.120081\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/08\/Journal-Cleaner-prod-novo-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/08\/Journal-Cleaner-prod-novo-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/08\/Journal-Cleaner-prod-novo.jpg 576w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/journal-cleaner-prod-novo\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><span style=\"font-size: 12pt;\"><a href=\"https:\/\/doi.org\/10.1016\/j.jclepro.2020.120081\"><strong>Process simulation of renewable electricity from sugarcane straw: Techno-economic assessment of retrofit scenarios in Brazil<\/strong><\/a><\/span><\/p>\n<p style=\"text-align: justify;\"><strong>MAY-2020 <\/strong>Brazil can further reduce greenhouse gas emissions by significantly increasing renewable electricity generated from biomass. This is due to environmental legislation that has progressively prohibited burning before sugarcane harvesting and led to high availability of straw. This work integrates both agricultural and industrial models to provide techno-economic assessments that can enable retrofit investments in existing biorefineries. It highlights the strong dependence on electricity prices of straw recovery projects.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_empty_space][vc_row_inner css=&#8221;.vc_custom_1594988391496{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594985968478{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594986104498{margin-bottom: 3px !important;border-bottom-width: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-c0c6d4e8c47b1d0d7d6ea093d9351b0c.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-c0c6d4e8c47b1d0d7d6ea093d9351b0c.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-c0c6d4e8c47b1d0d7d6ea093d9351b0c .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-c0c6d4e8c47b1d0d7d6ea093d9351b0c .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-c0c6d4e8c47b1d0d7d6ea093d9351b0c alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/biotechnologyforbiofuels.biomedcentral.com\/articles\/10.1186\/s13068-020-01732-w\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20306%20306&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/08\/Biotech-for-biofuels-novo-1.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/08\/Biotech-for-biofuels-novo-1.jpg 306w\" loading=\"eager\" style=\"--ratio: 306 \/ 306\" sizes=\"(max-width: 306px) 100vw, 306px\" width=\"306\" height=\"306\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/biotech-for-biofuels-novo-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988399619{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><span style=\"font-size: 12pt;\"><a href=\"https:\/\/biotechnologyforbiofuels.biomedcentral.com\/articles\/10.1186\/s13068-020-01732-w\"><strong>Rational engineering of the <em>Trichoderma reesei<\/em> RUT-C30 strain into an industrially relevant platform for cellulase production<\/strong><\/a><\/span><\/p>\n<p style=\"text-align: justify;\"><strong>MAY-2020 <\/strong>Sustainable biofuels are important for decarbonization of light-vehicle road transportation. Synthetic biology was used to develop a microbial platform for cellulase production to reduce the cost of cellulosic ethanol production. This work describes a Brazilian technology validated at industrial operating conditions, which employs rational design of a public domain strain for cellulosic on-site manufacture of enzymes for ethanol production from sugarcane residues.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1594985511328{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243;][vc_column_text css=&#8221;.vc_custom_1594986122121{margin-bottom: 3px !important;border-bottom-width: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-dc24ebaf6c7d33848362954822c44567.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-dc24ebaf6c7d33848362954822c44567.