聚合度为 6-16 的壳寡糖的超氧自由基分离和清除活性。

Separation and scavenging superoxide radical activity of chitooligomers with degree of polymerization 6-16.

机构信息

Institute of Oceanology, Chinese Academy of Sciences, Qingdao 266071, China.

出版信息

Int J Biol Macromol. 2012 Dec;51(5):826-30. doi: 10.1016/j.ijbiomac.2012.07.031. Epub 2012 Aug 3.

DOI:10.1016/j.ijbiomac.2012.07.031

Abstract

The separation of chitooligomers (COS) with well-defined degree of polymerization (DP) is of interest to further study their bioactivity. However, there has been no report on separation of chitooligomers with DP>6 and the activity of these oligomers is unknown. This paper focuses on separating COS with DP>6 and five fractions were separated from the prepared fully deacetylated chitooligomers mixture by CM Sepharose Fast Flow column and analyzed by HPLC, which mainly contained glucosamine oligomers with DP6-7 (41.31%, 50.22%), DP7-8 (22.47%, 70.13%), DP9-10 (53.06%, 27.99%), DP10-12 (18.45%, 49.36%, 22.31%), and DP>12, respectively. The superoxide radical scavenging activity of each fraction was investigated. The oligomers with DP ranging from 10 to 12 exhibited higher scavenging activity than other fractions and in combination with the DP distribution of fractions, it was further concluded that the chitooligomers with DP11 was likely to be optimal for scavenging superoxide radical activity.

摘要

具有明确聚合度（DP）的壳寡糖（COS）的分离引起了人们的兴趣，以便进一步研究其生物活性。然而，目前还没有关于分离 DP>6 的壳寡糖的报道，这些寡糖的活性也不清楚。本文重点研究了 DP>6 的壳寡糖的分离，从制备的完全脱乙酰壳寡糖混合物中通过 CM Sepharose Fast Flow 柱分离得到了五个级分，并通过 HPLC 进行了分析，主要含有 DP6-7（41.31%、50.22%）、DP7-8（22.47%、70.13%）、DP9-10（53.06%、27.99%）、DP10-12（18.45%、49.36%、22.31%）和 DP>12 的葡糖胺寡糖。研究了各馏分的超氧自由基清除活性。DP 为 10 至 12 的寡糖表现出比其他馏分更高的清除活性，并且结合馏分的 DP 分布，进一步得出结论，DP11 的壳寡糖可能最有利于清除超氧自由基活性。

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聚合度为 6-16 的壳寡糖的超氧自由基分离和清除活性。

Separation and scavenging superoxide radical activity of chitooligomers with degree of polymerization 6-16.

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