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| Study on Drug Substance Accumulation of Polygala Tenuifolia in
Different Years Based on FTIR |
| LI Hui, LI Jian-li, SU Qi-hui, HUANG Yu-rong, CHENG Yan-gang, GAO Rui-rui, WANG Ying-li*, ZHAN Hai-xian* |
College of Traditional Chinese Medicine and Food Engineering,Shanxi University of Chinese Medicine,Jinzhong 030619,China
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Abstract To analyze the accumulation rule of pharmacodynamic substances of characteristic chemical constituents of Radix polygala in different growth years. FTIR was used to scan and analyze 12 batches of Radix polyphyllum with different growth years in Fenyang and Xinjiang of Shanxi Province. The infrared fingerprint of Radix polyphyllum was established, and the sequence of common peak rate and variation peak rate was analyzed. There were obvious common absorption peaks at 3 130, 2 920, 1 650, 1 540, 1 400, 1 260 and 1 050 cm-1. The characteristic absorption peaks of ethanol extract were in the range of 3 150~3 000, 2 950~2 920, 2 850, 1 740~1 710, 1 670~1 630, 1 540~1 520, 1 450~1 400, 1 100~1 050, 990, 530 cm-1. The number of absorption peaks increased with the increase of age. In the same year, there were differences in the number, shape and strength of absorption peaks near 3 380, 1 315, 1 060 and 990 cm-1 for P. polygonum, and the number, shape and strength of absorption peaks near 3 360 and 1 315 cm-1 for alcohol extract, and there was no characteristic absorption of P. polygonum in autumn. In terms of the accumulation of pharmacodynamic substances, the accumulation of pharmacodynamic substances in Fenyang and Xinjiang polygonum was larger in spring harvesting, and the accumulation of tenuifolin in fenyang polygonum, 3,6’-Disinapoylsucrose, and Polygalaxanthone Ⅲ increased with the growth of polygonum. The accumulation of 3,6’-Disinapoylsucrose increased firstly and then decreased, while the contents of Polygalaxanthone Ⅲ and some tenuifolin decreased with the increase of growth years. The common peak rates were 66.7%~100%, the variation peak rates were 0~63.6%, the common peak rates of alcohol extract were 66.7%~94.7%, and the variation peak rates were 0~30.0%. The common peak rate of the same period was high, and the peak rate between spring and autumn harvests was high. The common peak rate was high, and the accumulation of pharmacodynamic substances was similar to the increase in age, but there was no significant difference. The highest mutation peak rate was S-2-3 (picked in spring) and S-2-5 (picked in autumn), which was 63.6%. The two sequences were harvested in different seasons in different years, and the accumulation of pharmacodynamic substances differed greatly. The characteristic peaks of effective chemical components and the accumulation of pharmacodynamic substances of P. polygonum in different growth years can be analyzed and explored based on infrared spectroscopy and second derivative combined with double index sequence analysis, which can provide a reference for quality evaluation of Polygala tenuifolia.
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Received: 2022-02-11
Accepted: 2022-06-06
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Corresponding Authors:
WANG Ying-li, ZHAN Hai-xian
E-mail: wyl@sxtcm.edu.cn;zhan030006@126.com
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[1] PU Ya-jie,WANG Dan-dan,ZHANG Fu-sheng,et al(蒲雅洁,王丹丹,张福生,等). Chinese Traditional and Herbal Drugs(中草药),2017,48(1):211.
[2] Chinese Pharmacopoeia Commission(中华人民共和国药典委员会). Pharmacopoeia of the People’s Republic of China(中华人民共和国药典). Beijing: China Medical Science Press(北京: 中国医药科技出版社),2020.
[3] ZHANG Tao-zhen,RONG Wei-wei,LI Qing,et al(张陶珍,荣巍巍,李 清,等). Chinese Traditional and Herbal Drugs(中草药),2016,47(13):2381.
