通过 CLEA 技术固定 Eversa Transform，将其转化为适合使用废食用油生产生物润滑剂的生物催化剂。

Immobilization of Eversa Transform via CLEA Technology Converts It in a Suitable Biocatalyst for Biolubricant Production Using Waste Cooking Oil.

机构信息

Postgraduate Program in Chemical Engineering (PPGEQ), Department of Chemical Engineering, Federal University of São Carlos (DEQ/UFSCar), Rod. Washington Luís, km 235, 13565-905 São Carlos, SP, Brazil.

Departamento de Biocatálisis, ICP-CSIC, Campus UAM-CSIC, 28049 Madrid, Spain.

出版信息

Molecules. 2021 Jan 2;26(1):193. doi: 10.3390/molecules26010193.

DOI:10.3390/molecules26010193

PMID:33401727

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7794791/

Abstract

The performance of the previously optimized magnetic cross-linked enzyme aggregate of Eversa (Eversa-mCLEA) in the enzymatic synthesis of biolubricants by transesterification of waste cooking oil (WCO) with different alcohols has been evaluated. Eversa-mCLEA showed good activities using these alcohols, reaching a transesterification activity with isoamyl alcohol around 10-fold higher than with methanol. Yields of isoamyl fatty acid ester synthesis were similar using WCO or refined oil, confirming that this biocatalyst could be utilized to transform this residue into a valuable product. The effects of WCO/isoamyl alcohol molar ratio and enzyme load on the synthesis of biolubricant were also investigated. A maximum yield of around 90 wt.% was reached after 72 h of reaction using an enzyme load of 12 esterification units/g oil and a WCO/alcohol molar ratio of 1:6 in a solvent-free system. At the same conditions, the liquid Eversa yielded a maximum ester yield of only 34%. This study demonstrated the great changes in the enzyme properties that can be derived from a proper immobilization system. Moreover, it also shows the potential of WCO as a feedstock for the production of isoamyl fatty acid esters, which are potential candidates as biolubricants.

摘要

已评估了先前优化的用于通过废烹饪油 (WCO) 与不同醇的酯交换酶法合成生物润滑剂的可逆变构酶交联酶聚集体 (Eversa-mCLEA) 在酶法合成生物润滑剂中的性能。Eversa-mCLEA 在使用这些醇时表现出良好的活性，其与异戊醇的转酯活性比与甲醇的转酯活性高约 10 倍。使用 WCO 或精炼油进行异戊酸脂肪酸酯合成的产率相似，这证实了这种生物催化剂可用于将这种残留物转化为有价值的产品。还研究了 WCO/异戊醇摩尔比和酶负荷对生物润滑剂合成的影响。在无溶剂体系中，当酶负荷为 12 个酯化单位/克油，且 WCO/醇摩尔比为 1:6 时，反应 72 小时后，达到了约 90wt.%的最大产率。在相同条件下，液体 Eversa 的最大酯产率仅为 34%。这项研究表明，适当的固定化系统可以使酶的性质发生巨大变化。此外，它还展示了 WCO 作为生产异戊酸脂肪酸酯的原料的潜力，异戊酸脂肪酸酯是生物润滑剂的潜在候选物。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/6ce9/7794791/a0f9beb99c6a/molecules-26-00193-g001.jpg

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通过 CLEA 技术固定 Eversa Transform，将其转化为适合使用废食用油生产生物润滑剂的生物催化剂。

Immobilization of Eversa Transform via CLEA Technology Converts It in a Suitable Biocatalyst for Biolubricant Production Using Waste Cooking Oil.

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