基于主成分分析和聚类分析的不同产地绒柄牛肝菌红外光谱鉴别研究

doi:10.3964/j.issn.1000-0593(2016)06-1726-05

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摘要：采用傅里叶变换红外光谱结合主成分分析和聚类分析建立快速鉴别不同产地绒柄牛肝菌的方法。采集15个产地绒柄牛肝菌样品的红外光谱信息，用多元散射校正(multiplicative signal correction, MSC)、二阶求导(Second derivative, SD)、Norris平滑的组合方法对原始光谱进行优化处理，MSC+SD+ND(15，5)预处理后的光谱数据进行主成分分析和聚类分析，并通过主成分载荷图分析不同产地绒柄牛肝菌样品差异的原因。结果显示，该方法的重现性，精密度及稳定性的RSD值分别为0.17%, 0.08%, 0.27%，表明方法稳定、可靠。主成分分析的前3个主成分累积贡献率达到87.24%，能表达红外光谱的主要信息，主成分得分散点图中同一产地样品成簇聚集，不同产地样品分布于相对独立的空间，能有效区分不同产地样品。主成分载荷图显示，随主成分贡献率降低，主成分所捕获的样品信息减少，其中PC1在3 571, 2 958, 1 625, 1 456, 1 405, 1 340, 1 191, 1 143, 1 084, 935, 840, 727 cm^-1波数捕获大量样品信息，归属为糖类、蛋白质、氨基酸、脂肪、纤维素等化学物质的吸收峰，表明这些化学物质含量的差异是区分不同产地绒柄牛肝菌样品的主要依据。基于离差平方和法(Ward method)及欧氏距离(Euclidean distance)进行聚类分析，能直观显示不同产地样品的分类情况及样品之间的相关性，15个产地样品基本能够按照产地来源正确聚类，正确率为93.33%。傅里叶变换红外光谱结合主成分分析和聚类分析，可以有效鉴别绒柄牛肝菌产地来源，并且能够分析不同产地样品具有差异的原因，为野生食用菌的鉴别分类和应用研究提供可靠依据。

关键词：红外光谱;主成分载荷分析;绒柄牛肝菌;鉴别

Abstract：With the aim of establishing a rapid method to discriminate Boletus tomentipes samples from different regions, FTIR spectroscopy with the aid of principal component analysis and clustering analysis were used in the present study. The information of infrared spectra of B. tomentipes samples originated from 15 regions has been collected. The original infrared spectra was pretreated by multiplicative signal correction (MSC) in combination with second derivative and Norris smooth. The spectral data were analyzed by principal component analysis and cluster analysis after the optimal pretreatment of MSC+SD+ND (15, 5), and the reasons for the differences of B. tomentipes samples from different regions could be explained through the principal component loading plot. The results showed that, the RSDs of repeatability, accuracy and stability of the method were 0.17%, 0.08% and 0.27%, respectively, which indicated the method was stable and reliable. The cumulative contribution of first three principal components of PCA was 87.24% which could reflect the most information of the samples. Principal component scores scatter plot displaying the samples from same origin could clustered together and samples from different areas distributed in a relatively independent space. Which can distinguish samples collected from different origins, effectively. The loading plot of principal component showed that with the principal component contribution rate decreasing, the captured sample information of principal component was also reducing. In the wave number of 3 571, 2 958, 1 625, 1 456, 1 405, 1 340, 1 191, 1 143, 1 084, 935, 840, 727 cm^-1, the first principal component captured a large amount of sample information which attributed to carbohydrates, proteins, amino acids, fat, fiber and other chemical substances. Which showed that the different contents of these chemical substances may be the basis of discrimination of B. tomentipes samples from different origins. Cluster analysis based on ward method and Euclidean distance has shown the classification and correlation among samples. Samples originated from 15 regions could be clustered correctly in accordance with the basic origins and the correct rate was 93.33%. Which can be used to identify and analyze B. tomentipes collected from different sites. Fourier transform infrared spectroscopy combined with principal component analysis and cluster analysis can be effectively used to discriminate origins of B. tomentipes mushrooms and the reasons for the differences of B. tomentipes samples from different regions could be explained. This method could provide a reliable basis for discrimination and application of wild edible mushrooms.

