根部吸收氟啶虫酰胺在玉米植株中的分布特点及对玉米蚜虫活性效果评价

doi:10.16035/j.issn.1001-7283.2022.05.038

Abstract

Abstract:

Systemic distribution of flonicamid in maize and its activity evaluation against Rhopalosiphum maidis were investigated by application of hydroponic nutrient solution. The results showed that flonicamid accumulation in maize aboveground peaked 4-8 days after treatment and subsequently gradually dropped. After root-drenching, the retention of flonicamid in the root rose for 1-2 days, then remained generally steady for 2-32 days. According to the activity effect of flonicamid on R.maidis, after one day of treatment, all treatments demonstrated a certain control effect, with values ranging from 23.33% to 38.22% and honeydews substantially lower than the control group. The control effect of flonicamid on R.maidis was gradually increased with the increase of treatment time, the values of 31.25 and 125.00mg/L treatments after treated 16d were 88.60% and 99.49%, and the inhibition rates of honeydews were 96.70% and 99.95%, respectively. The honeydews of R.maidis decreased gradually with the increase of concentration, and the inhibitory rate of honeydews was higher than that of the control under the same concentration and time. Therefore, flonicamid can be used to control R.maidis through underground treatment of maize.

Key words: Flonicamid, Root absorption, Maize, Activity effect

Zhou Chao, Zhang Tiantian, Yang Li’na, Zhang Yong, Ma Chong, Dai Weicheng, Wu Cuixia, Song Min. Systemic Distribution of Flonicamid in Maize and Its Activity Effect against Rhopalosiphum maidis with Root Absorption[J].Crops, 2022, 38(5): 261-266.

