不同药剂低浓度处理的褐飞虱室内种群生命表

以噻嗪酮(Applaud,buprofezin)、叶蝉散和速灭杀丁三种不同类型药剂的低浓度(约对褐飞虱一龄若虫的LC_(10)～LC_(15))及亚致死浓度从一龄若虫开始持续处理褐飞虱一个完整世代,供试的噻嗪酮三种浓度处理对成虫的寿命、产卵量和卵的孵化均有一定的影响,显著降低了褐飞虱种群的增殖能力。     

褐飞虱和白背飞虱对几类杀虫剂的敏感性

为了科学用药和抗性治理提供理论基础, 采用稻茎浸渍法测定了2008年7月采自浙江省杭州市和宁波市褐飞虱 Nilaparvata lugens (Stål)种群对7种杀虫剂的抗药性及褐飞虱和白背飞虱Sogatella furcifera (Horváth)种群对16种杀虫剂的敏感性。褐飞虱抗药性测定结果表明, 与相对敏感品系相比, 杭州种群和宁波种群对吡虫啉的抗性倍数分别为479.0倍和366.1倍; 对氯噻啉的抗性倍数分别为81.1倍和50.9倍; 对噻虫嗪的抗性倍数分别为10.3倍和9.4倍; 对噻嗪酮和氟虫腈分别产生了5.0~8.6倍和15.8~17.0倍的抗药性; 对烯啶虫胺和啶虫脒的抗性倍数在3倍以下。两种稻飞虱对杀虫剂的敏感性测定结果表明: 噻虫嗪、噻嗪酮、烯啶虫胺和毒死蜱对褐飞虱和白背飞虱种群都具有较高的室内毒力。当田间褐飞虱和白背飞虱混合发生时, 可选用噻虫嗪、噻嗪酮、烯啶虫胺和毒死蜱进行防治, 不宜使用吡虫啉、氯噻啉和氟虫腈防治。     

吡蚜酮对白背飞虱的发育、繁殖和药剂敏感性的亚致死效应（英文）

【目的】白背飞虱Sogatella furcifera(Horváth)是我国重要的水稻害虫。本研究旨在确定亚致死浓度吡蚜酮对白背飞虱发育和繁殖及亚致死浓度处理后白背飞虱对其他药剂的敏感性变化的影响。【方法】用生命表法研究了亚致死浓度吡蚜酮处理对白背飞虱F0及F1代发育历期、存活率、羽化率和寿命的亚致死效应;采用稻茎浸渍法,测定了亚致死浓度吡蚜酮处理后白背飞虱对其他药剂的敏感性。【结果】经LC_(10)和LC_(25)吡蚜酮处理后,白背飞虱F0代3-5龄若虫历期比对照(8.25 d)分别延长了1.98 d和4.25 d,寿命分别比对照(14.54 d)缩短了0.49和1.73 d,3-5龄若虫存活率(分别为85.00%和68.50%)和羽化率(分别为75.89%和67.78%)比对照(分别为92.00%和85.90%)下降,其中LC_(25)处理组与对照比差异显著。LC_(10)和LC_(25)吡蚜酮处理的白背飞虱F1代羽化率(分别为76.97%和68.94%)、交尾率(分别为77.79%和66.44%)和卵孵化率(分别为73.19%和68.67%)比对照(分别为88.22%,86.67%和87.26%)显著降低,但只有LC_(25)处理组的F1代发育历期与对照组有显著差异;LC_(10)和LC_(25)吡蚜酮处理后的F1代单雌产卵量比对照(147.80粒/雌)显著下降(分别为112.36和88.34粒/雌),种群相对适合度比对照(1.00)也明显下降(分别为0.41和0.20)。经吡蚜酮LC_(10)和LC_(25)处理后,测定白背飞虱对噻虫嗪,毒死蜱和噻嗪酮的敏感性结果显示,这3种杀虫剂的LC50在LC_(10)处理组中分别为2.16,40.87和3.12 mg/L,在LC_(25)处理组中分别为4.93,17.96和8.39 mg/L。噻虫嗪、毒死蜱、噻嗪酮的相对毒力指数(RTI)结果显示,LC_(10)和LC_(25)处理后的白背飞虱对这3种杀虫剂的敏感性均降低。【结论】吡蚜酮处理后,白背飞虱对其他药剂的敏感性均降低。吡蚜酮亚致死浓度处理能降低白背飞虱的繁殖力,抑制种群增长,亚致死浓度处理后的白背飞虱种群对噻虫嗪、毒死蜱和噻嗪酮的敏感性均降低。     

