亚油酸合成风味化合物己醛的生物与化学催化剂对比分析

Reactions Pub Date : 2023-09-18 DOI:10.3390/reactions4030031
Jan Drönner, Valentin Gala Marti, Simone Bandte, Anna Coenen, Ulrich Schörken, Matthias Eisenacher
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引用次数: 0

摘要

己醛、己烯醛、壬烯醛及其相应的醇在香精和香精工业中用作绿色调。生物基己醛的生产始于亚油酸,亚油酸可以从向日葵或红花油中获得。该生物催化过程利用c13特异性脂氧合酶(LOX)进行加氢过氧化并与氢过氧化物裂解酶(HPL)连续裂解。在这项研究中,我们研究了LOX产物13-HPODE的化学分裂与HPL催化的比较。此外,以红花油为原料,利用富集亚油酸合成了13-HPODE。不同数量的豆粉悬浮液作为LOX的来源,产生高达60%的HPODE,对13-HPODE的区域选择性为92%。使用低毒性的路易斯酸,如AlCl3和ZrCl4,产生的13- hopode的切割是可能的。在温和的反应条件下,AlCl3的己醛收率最高可达22.9%,但产物的降解是一个干扰过程。与n端截断木瓜HPL的比较试验显示,己醛回收率在相当范围内。此外,我们成功地证明了13-HPODE通过多相催化剂Hock重排的可行性。值得注意的是,β沸石和蒙脱土K10表现出与工业过程中使用的常见非均相催化剂相当的周转频率(TOF)。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Comparative Analysis of Bio- and Chemo-Catalysts for the Synthesis of Flavour Compound Hexanal from Linoleic Acid
Hexanal, hexenal, nonenal and their corresponding alcohols are used as green notes in the fragrance and flavour industry. The production of bio-based hexanal starts from linoleic acid, which can be obtained from sunflower or safflower oil. The biocatalytic process utilizes C13-specific lipoxygenase (LOX) for hydroperoxidation and consecutive splitting with hydroperoxide lyase (HPL). In this study, we investigated the chemical splitting of the LOX product 13-HPODE in comparison to HPL catalysis. In addition, 13-HPODE was synthesized using enriched linoleic acid from safflower oil. Varying amounts of soybean flour suspension as a source of LOX yielded up to 60% HPODE with a regioselectivity of 92% towards 13-HPODE. Using low-toxicity Lewis acids like AlCl3 and ZrCl4, cleavage of the produced 13-HPODE was possible. A maximum hexanal yield of 22.9% was reached with AlCl3 under mild reaction conditions, though product degradation was an interfering process. Comparative trials with N-terminal truncated HPL from papaya revealed hexanal recovery within a comparable range. Additionally, we successfully demonstrated the viability of Hock rearrangement of 13-HPODE through heterogeneous catalysts. Notably, Beta zeolite and Montmorillonite K10 exhibited a turnover frequency (TOF) on par with common heterogeneous catalysts employed in industrial processes.
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CiteScore
2.70
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