快速分光光度法同步测定地下水中赤霉素和草甘膦的相互影响

doi:10.3964/j.issn.1000-0593(2015)04-0966-05

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摘要：随着设施化农业的迅速发展，大量农药的不规范使用使高浓度赤霉素和草甘膦集中进入环境的风险增大(特别是地下水环境)，因而关于二者在地下水中残留量测定方法的研究尤为重要。分光光度法、气相色谱-质谱法、液相色谱法和液相色谱-质谱法是普遍使用的赤霉素和草甘膦测试方法，分光光度法由于操作简便而在快速检测中被广泛应用。然而，关于分光光度计快速同时测定地下水中赤霉素和草甘膦的方法，尚未有研究关注其相互影响。故建立和优化了快速分光光度法同步测定地下水中赤霉素和草甘膦的分析方法，并研究二者同步测定时的相互影响。结果表明，赤霉素校准曲线在0～20和0～100 μg范围内，具有良好线性相关关系(R²>0.99)，方法检出限为0.48 μg。水样测定时，含15～150 μg赤霉素的平均回收率为71.3%±1.9%，方法精密度的RSD<10%;草甘膦校准曲线在0～8和5～15 μg范围内，具有良好线性相关关系(R²>0.99)，方法检出限为0.82 μg。水样测定时，含3～10 μg草甘膦的平均回收率为98.4%±8.1%，方法精密度的平均RSD<10%。同时，根据浓度效应研究赤霉素和草甘膦快速分光光度法测定的相互影响表明，草甘膦0～100 mg·L^-1对赤霉素的回收率没有显著影响，但是会降低其测试精密度;赤霉素2 mg·L^-1会导致草甘膦测试中回收率由108.72%±4.33%增加到117.06%±3.2%。

关键词：赤霉素;草甘膦;分光光度法;相互影响

Abstract：In the present study, a spectrophotometry method for the simultaneous determination of gibberellins (GA3) and glyphosate in groundwater was established and optimized. In addition, the mutual effect on simultaneous determination of GA3 and glyphosate was studied. Based on the experiment, good linearity (R²>0.99) was obtained for GA3 in the range of 0~20 and 0~100 μg and for glyphosate in the range of 0~8 and 5~15 μg. The method’s detection limit (MDL) of GA3 and glyphosate was 0.48 and 0.82 μg, respectively; and the recovery rates of 15 to 150 μg GA3 and 3 to 10 μg glyphosate in all samples at a spiked level were 71.3%±1.9% and 98.4%±8.1%, respectively. No obvious influence of glyphosate (0～100 mg·L^-1) on the recovery rates of GA3 was observed, but the presence of glyphosate could cause slight determination precision decrease of GA3. Meanwhile, adding 2 mg·L^-1 GA3 can increase the recovery rate of glyphosate.

Key words：Gibberellins;Glyphosate;Spectrophotometry;Mutual effect

收稿日期: 2014-09-25 修订日期: 2014-12-04

中图分类号:

O657.3

通讯作者: 刘菲 E-mail: feiliu@cugb.edu.cn

引用本文:

张莉¹，陈亮²，刘菲^1* . 快速分光光度法同步测定地下水中赤霉素和草甘膦的相互影响 [J]. 光谱学与光谱分析, 2015, 35(04): 966-970.
ZHANG Li¹, CHEN Liang², LIU Fei^1* . Mutual Effect on Determination of Gibberellins and Glyphosate in Groundwater by Spectrophotometry. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2015, 35(04): 966-970.

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[1] CAO Hong-en, XIA Hui, YANG Yi-zhong(曹洪恩, 夏慧, 杨益众). Journal of Toxicology(毒理学杂志), 2011, 25(5): 383.
[2] CHEN Xiao-peng, WANG Xiu-feng, SUN Xiao-lei, et al(陈小鹏, 王秀峰, 孙小镭, 等). Shandong Agricultural Science(山东农业科学), 2005, 1: 65.
[3] XU Ai-dong(徐爱东). China Vegetable(中国蔬菜), 2009, 8: 1.
[4] YU Hui(俞慧). Journal of Bengbu Medical College(蚌埠医学院学报), 2012, 37(6): 743.
[5] Rubio F, Veldhuis L J, Clegg S, et al. Journal of Agricultural and Food Chemistry, 2003, 51: 691.
[6] YIN Tian-shou, CHEN Shi-yong, YU Qun-ying, et al(印天寿, 陈世勇, 于群英, 等). Journal of Mianyang Agricultural College(绵阳农专学报), 1989, 6(4): 10.
[7] DONG Wen-geng, CHEN Xue-cheng, LANG Zhi-min, et al(董文庚, 陈学诚, 郎志敏, 等). Chinese Journal of Analytical Chemistry(分析化学研究简报), 1997, 25(10): 1210.
[8] HUANG Hong-lin, LIU Shi, ZHANG Tao-zhi(黄红林, 刘实, 张桃芝). Journal of Analytical Science(分析科学学报), 2005, 21(1): 75.
[9] WANG Lin, ZENG Jin-ming, HAN Yan-fei, et al(汪琳, 曾锦明, 韩燕飞, 等). Modern Scientific Instruments(现代科学仪器), 2010，(6): 99.
[10] Xie Wen, Han Chao, Zheng Ziqiang, et al. Food Chemistry, 2011, 127: 890.
[11] ZHANG Song, GUO Hao, ZHANG Pan, et al(张松, 郭浩, 张盼, 等). Chinese Journal of Analysis Laboratory(分析试验室), 2014, 33(1): 78.
[12] FU Lei, TAO Yan-fei(付磊, 陶燕飞). Journal of Wuhan University of Science and Technology(Natural Science Edition)(武汉科技大学学报·自然科学版), 2002, 25(4): 359.
[13] HU Ji-ye, ZHANG Dian-ying, NING Jun, et al(胡继业, 赵殿英, 宁君, 等). Chinese Journal of Pesticide Science(农药学学报), 2007, 9(3): 285.
[14] HUANG Hong-lin, ZHANG Tao-zhi, LIU Shi(黄红林, 张桃芝, 刘实). Physical Testing and Chemical Analysis Part B(Chemical Analysis)(理化检验·化学分册), 2006, 42(3): 194.
[15] MA Wei-min, NIU Sen, LI Dong-yun, et al(马为民, 牛森, 李东运, 等). Agrochemicals(农药), 2006, 45(4): 261.
[16] ZHENG Qiu-ling(郑秋玲). Journal of Hebei Agricultural Sciences(河北农业科学), 2010, 14(3): 154.
[17] Lee H U, Shin H Y, Lee J Y et al. Journal of Agricultural and Food Chemistry, 2010, 58(23): 12096.
[18] WANG Shi-yu, LIU Fei, LIU Yu-long, et al(王世玉, 刘菲, 刘玉龙, 等). Chinese Journal of Analytical Chemistry(分析化学), 2013, 41(11): 1699.
[19] U S EPA. Subchapter D: 40 CFR Part 136, Appendix B to Part 136-Definition and Procedure for the Determination of the Method Detection Limit-Revision 1.11: (http://www.epa.gov/region9/qa/pdfs/40cfr136_03.pdf). 1978. 317.
[20] Takeda K, Moriki M, Oshiro W, et al. Marine Chemistry, 2013, 157: 208.
[21] SHEN Yuan-li, MA Jin-feng, ZHAO Xu, et al(申元丽, 马金锋, 赵旭, 等). Acta Scientiae Circumstantiae(环境科学学报), 2011, 31(8): 1647.