Figures/Tables 5

Fig.1

Table 1

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Table 4

References 26

[1]	中华人民共和国国家统计局. 中华人民共和国主要农作物播种面积年度数据. [2022-04-15]. http://data.stats.gov.cn/easyquery.htm?cn=C01 .
[2]	中华人民共和国国家统计局. 中华人民共和国主要农作物产品产量年度数据. [2022-04-15]. http://data.stats.gov.cn/easyquery.htm?cn=C01 .
[3]	王振营, 王晓鸣. 我国玉米病虫害发生现状、趋势与防控对策. 植物保护, 2019, 45(1):1-11.
[4]	吴玉娥, 李静, 郑坤明, 等. UPLC-HRMS法探究氯虫苯甲酰胺在水稻植株中的内吸传导特性. 农药, 2017, 56(3):176-179.
[5]	Insecticide Resistance Action Committee. IRAC MoA Classification Scheme. [2021-03-11]. http://www.irac-online.org/documents/moa-classification/?ext=pdf .
[6]	Alan B. Agrochemicals coming off-patent 2012-2016. London:Informa UK Ltd., 2011:94-96.
[7]	束兆林, 于居龙, 缪康, 等. 氟啶虫酰胺对水稻白背飞虱的防治效果及天敌安全性评价. 农药, 2016, 55(11):851-853.
[8]	Morita M, Yoneda T, AkiyoshI N. Research and development of a novel insecticide,flonicamid. Journal of Pesticide Science, 2014, 39(3):179-180. doi: 10.1584/jpestics.J14-05
[9]	仇是胜, 柏亚罗, 顾林玲. 氟啶虫酰胺的研究开发及市场前景. 现代农药, 2014, 13(5):6-11.
[10]	张亦冰. 新颖杀虫剂——氟啶虫酰胺. 世界农药, 2010, 32(1):54-56.
[11]	Sicbaldi F, Sacchi G A, Trevisan M, et al. Root uptake and xylem translocation of pesticides from different chemical classes. Pesticide Science, 1997, 50(2):111-119. doi: 10.1002/(SICI)1096-9063(199706)50:2<111::AID-PS573>3.0.CO;2-3
[12]	高晓旭, 张志刚, 段颖, 等. 高浓度营养液对黄瓜和番茄下胚轴徒长的抑制作用. 植物营养与肥料学报, 2014, 20(5):1234-1242.
[13]	杨焕青, 王开运, 王红艳, 等. 抗吡虫啉棉蚜种群对吡蚜酮等药剂的交互抗性及施药对其生物学特性的影响. 昆虫学报, 2009, 52(2):175-182.
[14]	Hyeyoung K, Steven J. L, Lucía G A. Variability of matrix effects in liquid and gas chromatography-mass spectrometry analysis of pesticide residues after QuEChERS sample preparation of different food crops. Journal of Chromatography A, 2012, 1270:235-245. doi: 10.1016/j.chroma.2012.10.059 pmid: 23182936
[15]	农业部农药检定所. 农药残留试验准则:NY/T 788―2004. 北京: 中国农业出版社, 2004.
[16]	范添乐, 宋玥颐, 陈小军, 等. 农药内吸性的研究现状与改善策略. 农药学学报, 2020, 22(4):579-585.
[17]	杨庆喜, 李东阳, 纪明山, 等. 喷雾和灌根施药后吡虫啉在草莓植株中的分布及其对草莓蚜虫的防效. 植物保护, 2019, 45(4):250-254.
[18]	宗建平, 魏书娟, 王景阳, 等. 喷雾和灌根施药后吡虫啉在番茄植株中的分布及其对烟粉虱的防效. 农药学学报, 2009, 11(2):219-224.
[19]	郭东梅, 郑永权, 董丰收, 等. 油菜对吡虫啉的吸收运转与分布特性研究. 农业环境科学学报, 2006(3):606-609.
[20]	彭建红, 李耀发, 高占林, 等. 用水培法测定根部吸收的吡虫啉在小麦和棉花植株体内的持留分布动态. 农药, 2017, 56(12):901-904.
[21]	苏建亚. 氟啶虫酰胺作用靶标——内向整流钾离子通道研究进展. 农药学学报, 2019, 21(2):131-139.
[22]	Cho S R, Koo H N, Yoon C, et al. Sublethal effects of flonicamid and thiamethoxam on green peach aphid,Myzus persicae and feeding behavior analysis. Journal of the Korean Society for Applied Biological Chemistry, 2011, 54(6):889-898. doi: 10.1007/BF03253177
[23]	Ren M M, Niu J G, Hu B, et al. Block of Kir channels by flonicamid disrupts salivary and renal excretion of insect pests. Insect Biochemistry and Molecular Biology, 2018, 99:17-26. doi: S0965-1748(18)30152-8 pmid: 29842935
[24]	Powell G F, Ward D A, Prescott M C, et al. The molecular action of the novel insecticide,Pyridalyl. Insect Biochemistry and Molecular Biology, 2011, 41(7):459-469. doi: 10.1016/j.ibmb.2011.03.007
[25]	李冠楠, 苗昌见, 李为争, 等. 吡虫啉悬浮种衣剂对玉米田节肢动物群落及主要非靶标害虫的影响. 中国农业科学, 2017, 50(24):4735-4746.
[26]	田体伟, 王丽莎, 王燕, 等. 3种新烟碱类种子处理剂对玉米及其主要害虫的影响. 河南农业科学, 2015, 44(11):73-78.

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项目Item	线性方程Linear equation	相关系数Correlation coefficient (r)	基质效应Matrix effect (%)
地上部Aboveground	y=47 617x+7807.9	1.0000	-26.09
根Root	y=38 726x+13 974	1.0000	-39.89
营养液Nutrient solution	y=59 315x+21 309	0.9999	-7.93
空白对照CK	y=64 427x+8291	1.0000	–