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-dc24ebaf6c7d33848362954822c44567 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-dc24ebaf6c7d33848362954822c44567 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-dc24ebaf6c7d33848362954822c44567 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/doi.org\/10.1016\/j.energy.2020.117422\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/11\/Energy-quadrada-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/11\/Energy-quadrada-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/11\/Energy-quadrada.jpg 576w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/energy-quadrada\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/doi.org\/10.1016\/j.energy.2020.117422\"><span style=\"font-size: 12pt;\"><strong>Techno-economic assessment of bioenergy and biofuel production in integrated sugarcane biorefinery: Identification of technological bottlenecks and economic feasibility of dilute acid pretreatment<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>MAY-2020 <\/strong>The production of cellulosic ethanol still faces challenges to become commercially competitive and impact circular economy. This work evaluated the production of cellulosic ethanol from the dilute acid pretreatment and subsequent enzymatic hydrolysis of the bagasse of a sugarcane hybrid (with low lignin content, high fiber content and high agricultural productivity). It is noteworthy that the costs of sugarcane production, investment in industrial equipment and costs of chemical inputs are the main factors that impact the economic viability of the evaluated process.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_empty_space][vc_row_inner css=&#8221;.vc_custom_1606303635379{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243;][vc_column_text css=&#8221;.vc_custom_1594986122121{margin-bottom: 3px !important;border-bottom-width: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>SCIENCE<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-036c1ec519c57b8ce00638dd1dd4d17a.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-036c1ec519c57b8ce00638dd1dd4d17a.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-036c1ec519c57b8ce00638dd1dd4d17a .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-036c1ec519c57b8ce00638dd1dd4d17a .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-036c1ec519c57b8ce00638dd1dd4d17a alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/www.nature.com\/articles\/s41589-020-0554-5\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20300%20300&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/07\/Nature-CHEM-BIO-1.png\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/07\/Nature-CHEM-BIO-1.png 300w\" loading=\"eager\" style=\"--ratio: 300 \/ 300\" sizes=\"(max-width: 300px) 100vw, 300px\" width=\"300\" height=\"300\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/nature-chem-bio-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><span style=\"font-size: 12pt;\"><a href=\"https:\/\/www.nature.com\/articles\/s41589-020-0554-5\"><strong>Structural insights into \u03b2-1,3-glucan cleavage by a glycoside hydrolase family<\/strong><\/a><\/span><\/p>\n<p style=\"text-align: justify;\"><strong>MAY-2020 <\/strong>Discovery of new enzymes for health, nutrition, biofuels, and other industrial biotechnological applications. Inspired by the molecular biodiversity of microorganisms this work has deepened the knowledge about new enzymatic strategies for the polysaccharides \u03b2-1,3-glucans processing, discovering a new mechanism of polysaccharide recognition and new mode of enzymatic action.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1606303643284{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594985980260{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594986132431{margin-bottom: 3px !important;border-bottom-width: 3px !important;padding-bottom: 3px !important;background-color: #81d742 !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>TECHNOLOGY<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-811e117dbd30775c4eb94e3bbca34c81.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-811e117dbd30775c4eb94e3bbca34c81.