脂质过氧化的产物及机制的最新进展。
An update on products and mechanisms of lipid peroxidation.
作者信息
Schneider Claus
机构信息
Division of Clinical Pharmacology, Department of Pharmacology, Vanderbilt University Medical School, Nashville, TN 37232-6602, USA.
出版信息
Mol Nutr Food Res. 2009 Mar;53(3):315-21. doi: 10.1002/mnfr.200800131.
Abstract
The free radical reaction of polyunsaturated fatty acids with molecular oxygen leads to hydroperoxides as the first stable products. From linoleic acid the two conjugated diene hydroperoxides at carbons 9 and 13 were considered the only primary products until the recent discovery of the bis-allylic 11-hydroperoxide. The 11-carbon is the site of the initial hydrogen abstraction, and the 11-hydroperoxide is formed without isomerization of the 9,10 and 12,13 cis double bonds. In the autoxidation reaction, bis-allylic hydroperoxides are obtained only in the presence of an efficient antioxidant, for example, alpha-tocopherol. The antioxidant functions as a hydrogen atom donor, necessary to trap the fleeting bis-allylic peroxyl radical intermediate as the hydroperoxide. Understanding of the mechanism of formation of bis-allylic hydroperoxides has led to increased appreciation of the central role of the intermediate peroxyl radical in determining the outcome of lipid peroxidation.
摘要
多不饱和脂肪酸与分子氧的自由基反应会生成氢过氧化物作为首个稳定产物。直到最近发现双烯丙基11-氢过氧化物之前,人们一直认为亚油酸在碳9和碳13位的两种共轭二烯氢过氧化物是唯一的初级产物。碳11位是最初氢原子被夺取的位点,并且11-氢过氧化物的形成并未导致9,10和12,13位顺式双键的异构化。在自氧化反应中,只有在高效抗氧化剂(例如α-生育酚)存在的情况下才能获得双烯丙基氢过氧化物。抗氧化剂作为氢原子供体,对于捕获转瞬即逝的双烯丙基过氧自由基中间体形成氢过氧化物是必需的。对双烯丙基氢过氧化物形成机制的理解使得人们更加认识到中间体过氧自由基在决定脂质过氧化结果中的核心作用。
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