惠州地区褐飞虱对几种药剂的抗药性监测

2009年采用稻茎浸渍法测定广东省惠州地区褐飞虱Nilaparvata lugens(Stl)种群对吡虫啉、噻嗪酮、异丙威、丁烯氟虫腈、烯定虫胺和毒死蜱等杀虫剂的敏感性,测定结果表明:当地褐飞虱种群对吡虫啉产生了极高水平抗性(抗性倍数为422.2倍),对噻嗪酮、异丙威产生了中等水平抗性(抗性倍数分别为11.0和14.0倍),对丁烯氟虫腈仍处于敏感性降低(抗性倍数为3.7倍),对烯定虫胺和毒死蜱敏感(抗性倍数<3倍)。基于褐飞虱对这6种药剂抗性的明显差异,对田间治理褐飞虱合理使用药剂进行了讨论。     

中国和越南褐飞虱抗药性研究

2010年用稻茎浸渍法监测了我国和越南共14个褐飞虱Nilaparvata lugens(St(a)l)田间种群对5种杀虫剂的抗性,结果表明:14个褐飞虱田间种群对吡虫啉、噻嗪酮、氟虫腈、吡蚜酮和叶蝉散的LC50值分别在9.5287～46 6716、1.6621～17.8785、0.9818～ 8.4084、0.331...     

几类杀虫剂对灰飞虱的相对毒力及田间种群的抗药性现状

采用浸苗法测定了6类11种杀虫剂对灰飞虱Laodelphax striatellus (Fallén)3龄若虫的毒力,并分析比较了江苏句容、通州、楚州、大丰、南京和苏州以及安徽庐江等7地灰飞虱种群对10种杀虫剂的抗药性水平。对云南种群而言,在所测杀虫剂中,以乙酰甲胺磷为标准药剂,氟虫腈的相对毒力最高;噻嗪酮、阿维菌素和噻虫嗪次之;高效氯氰菊酯、IPP（硝基亚甲基类化合物）、毒死蜱、敌敌畏和三唑磷间毒力处于同一数量级,低于阿维菌素等杀虫剂;吡虫啉的相对毒力最低。与云南种群相比,2007年采自苏、皖7个不同地区的灰飞虱种群对噻嗪酮产生了极高水平的抗性,其抗性倍数均超过200倍;对高效氯氰菊酯产生了中高水平的抗性,其抗性倍数为7.8～108.8;安徽庐江灰飞虱种群对三唑磷产生了7.7倍的抗性,对毒死蜱产生了12.0倍的抗性,江苏楚州、南京、大丰和句容灰飞虱种群对毒死蜱产生了5.7～12.6倍的抗性; 所有灰飞虱种群对敌敌畏仍然敏感,对氟虫腈、阿维菌素和新烟碱类杀虫剂吡虫啉、噻虫嗪和IPP等也比较敏感。     

环境因子对褐飞虱两种生物型种群参数影响的比较

比较了孟加拉型和生物型Ⅱ褐飞虱种群对高温、饥饿、浸水和杀虫剂等因子的反应。结果表明,35.0℃下孟加拉型若虫的致死中量时间(LT50)显著高于生物型Ⅱ,但两个生物型在26℃和37.5℃下的LT50间差异均不显著,而40.0℃时生物型Ⅱ若虫的LT50显著高于孟加拉型。在26、35.0℃和室内自然变温(26~35.0℃)条件下测定成虫耐饥力,两生物型间LT50均差异不显著。在各饥饿处理时间下,两生物型褐飞虱单雌平均产卵量差异均不显著。褐飞虱卵浸水1、3d和5d,两个生物型孵化率无显著差异,但生物型Ⅱ卵浸水5d后孵化率与对照相比差异显著,说明浸水5d对褐飞虱生物型Ⅱ卵的孵化率有影响。取食经浸水5d处理的稻株168h后,生物型Ⅱ若虫的死亡率与对照有显著差异,而孟加拉型死亡率与对照相比差异不显著;不浸水对照处理两个生物型的2~3龄若虫168h时就已全部发育为成虫,而浸水处理则到216h时才全部发育为成虫,这表明水稻浸水处理延迟了两个生物型若虫的发育进度。对于甲胺磷,药后1d、2d孟加拉型的致死中浓度(LC50)均显著小于生物型Ⅱ;对于噻嗪酮,孟加拉型药后5d的LC50均显著小于生物型Ⅱ,表明孟加拉型对这两种杀虫剂较生物型Ⅱ敏感。     