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-811e117dbd30775c4eb94e3bbca34c81 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-811e117dbd30775c4eb94e3bbca34c81 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-811e117dbd30775c4eb94e3bbca34c81 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/www.sciencedirect.com\/science\/article\/abs\/pii\/S0960852419319145?via%3Dihub\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/08\/biotechnology-res-novo-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/08\/biotechnology-res-novo-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/08\/biotechnology-res-novo.jpg 576w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/biotechnology-res-novo\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988413969{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><span style=\"font-size: 12pt;\"><a href=\"https:\/\/www.sciencedirect.com\/science\/article\/abs\/pii\/S0960852419319145?via%3Dihub\"><strong>Engineering aspects of hydrothermal pretreatment: From batch to continuous operation, scale-up and pilot reactor under biorefinery concept<\/strong><\/a><\/span><\/p>\n<p style=\"text-align: justify;\"><strong>MAR-2020 <\/strong>Sustainable biofuels are important for decarbonization of light-vehicle road transportation. Hydrothermal pre-treatment is considered one of the most promising technologies for cellulosic ethanol production. This review provides comprehensive information on hydrothermal pretreatment, including performance at semi-industrial scale (LNBR pilot plant) and discusses integrated process design.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1606303667510{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594985980260{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594986132431{margin-bottom: 3px !important;border-bottom-width: 3px !important;padding-bottom: 3px !important;background-color: #81d742 !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>TECHNOLOGY<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-d6eacda49b65c21c80a6941d34bfbac3.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-d6eacda49b65c21c80a6941d34bfbac3.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-d6eacda49b65c21c80a6941d34bfbac3 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-d6eacda49b65c21c80a6941d34bfbac3 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-d6eacda49b65c21c80a6941d34bfbac3 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/doi.org\/10.1111\/1751-7915.13556\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20500%20500&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/11\/Microbial-Biotech-quadrada-500x500.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/11\/Microbial-Biotech-quadrada-500x500.jpg 500w, https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/11\/Microbial-Biotech-quadrada.jpg 763w\" loading=\"eager\" style=\"--ratio: 500 \/ 500\" sizes=\"(max-width: 500px) 100vw, 500px\" width=\"500\" height=\"500\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/microbial-biotech-quadrada\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988413969{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/doi.org\/10.1111\/1751-7915.13556\"><span style=\"font-size: 12pt;\"><strong>Improvement of homologous GH10 xylanase production by deletion of genes with predicted function in the Aspergillus nidulans secretion pathway<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>MAR-2020 <\/strong>Filamentous fungi are important microbial platforms for biotechnological applications. One challenge is to achieve high protein production titers. In this work, the large-scale transcriptional analysis was used to identify genes involved in protein secretion pathways. Genetic modifications of these target genes resulted in strains with improved protein production, demonstrating it is an interesting strategy for the development of industrially relevant strains.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1606303680344{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243;][vc_column_text css=&#8221;.vc_custom_1594986164534{margin-bottom: 3px !important;border-bottom-width: 3px !important;padding-bottom: 3px !important;background-color: #8224e3 !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>PARTNERSHIP<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-ddbba48bacf84c4a45262423f17d07f2.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-ddbba48bacf84c4a45262423f17d07f2.