[4] LIU Lu,FENG Wei-hong,LIU Xiao-qian,et al(刘 露,冯伟红,刘晓谦,等). China Journal of Chinese Materia Medica(中国中药杂志),2021,46(22):5744.
[5] LI Ya-ni,WEI Feng-hua,JI Xin-yan,et al(李亚妮,魏凤华,季新燕,等). Chinese Journal of Modern Applied Pharmacy(中国现代应用药学),2014,31(2):159.
[6] LUO Lu,HU Ben-xiang,CAO Fu-lin,et al(罗 露,胡本祥,曹福麟,等). Lishizhen Medicine and Materia Medica Research(时珍国医国药),2019,(8):1895.
[7] WANG Zhen-jie,CAO Zhen,ZHAO Jian-cheng,et al(王振杰,曹 珍,赵建成,等). Journal of Chinese Medicinal Materials(中药材),2017,40(4):807.
[8] WANG Xiao-min,SHI Guan-ying,WANG Zhao-gai,et al(王晓敏,史冠莹,王赵改,等). Science and Technology of Food Industry(食品工业科技),2019,40(20):231.
[9] AGIGU Abudurexiti,CHU Gang-hui,TUOHATIAJI Maimaitiaili,et al(阿吉姑·阿布都热西提,楚刚辉,托哈提阿吉·麦麦提艾力,等). Chinese Journal of Experimental Traditional Medical Formulae(中国实验方剂学杂志),2015,21(17):47.
[10] WU Fang-bin,GAO Shan-shan,WEI Xue-min,et al(吴方斌,高姗姗,韦学敏,等). Journal of Chinese Medicinal Materials(中药材),2017,40(3):543.
[11] LIANG Yue,LI Bo,LIU Tao,et al(梁 悦,李 波,刘 涛,等). Chinese Traditional Patent Medicine(中成药),2019,41(6):1399.
[12] LI Chao,HUANG Xian-zhang,ZHANG Chao-yun,et al(李 超,黄显章,张超云,等). Journal of Chinese Medicinal Materials(中药材),2019,42(1):51.
[13] ZHOU Feng-ran,HAN Qiao,ZHANG Ti-qiang,et al(周枫然,韩 桥,张体强,等). Chemical Reagents(化学试剂),2021,43(8):1001.
[14] HAN Jia-xin,CHEN Chang-yun(韩嘉欣,陈昌云). Chemical Research and Application(化学研究与应用),2018,30(12):2008.
[15] LI Yu-xin,XING Na,ZHANG Zhi-hong,et al(李雨昕,邢 娜,张志宏,等). China Pharmacy(中国药房),2021,32(18):2194.
[16] ZHANG Fu-sheng,CHEN Tong-yao,WANG Dan-dan,et al(张福生,陈彤垚,王丹丹,等). Chinese Traditional and Herbal Drugs(中草药),2017,48(12):2538.
[17] XUE Ying,LI Xiao-wei,LI Zhen-yu,et al(薛 英,李晓伟,李震宇,等). Acta Pharmaceutica Sinica(药学学报),2015,50(3):340.
[18] ZHANG Wei-fang,FAN Ke-feng,LEI Jing-wei,et al(张维方,樊克锋,雷敬卫,等). Spectroscopy and Spectral Analysis(光谱学与光谱分析),2021,41(11):3392.
[19] CHEN Qian-feng,HOU Peng,LIU Qiao,et al(陈前锋,侯 鹏,刘 巧,等). Journal of Southwest University(Natural Science Edition)[西南大学学报)自然科学版)],2016,38(6):188.
[20] IANG Li,ZHANG Gui-jun,ZHAO Bao-sheng,et al(向 丽,张贵君,赵保胜,等). Chinese Journal of Experimental Traditional Medical Formulae(中国实验方剂学杂志),2017,23(8):57.
[21] LIU Yan-yan,LIU Jian-fei,XING Lian-xi,et al(刘妍妍,刘建飞,邢连喜,等). Natural Product Research and Development(天然产物研究与开发),2022,34(5):887.
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