Enzymatic conversion of camellia seed oil into glycerol esters: Synthesis and characterization

IF 1.9 4区农林科学 Q3 CHEMISTRY, APPLIED

Journal of the American Oil Chemists Society Pub Date : 2024-06-23 DOI:10.1002/aocs.12852

Jingzhi Wu, Jingjing Xiao, Suli Nie, Yan Chao, Peiwang Li, Changzhu Li, Zhihong Xiao, Hongmei Wu

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引用次数: 0

Abstract

The conversion of triacylglycerols in edible oils into diacylglycerols (DAGs) is of great significance for obtaining products with health benefits. Camellia seed oil (C-oil), which is rich in oleic acid and linoleic acid, is an excellent raw material for the production of DAGs. In this study, single factor optimization experiments were carried out for hydrolysis and esterification respectively. Using Lipozyme® RM IM as catalyst, the maximum percent of C-oil hydrolysis reached 87.14% at the reaction temperature of 60°C, reaction time of 24 h, water content of 30% and enzyme addition amount of 4%. The maximum content of camellia seed oil diacylglycerol (C-DAG) reached 62.49% under the conditions of Lipozyme® RM IM as catalyst, vacuum system, 3% enzyme addition, 2% water addition, reaction temperature of 50°C and substrate molar ratio of free fatty acid to glycerol of 1:1. The high content of DAG was obtained by a coupled method, which eliminated the purification steps and reduced production costs. C-oil and C-DAG have been characterized by GC, TG, DSC, and GC-IMS. Our results showed that the enzymatic coupling method did not affect the structural of the substances, but did affect the crystallization and melting properties of the oils. Moreover, the taste of C-DAG was more delicate than C-oil. Finally, the reaction mechanism was analyzed using FTIR spectroscopy, revealing that C-oil was primarily hydrolyzed into free fatty acids. C-DAG exhibited ester C-O stretching vibrations in the range 1280–1030 cm⁻¹, indicating successful esterification reaction between camellia seed oil free fatty acids (C-FFAs) and glycerol catalyzed by lipases.

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将山茶籽油酶促转化为甘油酯：合成与表征

将食用油中的三酰甘油转化为二酰基甘油（DAGs）对获得有益健康的产品具有重要意义。山茶籽油（C-oil）富含油酸和亚油酸，是生产 DAG 的绝佳原料。本研究对水解和酯化分别进行了单因素优化实验。以 Lipozyme® RM IM 为催化剂，在反应温度为 60°C、反应时间为 24 小时、含水量为 30%、酶添加量为 4% 的条件下，C-油的水解率最高可达 87.14%。在以 Lipozyme® RM IM 为催化剂，真空条件下，加酶量为 3%，加水量为 2%，反应温度为 50℃，底物游离脂肪酸与甘油摩尔比为 1:1 的条件下，山茶籽油二酰甘油（C-DAG）的最高含量达到 62.49%。通过耦合法获得了高含量的 DAG，省去了纯化步骤，降低了生产成本。C-oil 和 C-DAG 已通过 GC、TG、DSC 和 GC-IMS 进行了表征。结果表明，酶偶联法不会影响物质的结构，但会影响油的结晶和熔化特性。此外，C-DAG 的口感比 C 油更细腻。最后，利用傅立叶变换红外光谱分析了反应机理，发现 C-oil 主要水解为游离脂肪酸。C-DAG 在 1280-1030 cm-1 范围内呈现酯 C-O 伸展振动，表明山茶籽油游离脂肪酸与甘油在脂肪酶的催化下成功发生了酯化反应。

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来源期刊

Journal of the American Oil Chemists Society 工程技术-食品科技

CiteScore

4.10

自引率

5.00%

发文量

审稿时长

2.4 months

期刊介绍： The Journal of the American Oil Chemists’ Society (JAOCS) is an international peer-reviewed journal that publishes significant original scientific research and technological advances on fats, oils, oilseed proteins, and related materials through original research articles, invited reviews, short communications, and letters to the editor. We seek to publish reports that will significantly advance scientific understanding through hypothesis driven research, innovations, and important new information pertaining to analysis, properties, processing, products, and applications of these food and industrial resources. Breakthroughs in food science and technology, biotechnology (including genomics, biomechanisms, biocatalysis and bioprocessing), and industrial products and applications are particularly appropriate. JAOCS also considers reports on the lipid composition of new, unique, and traditional sources of lipids that definitively address a research hypothesis and advances scientific understanding. However, the genus and species of the source must be verified by appropriate means of classification. In addition, the GPS location of the harvested materials and seed or vegetative samples should be deposited in an accredited germplasm repository. Compositional data suitable for Original Research Articles must embody replicated estimate of tissue constituents, such as oil, protein, carbohydrate, fatty acid, phospholipid, tocopherol, sterol, and carotenoid compositions. Other components unique to the specific plant or animal source may be reported. Furthermore, lipid composition papers should incorporate elements of yeartoyear, environmental, and/ or cultivar variations through use of appropriate statistical analyses.