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-ddbba48bacf84c4a45262423f17d07f2 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-ddbba48bacf84c4a45262423f17d07f2 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-ddbba48bacf84c4a45262423f17d07f2 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/www.jbc.org\/content\/295\/15\/5012\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20200%20200&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/07\/JBC29-1.gif\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/07\/JBC29-1.gif 200w\" loading=\"eager\" style=\"--ratio: 200 \/ 200\" sizes=\"(max-width: 200px) 100vw, 200px\" width=\"200\" height=\"200\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/jbc29-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243;][vc_column_text]<span style=\"font-size: 12pt;\"><a href=\"https:\/\/www.jbc.org\/content\/295\/15\/5012\"><strong>Spatially remote motifs cooperatively affect substrate preference of a ruminal GH26-type endo-\u03b2-1,4-mannanase<\/strong><\/a><\/span><\/p>\n<p style=\"text-align: justify;\"><strong>MAR-2020 <\/strong>Enzymes can improve digestibility of mannan oligosaccharides present in cattle diets. Thus, cattle rumen contains a microbial community highly adapted to breakdown of lignocellulosic biomass. This work, with a partnering company, indicates a novel, complex and cooperative mechanism between enzyme subsites and ancillary domain to modulate substrate preference. It furthers the molecular understanding of substrate binding and recognition in the GH26 family and exhibits potential industrial use.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1606303699374{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988529956{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594986174251{margin-bottom: 3px !important;border-bottom-width: 3px !important;padding-bottom: 3px !important;background-color: #81d742 !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>TECHNOLOGY<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-95e98c77d170955dbf2dbc4ff50beb1b.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-95e98c77d170955dbf2dbc4ff50beb1b.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-95e98c77d170955dbf2dbc4ff50beb1b .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-95e98c77d170955dbf2dbc4ff50beb1b .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-95e98c77d170955dbf2dbc4ff50beb1b alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"https:\/\/doi.org\/10.1007\/s00253-019-10318-y\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20138%20138&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/11\/Applied-Micro-Biotech-quadrada.jpg\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/11\/Applied-Micro-Biotech-quadrada.jpg 138w\" loading=\"eager\" style=\"--ratio: 138 \/ 138\" sizes=\"(max-width: 138px) 100vw, 138px\" width=\"138\" height=\"138\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/research-highlights\/applied-micro-biotech-quadrada\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988431142{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><a href=\"https:\/\/doi.org\/10.1007\/s00253-019-10318-y\"><span style=\"font-size: 12pt;\"><strong>Functional genomic analysis of bacterial lignin degraders: diversity in mechanisms of lignin oxidation and metabolism<\/strong><\/span><\/a><\/p>\n<p style=\"text-align: justify;\"><strong>FEB-2020 <\/strong>The valorization of biomass whole constituents is important for the development of new bioproducts and for decarbonization of the economy. In this work, genomic analyzes were used to identify several mechanisms employed by bacteria for the metabolism of lignin. These bacterial pathways may inspire the development of biotechnological applications to convert lignin into value-added products.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1606303988310{background-color: #ffffff !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988529956{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594986174251{margin-bottom: 3px !important;border-bottom-width: 3px !important;padding-bottom: 3px !important;background-color: #81d742 !important;}&#8221;]<\/p>\n<p style=\"text-align: center;\"><span style=\"color: #ffffff;\"><strong>TECHNOLOGY<\/strong><\/span><\/p>\n<p>[\/vc_column_text]<style type=\"text\/css\" data-type=\"the7_shortcodes-inline-css\">.shortcode-single-image-wrap.shortcode-single-image-35eab8679a34dbf8671855a3ed1d1210.enable-bg-rollover .rollover i,\n.shortcode-single-image-wrap.shortcode-single-image-35eab8679a34dbf8671855a3ed1d1210.enable-bg-rollover .rollover-video i {\n  background: -webkit-linear-gradient();\n  background: linear-gradient();\n}\n.shortcode-single-image-wrap.shortcode-single-image-35eab8679a34dbf8671855a3ed1d1210 .rollover-icon {\n  font-size: 32px;\n  color: #ffffff;\n  min-width: 44px;\n  min-height: 44px;\n  line-height: 44px;\n  