引进俄罗斯第三代沙棘无性系果实黄酮类化合物研究
Study on Flavonoids in Fruits of Third Generation Seabuckthorn Clones Introduced from Russia

DOI: 10.12677/HJFNS.2022.111002, PP. 11-20

Keywords: 引进沙棘，果实，高效液相色谱法，糖苷，苷元
Introduced Seabuckthorn, Fruits, GC-MS, Glycosides, Aglycone

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Abstract:

为了掌握我国引进沙棘果实所含黄酮类化合物情况，对黑龙江、辽宁、新疆3地定植的21个无性系，以及用于对比的4个杂交沙棘无性系，采集果实样品48个，采用高效液相色谱法(HPLC)，检测得到主要7个黄酮类化合物——5个糖苷、2个苷元，这些成分含量果肉普遍高于籽；糖苷类5种化合物干基含量合计达19.854 mg/100g，比苷元类2种化合物干基含量合计值14.601 mg/100g高36.0%，不过2种苷元类的单个化合物含量普遍都高于糖苷类5个化合物；引进沙棘7种黄酮化合物干基含量也只占杂交沙棘的54.7%~92.8%，杂交沙棘果实黄酮类化合物含量均高于引进沙棘；引进沙棘21个无性系中，黄酮类化合物含量较高的有“201316”“201301”“201319”“201317”“201315”共5个无性系。引进、杂交两大类沙棘果实含有的黄酮糖苷、苷元等一些生物活性成分较为丰富，作为保健和药用的前景看好。
For understanding the flavonoids contained in seabuckthorn introduced from Russia, 48 fruit samples were collected from 21 introduced clones and 4 hybrid clones for comparison planted in Heilongjiang, Liaoning and Xinjiang. Seven main flavonoids—5 glycosides and 2 aglycones were detected by high performance liquid chromatography (HPLC). The content of these components in pulp was generally higher than that in seed. The total dry basis content of five kinds of glycosides was 19.854 mg/100g, 36.0% higher than the total dry basis content of 14.601 mg/100g two kinds of aglycone, but the content of anyone of the two kinds of aglycone was generally higher than that of each glycoside. The dry basis content of seven flavonoids from introduced seabuckthorn only accounted for 54.7% ~ 92.8% of hybrid seabuckthorn, and the content of flavonoids in hybrid seabuckthorn fruit was higher than that of introduced seabuckthorn. Among the 21 introduced seabuckthorn clones, 5 clones with high content of flavonoids were “201316” “201301” “201319” “201317” and “201315”. The introduced and hybrid seabuckthorn fruits contain abundant bioactive components such as flavonoids, glycosides and aglycones, which would have a promising prospect as health care and medicine.

References

[1]	胡建忠, 邰源临, 李永海. 砒耗岩区沙棘生态控制系统工程及产业化开发[M]. 北京: 中国水利水电出版社, 2015: 265-266.
[2]	方一杰, 徐岩成, 安毛毛, 王芳, 姜远英. 黄酮类化合物的药动学和药理作用研究进展[J]. 药学服务与研究, 2015, 15(1): 6-9.
[3]	Veitch, N.C. and Grayer, R.J. (2008) Flavonoids and Their Glycosides, Including Anthocyanins. Natural Product Reports, 25, 555-611. https://doi.org/10.1039/b718040n
[4]	俞文英, 张欢欢, 吴月国, 赵铮蓉, 余陈欢. 黄酮类化合物的构效关系及其在肺部炎症疾病中的应用[J]. 中草药, 2018, 49(20): 4912-4918.
[5]	Geissman, T.A. (1962) The Chemistry of Flavonoid Compounds. Pergamon Press, Oxford, London, New York, Paris, 1-25.
[6]	祁建宏, 董芳旭. 黄酮类化合物药理作用研究进展[J]. 北京联合大学学报, 2020, 34(3): 89-92.
[7]	郑丽, 刘振春, 张星, 刘想. 紫薯茎叶中黄酮的提取及其功能性研究进展[J]. 食品安全质量检测学报, 2016, 7(9): 3566-3573.
[8]	黄河胜, 马传庚, 陈志武. 黄酮类化合物药理作用研究进展[J]. 中国中药杂志, 2000, 25(10): 589-592.
[9]	吴晓军, 李桂新, 张景瑜, 郑建文 赵勤. 心达康治疗冠心病心绞痛的Meta分析[J]. 中国药物评价, 2017, 34(6): 454-457.
[10]	曹竑, 陈广仁, 王爱国. 沙棘黄酮类化合物及其生理功能探究[J]. 饮料工业, 2003, 6(6): 5-9.
[11]	周吉银, 刘莹, 周世文. 沙棘总黄酮抗心血管疾病和代谢综合征作用研究进展[J]. 中药药理与临床, 2012, 28(6): 152-155.
[12]	王军宪, 王启祥, 李星海, 雷海民, 付国琴. 沙棘叶黄酮苷元类成分研究初报[J]. 沙棘, 1997(3): 33-34.
[13]	杨金鑫, 常薇, 刘伶文, 王晓军. 高效液相色谱法测定银杏叶提取物中的黄酮醇苷[J]. 纺织高校基础科学学报, 2020, 33(4): 118-122.
[14]	李博艺, 谌柄旭, 魏志阳, 王希彬, 肖冬光. 高效液相色谱法测定山楂黄酮的研究[J]. 中国酿造, 2018, 37(3): 157-161.
[15]	张颖, 王晴, 钱玉梅, 李红侠, 曹稳根. 黄酮类化合物的提取及生物活性研究综述[J]. 山东化工, 2020, 49(9): 96-97+99.
[16]	栗明月, 焦梦荷, 蒋林树, 方洛云. 竹叶黄酮的生理功能及其应用前景[J]. 中国农学通报, 2018, 34(32): 144-149.
[17]	国家药典委员会. 中华人民共和国药典 2010年版(一部) [M]. 北京: 中国医药科技出版社, 2010: 171-172.
[18]	刘萍, 郑亚安, 王怡斯, 孙君社. 沙棘叶黄酮糖苷生物转化黄酮苷元研究[J]. 高校化学工程学报, 2006, 20(6): 996-1000.
[19]	陈时宏. 黄酮类化合物的抗氧作用及其构效关系(综述) [J]. 海峡药学, 1998, 10(4): 4-6.
[20]	张英, 吴晓琴, 陈秀俊. 竹叶黄酮糖苷的水解及其苷元的抗氧化性能研究——I 黄酮糖苷水解工艺的响应面法优化[J]. 中国粮油学报, 2001(3): 34-37.

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