灰飞虱对噻嗪酮的抗性风险及机理

为研究灰飞虱对噻嗪酮的抗性发展规律及抗性生化机理,采用稻苗喷雾法对灰飞虱种群进行连续筛选获得高抗性品系,估算其现实遗传力并进行田间抗性风险预测;采用稻苗浸渍法测定杀虫剂对灰飞虱的毒力及交互抗性;利用生物化学方法测定不同品系之间的解毒酶活力,探讨灰飞虱对噻嗪酮的抗性生化机理.结果表明:用噻嗪酮对灰飞虱种群连续筛选32代,其抗性倍数达到168.49倍,现实遗传力h~2为0.11.当杀死率为80%~90%时,预计灰飞虱对噻嗪酮的抗性增长10倍,仅需要5~6代.田间实际的现实遗传力要比室内选择种群估计低一些,预计田间抗性提高10倍所需要时间会更长.交互抗性测定结果表明,灰飞虱抗噻嗪酮品系与吡虫啉和噻虫嗪之间有高水平交互抗性,与啶虫脒有低水平交互抗性,与吡蚜酮和毒死蜱无交互抗性.增效作用和解毒酶活力测定结果显示,抗性品系细胞色素P450单加氧酶活力提高最大,酯酶次之,谷胱甘肽-S-转移酶无显著变化.田间使用噻嗪酮防治灰飞虱存在较大抗性风险,可与吡蚜酮和毒死蜱等交替使用以延缓抗性发展;3种解毒酶中,细胞色素P450单加氧酶在灰飞虱对噻嗪酮的抗性发展中起到了重要作用.     

氯虫苯甲酰胺对非靶标害虫褐飞虱实验种群的亚致死效应

在稻田中,氯虫苯甲酰胺是以鳞翅目幼虫为主要防治对象的新型杀虫剂,而褐飞虱 是该药剂的重要非靶标害虫.本文采用稻茎浸渍法测定氯虫苯甲酰胺对其非靶标害虫褐飞虱3龄若虫和成虫的毒力.结果表明:氯虫苯甲酰胺对褐飞虱3龄若虫和成虫的LC50分别为26.85和35.53 mg·L-1;以氯虫苯甲酰胺亚致死浓度LC10和LC25分别处理褐飞虱3龄若虫后,对当代褐飞虱雌虫寿命无显著影响,但LC25剂量处理后,当代褐飞虱雌虫产卵量显著降低45.6粒.亚致死剂量处理褐飞虱3龄若虫后,显著影响F1代褐飞虱的产卵量和雌虫寿命,雌虫产卵量分别减少43.5和72.9粒,雌虫寿命分别缩短1.35和2.87 d;两个剂量处理后F1代的各虫态发育历期均有所延长;施药后各项种群参数也发生了变化,种群内禀增长率rm分别降低12.8％和23.5％,净增殖率R0分别降低37.4％和68.7％,而世代平均历期T和种群加倍时间t均延长.表明氯虫苯甲酰胺亚致死剂量对褐飞虱种群增长具有一定的抑制作用.     

褐飞虱对五种杀虫剂抗性的快速检测技术

【目的】建立褐飞虱Nilaparvata lugens对常用杀虫剂抗性的快速检测技术,实时掌握田间褐飞虱种群的抗药性水平,以指导褐飞虱防控合理用药。【方法】基于玻璃瓶药膜法,研制褐飞虱3龄若虫对吡虫啉、啶虫脒、醚菊酯、毒死蜱和异丙威5种杀虫剂抗性的快速检测试剂盒;利用试剂盒测定的死亡率与稻苗浸渍法测得的抗性倍数进行相关性分析,并验证利用试剂盒快速测定褐飞虱田间种群对5种杀虫剂 抗性水平的准确性。【结果】处理1 h时吡虫啉、啶虫脒、醚菊酯、毒死蜱和异丙威对褐飞虱室内敏感种群3龄若虫的LD₉₀分别为：30.96, 92.05, 117.24, 514.21和1.24 ng/cm²。在吡虫啉、啶虫脒、醚菊酯、毒死蜱和异丙威相应诊断剂量下,贵州省不同田间种群褐飞虱3龄若虫的校正死亡率分别在23.75%~78.75%, 25.00%~78.75%, 43.75%~88.75%, 36.25%~85.00%和18.75%~67.50%之间。相关性分析表明,上述田间种群褐飞虱3龄若虫的死亡率与稻苗浸渍法测定的抗性倍数呈显著负相关,相关系数在0.8751~0.9754之间。通过快速检测试剂盒获得的死亡率及相关性方程计算得到贵州安龙地区(AL)褐飞虱种群对吡虫啉、啶虫脒、醚菊酯、毒死蜱和异丙威的推测抗性倍数分别为7.23, 3.68, 4.14, 4.12和31.18,采用稻苗浸渍法测得上述5种杀虫剂的实测抗性倍数分别为6.33, 5.24, 3.71, 4.50和26.56,表明推测抗性倍数与实测的抗性倍数结果表现一致。【结论】该快速检测试剂盒可以通过测定褐飞虱田间种群的死亡率,快速评估褐飞虱田间种群对杀虫剂的抗性水平。     