项目 Item	添加浓度 Added concentration (mg/kg)	添加回收率Adding recovery (%)					平均值 Average (%)	相对标准偏差 Relative standard deviation (%)
项目 Item	添加浓度 Added concentration (mg/kg)	1	2	3	4	5	平均值 Average (%)	相对标准偏差 Relative standard deviation (%)
地上部Aboveground	0.05	110.00	88.52	80.15	90.38	76.54	89.12	14.60
	0.20	105.25	99.53	91.17	93.65	86.25	95.17	7.77
	2.00	88.88	78.87	84.72	83.42	85.97	84.37	4.36
根Root	0.05	97.45	77.71	110.34	82.08	77.20	88.96	16.31
	0.20	97.87	100.26	102.78	91.83	82.46	95.04	8.54
	2.00	86.66	92.21	98.12	94.23	92.87	92.82	4.45
营养液Nutrient solution	0.05	109.65	92.46	88.92	103.62	89.83	96.89	9.53
	0.20	103.81	100.88	97.28	95.86	92.42	98.05	4.51
	2.00	100.49	97.48	96.56	100.53	105.86	100.18	3.63

项目 Item	处理浓度 Concentration (mg/L)	持留量（含量）Residue (content) (mg/kg)
项目 Item	处理浓度 Concentration (mg/L)	1d	2d	4d	8d	16d	32d
地上部Aboveground	7.81	5.89±0.52	8.87±0.55	13.45±0.95	12.75±0.69	12.05±0.54	10.78±0.66
	31.25	23.12±4.03	36.68±4.38	59.40±6.49	70.50±5.36	64.95±5.12	51.72±6.50
	125.00	116.39±7.75	148.38±5.00	247.62±15.18	228.80±12.19	204.74±13.53	184.53±7.43
根Root	7.81	3.33±1.19	3.68±1.13	3.88±1.22	3.44±1.08	4.00±0.98	3.62±1.02
	31.25	14.75±2.33	16.35±2.34	16.20±1.64	17.38±1.85	16.42±1.56	16.78±1.62
	125.00	51.40±5.33	53.95±1.97	52.53±2.68	54.82±5.14	53.89±3.54	52.94±3.84
营养液Nutrient solution	7.81	7.71±0.09	7.72±0.04	7.65±0.07	7.54±0.09	6.92±0.08	6.16±0.06
	31.25	31.47±0.44	31.20±0.43	31.03±0.08	29.43±0.62	26.77±0.54	25.41±0.18
	125.00	125.00±0.74	124.86±0.49	123.94±0.26	119.81±0.49	112.99±1.40	103.13±1.53

处理时间 Processing time	处理浓度 Concentration (mg/L)	防治效果 Control effect (%)	蜜露数（滴/头） Honeydews (drop/ head)	蜜露抑制率 Inhibitory rate (%)
1d	7.81	23.33bA	8.99±0.41bB	33.04aA
	31.25	29.47abA	8.32±0.51bBC	38.93aA
	125.00	38.22aA	6.88±0.88cC	58.17aA
	0.00（对照）	–	11.29±0.77aA	–
2d	7.81	35.51cC	8.08±0.51bB	49.18cC
	31.25	53.89bB	4.42±0.25cC	78.95bB
	125.00	71.68aA	1.82±0.55dD	95.16aA
	0.00（对照）	–	11.23±0.51aA	–
4d	7.81	47.25cC	8.64±0.36bB	54.61cC
	31.25	68.25bB	2.99±0.61cC	89.81bB
	125.00	82.40aA	1.38±0.37dD	97.62aA
	0.00（对照）	–	10.79±0.65aA	–
8d	7.81	55.18cC	7.92±0.54bB	66.00cC
	31.25	85.70bB	2.79±0.49cC	95.89bB
	125.00	95.53aA	1.01±0.29dD	99.59aA
	0.00（对照）	–	11.14±0.67aA	–
16d	7.81	59.53cC	7.64±0.36bB	71.31cC
	31.25	88.60bB	2.76±0.26cC	96.70bB
	125.00	99.49aA	0.51±0.61dD	99.95aA
	0.00（对照）	–	11.50±0.63aA	–
32d	7.81	56.21cC	7.96±0.59bB	68.47cC
	31.25	90.98bB	2.38±0.51cC	97.90bB
	125.00	100.00aA	0.00±0.00dD	100.00aA
	0.00（对照）	–	11.79±0.64aA	–

Systemic Distribution of Flonicamid in Maize and Its Activity Effect against Rhopalosiphum maidis with Root Absorption

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