border-radius: 100px;\n  border-style: solid;\n  border-width: 0px;\n}\n.dt-icon-bg-on.shortcode-single-image-wrap.shortcode-single-image-35eab8679a34dbf8671855a3ed1d1210 .rollover-icon {\n  background: rgba(255,255,255,0.3);\n  box-shadow: none;\n}\n<\/style><div class=\"shortcode-single-image-wrap shortcode-single-image-35eab8679a34dbf8671855a3ed1d1210 alignnone  enable-bg-rollover dt-icon-bg-off\" style=\"margin-top:0px; margin-bottom:0px; margin-left:0px; margin-right:0px; width:500px;\"><div class=\"shortcode-single-image\"><div class=\"fancy-media-wrap\" style=\"\"><a href=\"http:\/\/task39.sites.olt.ubc.ca\/files\/2020\/02\/Task-39-Phase-2.2-Ethanol-2G-Comparison-of-Biofuel-Life-Cycle-Analysis-Tools.pdf\" class=\" layzr-bg rollover\" style=\"\" target=\"_blank\" rel=\"noopener\" aria-label=\"Image\"><img decoding=\"async\" class=\"preload-me lazy-load aspect\" src=\"data:image\/svg+xml,%3Csvg%20xmlns%3D&#39;http%3A%2F%2Fwww.w3.org%2F2000%2Fsvg&#39;%20viewBox%3D&#39;0%200%20332%20332&#39;%2F%3E\" data-src=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/07\/2020-07-20-10_31_23-Window-1.png\" data-srcset=\"https:\/\/lnbr.cnpem.br\/wp-content\/uploads\/2020\/07\/2020-07-20-10_31_23-Window-1.png 332w\" loading=\"eager\" style=\"--ratio: 332 \/ 332\" sizes=\"(max-width: 332px) 100vw, 332px\" width=\"332\" height=\"332\"  data-dt-location=\"https:\/\/lnbr.cnpem.br\/en\/2020-07-20-10_31_23-window-2\/\" alt=\"\" \/><\/a><\/div><\/div><\/div>[\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988431142{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text]<\/p>\n<p style=\"text-align: justify;\"><span style=\"font-size: 12pt;\"><a href=\"http:\/\/task39.sites.olt.ubc.ca\/files\/2020\/02\/Task-39-Phase-2.2-Ethanol-2G-Comparison-of-Biofuel-Life-Cycle-Analysis-Tools.pdf\"><strong>Comparison of Biofuel Life Cycle Analysis Tools<\/strong><\/a><\/span><\/p>\n<p style=\"text-align: justify;\"><strong>DEC-2019 <\/strong>Life cycle assessment (LCA) is a tool to assess the environmental impacts of a product. LCA model differences challenge credibility of individual evaluations applied to greenhouse gas mitigation targets. This work, in partnership with the International Energy Agency, compares greenhouse gas emissions for cellulosic ethanol production using internationally accepted LCA models from Brazil, Canada, USA and the EU. It provides recommendations to promote transparency and harmonization of LCA models.<\/p>\n<p>[\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_empty_space][\/vc_column][vc_column width=&#8221;1\/4&#8243;][vc_accordion active_tab=&#8221;false&#8221; collapsible=&#8221;yes&#8221; style=&#8221;2&#8243;][vc_accordion_tab title=&#8221;RESEARCH&#8221;][vc_custom_heading text=&#8221;Research Divisions&#8221; font_container=&#8221;tag:p|text_align:left&#8221; google_fonts=&#8221;font_family:Open%20Sans%3A300%2C300italic%2Cregular%2Citalic%2C600%2C600italic%2C700%2C700italic%2C800%2C800italic|font_style:400%20regular%3A400%3Anormal&#8221; link=&#8221;url:https%3A%2F%2Fpages.cnpem.br%2Flnbrteste%2Fresearch%2Fdivisions%2F|title:LNBR%20%7C%20Research%20Divisions||&#8221;][vc_custom_heading text=&#8221;Research Highlights&#8221; font_container=&#8221;tag:p|text_align:left&#8221; google_fonts=&#8221;font_family:Open%20Sans%3A300%2C300italic%2Cregular%2Citalic%2C600%2C600italic%2C700%2C700italic%2C800%2C800italic|font_style:400%20regular%3A400%3Anormal&#8221; link=&#8221;url:https%3A%2F%2Fpages.cnpem.br%2Flnbrteste%2Fresearch-highlights%2F|title:LNBR%20%7C%20Research%20Highlights||&#8221;][vc_custom_heading text=&#8221;Scientific Publications&#8221; font_container=&#8221;tag:p|text_align:left&#8221; google_fonts=&#8221;font_family:Open%20Sans%3A300%2C300italic%2Cregular%2Citalic%2C600%2C600italic%2C700%2C700italic%2C800%2C800italic|font_style:400%20regular%3A400%3Anormal&#8221; link=&#8221;url:https%3A%2F%2Fpages.cnpem.br%2Flnbrteste%2Fscientific-publications%2F|title:LNBR%20%7C%20Scientific%20Publications||&#8221;][\/vc_accordion_tab][\/vc_accordion]<div class=\"hr-thin style-line\" style=\"width: 100%;border-color: #606060;border-top-width: 5px;\"><\/div>[vc_accordion active_tab=&#8221;1&#8243; collapsible=&#8221;yes&#8221; style=&#8221;2&#8243;][vc_accordion_tab title=&#8221;CONTACT US&#8221;][vc_column_text]<strong>General LNBR Inquiries<br \/>\n<\/strong><a