东莨菪内酯与双脱甲氧基姜黄素对朱砂叶螨毒力的温度效应

为明确植物性杀螨活性物质东莨菪内酯与双脱甲氧基姜黄素对朱砂叶螨Tetranychus cinnabarinus雌成螨毒力的温度效应, 采用玻片浸渍法测定了两者不同温度下的杀螨活性。结果表明： 在8～26℃的温度范围内, 东莨菪内酯和双脱甲氧基姜黄素对朱砂叶螨雌成螨的毒力呈正温度系数; 在26～34℃的温度范围内两者对朱砂叶螨雌成螨的毒力呈负温度系数。其中26℃下东莨菪内酯和双脱甲氧基姜黄素表现出较好杀螨活性, 处理后48 h的致死中浓度(LC₅₀)分别为0.1884和0.3376 mg/mL; 23℃下的毒力次之。致死中浓度(y)与温度(x)关系的拟合方程为： 东莨菪内酯: y₁= 0.006x₁²-0.278x₁+3.403; 双脱甲氧基姜黄素: y₂=0.007x₂²-0.354x₂+4.826。对y求最小值得出, 东莨菪内酯和双脱甲氧基姜黄素对朱砂叶螨雌成螨的最高毒力温度分别为23.2℃和25.3℃, LC₅₀分别为0.1828和0.3504 mg/mL。据此认为, 在一定的温度范围内, 随着温度的升高, 这两种植物性杀螨活性物质对朱砂叶螨的毒力与温度先呈正相关, 到达最佳毒力温度后再呈负相关。     

Effects of Selected Chemical Pesticides on Agamermis unka (Nematoda: Mermithidae), a Parasite of the Brown Plant Hopper,Nilaparvata lugens

Selected commercial and technical grade pesticides were tested against the egg, preparasite and adult stages of Agamermis unka , a nematode parasite of the brown planthopper, Nilaparvata lugens . The commercial insecticide, diazinon (LC = 0.37 ppm), was most toxic to the 50 preparasites, followed by phenthoate (LC = 0.43 ppm), BPMC (LC = 0.44 ppm), IBP 50 50 (LC = 0.46 ppm), cartap hydrochloride (LC = 0.82 ppm) and buprofezin + isoprocarb 50 50 (LC = 1.11 ppm). The least toxic commercial pesticide tested was the fungicide, pencycuron 50 (LC = 2.19 ppm). Out of 12 technical grade insecticides tested, phenthoate, monocrotophos, 50 diazinon and carbofuran (LC = 0.37-0.46 ppm) were highly toxic to the preparasites, followed by 50 buprofezin, BPMC and fenitrothion (LC = 0.74-0.86 ppm). Fenthion, etofenprox, chlorpyrifos, 50 imidacloprid and MIPC (LC = 1.11-2.19 ppm) were the technical grade insecticides least toxic 50 to the preparasites. Most preparasites survived for up to 24 h at the low insecticide concentrations (0.63 and 0.31 ppm). Preparasites that were exposed to BPMC for 24 h at concentrations as high as 5.0 ppm and survived the treatments infected brown planthopper nymphs. Four selected insecticides-chlorpyrifos, BPMC, imidacloprid and carbofuran-had significant adverse effects on A. unka egg hatching. Eggs that were in the insecticide solution for 168 h fared poorly with imidacloprid having the best survival ( > 2% of the eggs hatching at 0.04 ppm). No eggs hatched from the other insecticide treatments. Three selected insecticides, BPMC, imidacloprid and chlorpyrifos, tested against adult A. unka showed that most adults survived the exposure to the insecticides between 0.31 and 2.5 ppm. At 5.0 ppm of BPMC or chlorpyrifos none of the adults survived, whereas with imidacloprid 70% of the adults survived. Egg deposition by the surviving adults was greatly reduced in those treated with the insecticides compared with those in the controls. Imidacloprid had some negative impact on the preparasites' ability to infect BPH nymphs, but it had the least detrimental effect of the insecticides tested on preparasite survival and on the eggs and adults of A. unka .     