Key words：Infrared spectroscopy;Principal component loadings analysis;Boletus tomentipes;Discrimination

收稿日期: 2014-12-30 修订日期: 2015-03-23

中图分类号:

TS201.2

通讯作者: 王元忠，刘鸿高 E-mail: boletus@126.com; honggaoliu@126.com

引用本文:

杨天伟^{1, 2}，张霁²，李涛³，王元忠^2*，刘鸿高^1*. 基于主成分分析和聚类分析的不同产地绒柄牛肝菌红外光谱鉴别研究[J]. 光谱学与光谱分析, 2016, 36(06): 1726-1730.
YANG Tian-wei^{1, 2}, ZHANG Ji², LI Tao³, WANG Yuan-zhong^2*, LIU Hong-gao^1*. Discrimination of Boletus Tomentipes from Different Regions Based on Infrared Spectrum Combined with Principal Component Analysis and Cluster Analysis. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2016, 36(06): 1726-1730.

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[1] Yin L L, Shi G Q, Tian Q, et al. Journal of Food Science, 2012, 77(8): T151.
[2] LI Tai-hui, SONG Bin(李泰辉, 宋斌). Acta Edulis Fungi(食用菌学报), 2002, 9(2): 22.
[3] MAO Xiao-lan(卯晓岚). The Macrofungi in China(中国大型真菌). Zhengzhou: Henan Science and Technology Press(郑州：河南科学技术出版社), 2000, 322.
[4] Feng B, Xu J, Wu G, et al. PLoS One, 2012, 7(5): e37567.
[5] LI Tao, WANG Yuan-zhong, LI Rong-chun(李涛, 王元忠, 李荣春). Acta Edulis Fungi(食用菌学报), 2009, 15(4): 70.
[6] Kalac P, Svoboda L. Food Chemistry, 2000, 69(3): 273.
[7] Kalac P. Food Chemistry, 2009, 113(1): 9.
[8] YIN Jian-zhong, ZHOU Ling-xian(殷建忠, 周玲仙). Food Research and Development(食品研究与开发), 2008, 29(7): 133.
[9] Wang X M, Zhang J, Wu L H, et al. Food Chemistry, 2014, 151: 279.
[10] Ramírez-Anguiano A C, Santoyo S, Reglero G, et al. Journal of the Science of Food and Agriculture, 2007, 87(12): 2272.
[11] Vamanu E, Nita S. BioMed Research International, 2012, 2013: 1.
[12] NI Zong-yao(倪宗耀). Edible and Medicinal Mushrooms(食药用菌), 2013, 21(1): 22.
[13] LI Shu-hong, ZHAO Yong-chang, YU Fu-qiang, et al(李树红, 赵永昌, 于富强, 等). Edible Fungi of China(中国食用菌), 2011, 30(5): 34.
[14] Dentinger B T M, Suz L M. Peer J PrePrints, 2014, 2: e570.
[15] Sitta N, Floriani M. Economic Botany, 2008, 62(3): 307.
[16] Zhao K, Wu G, Feng B, et al. Mycological Progress, 2014, 13(4): 1127.
[17] Li Y C, Feng B, Yang Z L. Fungal Diversity, 2011, 49(1): 125.
[18] Zeng N K, Cai Q, Yang Z L. Mycologia, 2012，104(6): 1420.
[19] Dubost N J, Beelman R B, Peterson D, et al. International Journal of Medicinal Mushrooms, 2006, 8: 215.
[20] YANG Tian-wei, LI Tao, ZHANG Ji, et al(杨天伟, 李涛, 张霁, 等). Food Science(食品科学), 2014, 35(16): 105.
[21] ZHOU Zai-jin, LIU Gang, REN Xian-pei(周在进, 刘刚, 任先培). Laser and Infrared(激光与红外), 2009, 39(11): 1158.
[22] Jawaid S, Talpur F N, Afiridi I H, et al. Analytical Methods, 2014, 6: 5269.
[23] HAN Lin-na, ZHOU Feng-qin(韩琳娜, 周凤琴). The Journal of Light Scattering(光散射学报), 2011, 23(2): 181.
[24] Che Man Y B, Marina A M, Rohman A, et al. International Journal of Food Properties, 2014, 17(2): 354.
[25] Alamprese C, Casale M, Sinelli N, et al. LWT-Food Science and Technology, 2013, 53(1): 225.
[26] Yao X, Peng Y, Zhou Q, et al. Journal of Molecular Structure, 2010, 974(1): 161.
[27] Zhao Y, Zhang J, Yuan T, et al. PloS One, 2014, 9(2): e89100.
[28] Lu Y Z, Du C W, Yu C B, et al. Computers and Electronics in Agriculture, 2014, 107: 58.
[29] Lu Y Z, Du C W, Yu C B, et al. Analysis Methods, 2014, 6(5): 1412.
[30] Abdi H, Williams L J. Wiley Interdisciplinary Reviews: Computational Statistics, 2010, 2(4): 433.