href=\"mailto:lnbrcomunica@cnpem.br\">lnbrcomunica@cnpem.br<\/a><\/p>\n<div id=\"gtx-trans\" style=\"position: absolute; left: 104px; top: 6px;\">\n<div class=\"gtx-trans-icon\"><\/div>\n<\/div>\n<p>[\/vc_column_text][\/vc_accordion_tab][\/vc_accordion]<div class=\"hr-thin style-line\" style=\"width: 100%;border-color: #606060;border-top-width: 5px;\"><\/div>[vc_accordion active_tab=&#8221;false&#8221; collapsible=&#8221;yes&#8221; style=&#8221;2&#8243;][vc_accordion_tab title=&#8221;SHARE&#8221;][vc_column_text]<\/p>\n<div class=\"single-share-box\">\n<div class=\"share-buttons\"><a class=\"linkedin\" title=\"LinkedIn\" href=\"https:\/\/www.linkedin.com\/shareArticle?mini=true&amp;url=https%3A%2F%2Fpages.cnpem.br%2Flnbrteste%2Flideranca%2F&amp;title=Lideran%C3%A7a&amp;summary=&amp;source=LNBR\" target=\"_blank\" rel=\"noopener noreferrer\"><span class=\"social-text\">Share on LinkedIn<\/span><span class=\"screen-reader-text\">Share on LinkedIn<\/span><\/a><br \/>\n<a class=\"facebook\" title=\"Facebook\" href=\"http:\/\/www.facebook.com\/sharer.php?u=https%3A%2F%2Fpages.cnpem.br%2Flnbrteste%2Flideranca%2F&amp;t=Lideran%C3%A7a\" target=\"_blank\" rel=\"noopener noreferrer\"><span class=\"social-text\">Share on Facebook<\/span><span class=\"screen-reader-text\">Share on Facebook<\/span><\/a><br \/>\n<a class=\"twitter\" title=\"Twitter\" href=\"https:\/\/twitter.com\/share?url=https%3A%2F%2Fpages.cnpem.br%2Flnbrteste%2Flideranca%2F&amp;text=Lideran%C3%A7a\" target=\"_blank\" rel=\"noopener noreferrer\"><span class=\"social-text\">Tweet<\/span><span class=\"screen-reader-text\">Share on Twitter<\/span><\/a><br \/>\n<a class=\"whatsapp\" title=\"WhatsApp\" href=\"https:\/\/api.whatsapp.com\/send?text=Lideran%C3%A7a%20-%20https%3A%2F%2Fpages.cnpem.br%2Flnbrteste%2Flideranca%2F\" target=\"_blank\" rel=\"noopener noreferrer\" data-action=\"share\/whatsapp\/share\"><span class=\"social-text\">Share on WhatsApp<\/span><span class=\"screen-reader-text\">Share on WhatsApp<\/span><\/a><\/div>\n<p><!-- #content -->[\/vc_column_text][\/vc_accordion_tab][\/vc_accordion]<div class=\"hr-thin style-line\" style=\"width: 100%;border-color: #606060;border-top-width: 5px;\"><\/div>[\/vc_column][\/vc_row]<\/p>\n<\/div>\n<\/section>","protected":false},"excerpt":{"rendered":"<p>[vc_row][vc_column width=&#8221;3\/4&#8243;][vc_row_inner][vc_column_inner][vc_column_text] Selected highlights of scientific publications, technology developments and partnerships. [\/vc_column_text][\/vc_column_inner][\/vc_row_inner][vc_row_inner css=&#8221;.vc_custom_1594988184275{background-color: #f7f7f7 !important;}&#8221;][vc_column_inner width=&#8221;1\/5&#8243; css=&#8221;.vc_custom_1594988083140{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;}&#8221;][vc_column_text css=&#8221;.vc_custom_1594987229854{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px !important;padding-top: 3px !important;padding-bottom: 3px !important;background-color: #1e73be !important;}&#8221;] SCIENCE [\/vc_column_text][\/vc_column_inner][vc_column_inner width=&#8221;4\/5&#8243; css=&#8221;.vc_custom_1594988178545{margin-top: 3px !important;margin-bottom: 3px !important;border-top-width: 3px !important;border-bottom-width: 3px&hellip;<\/p>\n","protected":false},"author":3,"featured_media":0,"parent":0,"menu_order":0,"comment_status":"closed","ping_status":"closed","template":"","meta":{"_acf_changed":false,"_monsterinsights_skip_tracking":false,"_monsterinsights_sitenote_active":false,"_monsterinsights_sitenote_note":"","_monsterinsights_sitenote_category":0,"footnotes":"","_links_to":"","_links_to_target":""},"class_list":["post-46646","page","type-page","status-publish","hentry","description-off"],"acf":[],"_links":{"self":[{"href":"https:\/\/lnbr.cnpem.br\/en\/wp-json\/wp\/v2\/pages\/46646","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/lnbr.cnpem.br\/en\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/lnbr.cnpem.br\/en\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/lnbr.cnpem.br\/en\/wp-json\/wp\/v2\/users\/3"}],"replies":[{"embeddable":true,"href":"https:\/\/lnbr.cnpem.br\/en\/wp-json\/wp\/v2\/comments?post=46646"}],"version-history":[{"count":0,"href":"https:\/\/lnbr.cnpem.br\/en\/wp-json\/wp\/v2\/pages\/46646\/revisions"}],"wp:attachment":[{"href":"https:\/\/lnbr.cnpem.br\/en\/wp-json\/wp\/v2\/media?parent=46646"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}