四种农药对小菜蛾体温的影响

【目的】本研究旨在为阐明小菜蛾Plutellaxylostella体温在其防治中的应用价值提供资料。【方法】在不同人工气候箱内温度(环境温度)下,测定小菜蛾2, 3和4龄幼虫的体温,建立各龄幼虫体温(y)与环境温度(x)的关系方程;同时测定了不同环境温度下不同浓度阿维菌素、毒死蜱、氟虫腈和高效氯氰菊酯分别处理后小菜蛾3龄幼虫在不同处理时间的体温。【结果】小菜蛾2, 3和 4龄幼虫体温(y)与环境温度(x)关系方程分别为y＝0.95x+1.19(r=0.9463), y＝0.95x+1.18(r=0.9988),以及y＝0.93x+1.45(r=0.9989),等温点分别为22.16℃,21.40℃和21.41℃。在气候箱温度设定为15℃或40℃时,4种农药都对小菜蛾3龄幼虫体温无影响;而其他温度条件下,农药处理都可能改变小菜蛾3龄幼虫体温。对于阿维菌素,25℃下 2, 4和8 mg/L处理12 h,2和4 mg/L处理24 h, 0.5, 2, 4和8 mg/L处理36 h以及0.5, 1, 2和8 mg/L处理48 h时3龄幼虫体温均显著高于对照, 8 mg/L阿维菌素处理24 h时3龄幼虫体温显著低于对照;30℃下0.5 mg/L处理24 h及1 mg/L处理36 h 3龄幼虫体温显著低于对照,1 mg/L处理48 h和各浓度处理60 h时3龄幼虫体温均显著高于对照;35℃下只有1和8 mg/L处理48 h时3龄幼虫体温显著低于对照。对于毒死蜱,20℃下50, 200和800 mg/L处理24 h, 100, 400和800 mg/L处理36 h时3龄幼虫体温都显著低于对照;25℃下100和200 mg/L处理12h, 800 mg/L处理24 h, 100, 200和800 mg/L处理60 h时3龄幼虫体温均显著低于对照,而50, 100, 200和400 mg/L处理24 h, 100和200 mg/L处理36 h及100和400 mg/L处理48 h时3龄幼虫体温均显著高于对照;30℃下只有800 mg/L处理24 h时3龄幼虫体温显著低于对照,50, 100, 200和800 mg/L处理60 h时3龄幼虫体温显著高于对照。对于氟虫腈,20℃下只有0.5 mg/L处理36 h时3龄幼虫体温显著低于对照;25℃下 4 mg/L处理12 h和各浓度处理60 h时3龄幼虫体温显著低于对照,0.5 mg/L处理24 h以及0.25, 1和2mg/L处理48 h时3龄幼虫体温均显著高于对照;30℃下 0.25和0.5 mg/L处理12 h, 0.25和2 mg/L处理24h, 4 mg/L处理48 h以及2 mg/L处理60 h时3龄幼虫体温显著低于对照;35℃下只有0.25和0.5 mg/L处理60 h时3龄幼虫体温显著高于对照。对于高效氯氰菊酯,20℃下2和8 g/L处理36 h, 4和8 g/L处理48 h时3龄幼虫体温显著高于对照;25℃下 2, 4和8 g/L处理12 h时3龄幼虫体温均显著低于对照, 0.5, 4和8g/L处理24 h, 1, 4和 8 g/L处理36 h以及1, 2和4 g/L处理60 h时3龄幼虫体温均显著高于对照;30℃下 0.5和1 g/L浓度处理12 h, 0.5, 1, 4和8 g/L处理24 h以及1, 2和8 g/L处理60 h时3龄幼虫体温都显著低于对照。【结论】小菜蛾幼虫自律性体温调节能力低;阿维菌素、毒死蜱、氟虫腈或高效氯氰菊酯处理影响小菜蛾3龄幼虫的体温,影响形式随农药种类和浓度,环境温度及处理时间不同而不同。本研究拓宽了农药毒理学及害虫防治研究内容。     

Inter-regional differences in baseline toxicity of Bemisia argentifolii (Homoptera: Aleyrodidae) to the two insect growth regulators, buprofezin and pyriproxyfen.

