| 光谱学与光谱分析 |
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| Determination of Seven Metal Elements in Yunnan Wild Schizophyllum commune Fr by Atomic Absorption Spectrometry |
| GUO Jun-ming1,BAI Hong-li1,ZHANG Hong2,WANG Bao-sen2,CUI Qian2,LIU Gui-yang2 |
1. School of Chemistry and Biotechnology, Yunnan University of Nationalities, Kunming 650031, China
2. College of Science, Honghe University,Mengzi 661100,China |
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Abstract The seven metal elements in Yunnan wild schizophyllum commune Fr, including Zn,Co,Ni,Cu,Fe,Cr and Mg, were determined by atomic absorption spectrometry for providing a scientific basis of the development. The results show that Zn, Co, Ni, Fe, Cr and Mg are relatively rich in schizophyllum commune Fr and the content of Cu is lower. The ratio of the content of Zn to that of Cu is 7.4, which is consistent with the relative content level of Zn and Cu contained in many anticancer Chinese traditional plants, implying that the nutritive value of Yunnan wild schizophyllum commune Fr is high.
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Received: 2009-10-23
Accepted: 2010-01-26
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Corresponding Authors:
GUO Jun-ming
E-mail: guojunming@tsinghua.org.cn
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[1] MAO Xiao-lan(卯晓岚). Chinese Larger Members Fungi(中国大型真菌). Zhengzhou: Henan Science and Technology Press(郑州: 河南科学技术出版社), 2000. 79.
[2] ZHAO Qi, YUAN Li-chun, LI Rong-chun((赵 琪, 袁理春, 李荣春). Acta Edible Fungi(食用菌学报), 2004, 11(1): 59.
[3] Robertson C I,Bartholomew K A,Novotny C P,et al. Genetics(USA),1996,144(4): 1437.
[4] LI Zhao-lan(李兆兰). Journal of Nanjing University(Natural Sciences Edition)(南京大学学报·自然科学版),1994, 30(3): 482.
[5] HU De-qun,HU Ming,LUO Lan, et al(胡德群,胡 鸣,骆 兰,等). Sichuan Journal of Research on Chinese Drugs and Herbs(四川中草药研究),1994,36: 21.
[6] Mackenzie C R,Bilous D. Applied and Environmental Microbiology,1988,54(5): 1170.
[7] DENG Bai-wan,CHEN Wen-qiang,LI Zhi-zhou(邓百万,陈文强,李志洲). Amino Acids & Biotic Resources(氨基酸和生物资源), 2003, 25(4): 1.
[8] GUO Meng-bi, TIAN Mao-jun,LI Cong,et al(郭孟璧,田茂军,李 聪,等). Modern Instruments(现代仪器),2006,12(1): 22.
[9] MAO Shao-chun, LI Zhu-ying, LI Cong(毛绍春,李竹英,李 聪). Natural Product Research and Development(天然产物研究与开发),2007, 19: 610. |
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