A survey of 53 Bemisia argentifolii Bellows & Perring populations from different agricultural regions in California and Arizona was conducted from 1997 to 1999 to establish baseline toxicological responses to buprofezin and pyriproxyfen. Although both compounds proved to be highly toxic even in minute quantities to specific stages, geographical and temporal differences in responses were detected using a leaf spray bioassay technique. Monitoring for three years revealed that six to seven populations had higher LC50 values but not greater survival when exposed to these two insecticides. A significant difference in relative susceptibility to buprofezin was first observed in late season 1997 in San Joaquin Valley populations with LC50s ranging from 16 to 22 microg (AI)/liter(-1) compared with IC50s of 1 to 3 mg (AI)/liter(-1) in Imperial, Palo Verde Valley and Yuma populations. Whiteflies collected in subsequent years from these and other locations showed an increase in susceptibility to buprofezin. Regional differences in susceptibilities to pyriproxyfen were minimal within the same years. Three years of sampling revealed consistently higher LC50s to pyriproxyfen in populations from Palo Verde Valley, CA, compared with whiteflies from Imperial, San Joaquin Valley or Yuma. As was the case with buprofezin, a decline in LC50s to pyriproxyfen was observed in whiteflies from all locations sampled in 1999. However, no correlation was observed between buprofezin and pyriproxyfen toxicity in any of the strains. The variable toxicities observed to both compounds over a period of 3 yr may be due principally to inherent differences among geographical populations or due to past chemical use which may confer positive or negative cross-resistance to buprofezin or pyriproxyfen.     

Factors affecting the toxicity of Bacillus thuringiensis var. israelensis and Bacillus sphaericus to fourth instar larvae of Chironomus tepperi (Diptera: Chironomidae)

Laboratory bioassays (48h duration, 25+/-1 degrees C) were used to determine the toxicity of Bacillus thuringiensis var. israelensis (B.t.i.) and Bacillus sphaericus to fourth instar larvae of Chironomus tepperi, a major pest of rice in southern Australia. Bioassays were conducted using different combinations of larval ages and densities to determine if these factors affected toxicity. The effects of temperature and substrate type on B.t.i. toxicity were also investigated. Tests were conducted using a commercial B.t.i. formulation (VectoBac WDG, 3000ITU/mg), a spore/crystal mixture derived from the VectoBac WDG strain, and VectoLex WDG, a commercial B. sphaericus formulation (650ITU/mg). VectoBac WDG was highly toxic to fourth instar C. tepperi in bioassays using a sand substrate (LC(50) 0.46mg/L, older larvae); younger fourth instar larvae were more susceptible (LC(50) 0.20mg/L). Increasing larval densities (from 10 to 30 per bioassay cup) increased LC(50) values for both age groups, significantly so in the case of older larvae (higher density LC(50) 0.80mg/L). Use of a soil substrate increased the LC(50) value (older larvae, 10 per cup) to 0.99mg/L. Similar differences in toxicity relative to larval age and substrate type were found in bioassays using the B.t.i. spore/crystal mixture. VectoBac WDG and the spore/crystal mixture both showed similar (approximately 6-fold) declines in activity between 30 and 17.5 degrees C. At lower temperatures (between 17.5 and 15 degrees C), activity of the spore/crystal mixture declined much more rapidly than that of VectoBac WDG. VectoLex WDG showed very low toxicity to C. tepperi larvae, and the overall impact of larval age and density was relatively minor (LC(50) values 1062-1340mg/L). Autoclaving VectoLex WDG did not substantially reduce its toxicity (LC(50) 1426mg/L), suggesting that formulation additives (i.e., surfactants and other adjuvants) are responsible for much of the toxicity occurring at the high product concentrations required to cause C. tepperi mortality. Whilst VectoLex WDG was ineffective against C. tepperi, VectoBac WDG has the potential to provide selective control of this rice pest at economically viable application rates.     

Effects of alpha-mangostin from mangosteen pericarp extract and imidacloprid on Nilaparvata lugens (Stal.) and non-target organisms: toxicity and detoxification mechanism

The brown planthopper, Nilaparvato lugens Stat. (BPH) is the most devastating insect pest in rice fields. Outbreaks of BPH, which are resistant to many synthetic insecticides, can cause total rice crop loss. This research was done to evaluate the efficiency of extracts of mangosteen pericarp (Garcina mangostana L.) as an alternative control of BPH Thailand strain. Topical spraying was applied to various stages of nymphal and adult BPH to determine toxicity. An ethanol extract of mangosteen pericarp extract gave the best control of BPH, with LC50 of 4.5% w/v (r2 = 0.95) with 3rd instar BPH nymphs when compared with the other solvents, hexane, acetone and dichloromethane. The active compound, alpha-mangostin showed an LC50 of 5.44%w/v (r2 = 0.88). The toxicity of this extract was less than that of Imidacloprid which showed an LC50 of 0.0042% w/v (r2 = 0.99). The toxicity to non-target organisms was determined. This extract showed toxicity to guppies ((LC50 = 2.53 and 4.27 ppm for females and males, respectively; r2 = 0.97 and 0.97, respectively), bees (LC50 = 4.38% w/v, r2 = 0.95) and mice (no oral acute toxicity and no dermal inflammation but showed eye irritation in 1 day which became normal within 3 days). In vitro detoxification enzyme activities of carboxylesterase, acetylcholinesterase and glutathione-s-transferase from BPH after 24 hours exposure were also observed. Carboxylesterase showed stronger activity than other enzymes. Toxicity in terms of LC50 values of both the extract and imidacloprid treatments increased in each generation. The LC50 values for each generation were 4.22-6.67 after sequential spraying. After the ethanol extract was kept at 4 degrees C, room temperature and 55 degrees C for 3 months, the quantity of alpha-mangostin and the BPH control efficiency was lower at 55 degrees C than those for other temperatures. The results from this research indicate that mangosteen pericarp extract can be an alternative insecticide for the control of BPH, which may possess high efficiency, cause with fewer environmental problems and result in less resistance in the BPH.     

Baseline susceptibility of Planococcus ficus (Hemiptera: Pseudococcidae) from California to select insecticides

Between 2006 and 2008, 20 populations of Planococcus ficus (Signoret), from Coachella and San Joaquin Valleys of California were measured in the laboratory for susceptibility to buprofezin, chlorpyrifos, dimethoate, methomyl, and imidacloprid. Toxicity was assessed using a petri dish bioassay technique for contact insecticides and by a systemic uptake technique for imidacloprid. Mixed life stages were tested for susceptibility to all insecticides except for buprofezin, which was measured against early and late instars (first, second, and third). Dose-response regression lines from the mortality data established LC50 and LC99 values by both techniques. Responses of populations from the two geographical locations to all five insecticides varied, in some cases significantly. Variations in susceptibility to each insecticide among sample sites showed a sevenfold difference for buprofezin, 11-fold to chlorpyrifos, ninefold to dimethoate, 24-fold to methomyl, and 8.5-fold to imidacloprid. In spite of susceptibility differences between populations, baseline toxicity data revealed that all five insecticides were quite effective based on low LC50s. Chlorpyrifos was the most toxic compound to Planococcus ficus populations as shown by lowest LC50s. Buprofezin was toxic to all immature stages but was more potent to first instars. The highest LC99 estimated by probit analysis of the bioassay data of all 20 populations for each compound was selected as a candidate discriminating dose for use in future resistance monitoring efforts. Establishment of baseline data and development of resistance monitoring tools such as bioassay methods and discriminating doses are essential elements of a sustainable management program for Planococcus ficus.     

Toxicity of seven foliar insecticides to four insect parasitoids attacking citrus and cotton pests

Laboratory studies were carried out to compare the toxicity of seven foliar insecticides to four species of adult beneficial insects representing two families of Hymenoptera: Aphelinidae (Aphytis melinus Debach, Eretmocerus eremicus Rose & Zolnerowich, and Encarsiaformosa Gahan) and Mymaridae (Gonatocerus ashmeadi Girault) that attack California red scale, Aonidiella aurantii (Maskell); sweetpotato whitefly, Bemisia tabaci (Gennadius) (both E. eremicus and E. formosa); and glassy-winged sharpshooter, Homalodisca vitripennis (Germar), respectively. Insecticides from four pesticide classes were evaluated using a petri dish bioassay technique across a range of concentrations to develop dosage-mortality regressions. Insecticides tested included acetamiprid (neonicotinoid); chlorpyrifos (organophosphate); bifenthrin, cyfluthrin, and fenpropathrin (pyrethroids); and buprofezin and pyriproxyfen (insect growth regulators [IGRs]). Chlorpyrifos was consistently the most toxic pesticide to all four species of beneficial insects tested based on LC50 values recorded 24 h posttreatment compared with 48-h LC50 values with the neonicotinoid and pyrethroids or 96 h with the IGRs. Among the three pyrethroids, fenpropathrin was usually less toxic (except similar toxicity to A. melinus) than was cyfluthrin, and it was normally less toxic (except similar toxicity with E. formosa) than was bifenthrin. Acetamiprid was generally less toxic than bifenthrin (except similar toxicity with G. ashmeadi). The IGRs buprofezin and pyriproxyfen were usually less toxic than the contact pesticides, but we did not test for possible impacts on female fecundity. For all seven pesticides tested, A. melinus was the most susceptible parasitoid of the four test species. The data presented here will provide pest managers with specific information on the compatibility of select insecticides with natural enemies attacking citrus and cotton, Gossypium hirsutum L., pests.     

伊维菌素在环境中的降解及其对七种水生生物的急性毒性研究

伊维菌素作为一种高效的抗寄生虫兽药,在畜禽业有着广泛的应用。但药物随着畜禽动物的代谢产物的排放而进入自然生态系统也成为逐渐显现的环境问题。由于药物具有在自然环境中难以快速降解和对水生枝角类高毒性的特点,因此流入天然水体的伊维菌素存在着影响水生态平衡的风险。为了比较全面评估药物对水生动物潜在的毒害作用,研究模拟天然河道环境,对药物在底质中的降解速率进行了测定,并选取7种占据不同生态位的水生生物作为试验对象,通过关于急性毒性的国家标准试验方法来初步评价药物对水生态系统的风险。结果显示伊维菌素在自然水体中降解缓慢,在泥水混合25℃恒温条件下,70d的降解率仅为28.3%。急性毒性试验结果显示伊维菌素对发光细菌(Photobacterium)并不表现出毒性,对淡水小球藻(Chlorella vulgaris)的96h EC50=19.80 mg/L,属中毒;而对其他实验生物则表现出了较高的毒性,伊维菌素对斑马鱼(Brachydanio rerio)、食蚊鱼(Gambusia affinis)和鲫鱼鱼苗(Carassius carassius)的96h LC50分别为40.48、34.81和13.79μg/L,对罗氏沼虾(Macrobrachium rosenbergii)的96h LC50=7.87μg/L,对大型溞(Daphniamagna)的24h LC50=4.81 ng/L,均属极高毒。因此残留在天然水体的伊维菌素对水生态中的生物有较大影响,对含伊维菌素的废弃物排放进行监控和科学管理非常必要。     

亚致死浓度吡虫啉和毒死蜱对柑橘木虱成虫组织蛋白酶基因表达的影响

昆虫组织蛋白酶属于多功能酶系,在昆虫生命活动中具有重要作用,但昆虫组织蛋白酶对化学农药的响应却鲜有报道。吡虫啉和毒死蜱是目前防治柑橘木虱Diaphorina citri常用的化学药剂。本研究旨在探究吡虫啉和毒死蜱亚致死浓度处理对柑橘木虱成虫组织蛋白酶基因表达的影响。本研究基于柑橘木虱的转录组数据库,同时结合NCBI数据库,通过Blast比对鉴定得到8个柑橘木虱组织蛋白酶基因,序列分析得出其均属于半胱氨酸蛋白酶家族且含有保守的组氨酸活性位点。研究采用浸叶法处理得到经吡虫啉和毒死蜱处理24 h对柑橘木虱成虫的致死中浓度LC50分别为97.88 mg/L和47.94 mg/L。采用荧光定量PCR（qPCR）分析这两种药剂亚致死浓度（LC20和LC50）胁迫下柑橘木虱成虫组织蛋白酶基因表达水平变化。结果表明吡虫啉胁迫显著下调柑橘木虱DcCath-B,DcCath-F,DcCath-L和DcCath-L1基因表达量;毒死蜱LC20浓度胁迫显著下调柑橘木虱DcCath-B,DcCath-L和DcCath-W基因表达量,LC50浓度胁迫下仅DcCath-B表达量显著下调,其他基因表达无明显差异。以上结果表明吡虫啉和毒死蜱亚致死浓度胁迫下,柑橘木虱成虫下调表达体内部分组织蛋白酶基因以响应此逆境。本研究为探索亚致死浓度吡虫啉和毒死蜱对柑橘木虱的毒理机制提供了一定的理论依据。