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1.
 为筛选高毒农药的替代药剂,采用稻茎浸渍法测定了7类共21种杀虫剂对2006年和2007年采自南京市江浦地区的白背飞虱种群3龄若虫的毒力。结果表明,噻虫嗪、吡虫啉、噻嗪酮对白背飞虱3龄若虫的毒力最高(LC50=004~026 mg/L);烯啶虫胺、丁烯氟虫腈、吡蚜酮、啶虫咪、氯噻啉、毒死蜱、氟虫腈等也有较高的毒力(LC50<4.50 mg/L);异丙威、敌敌畏虽然触杀毒力稍低(LC50>19.85 mg/L),但两者在生产上仍广泛应用,所以把以上12种药剂作为田间药效试验的推荐品种;同时还比较了该地区白背飞虱种群对供试药剂敏感性的年度间差异,其中对毒死蜱、异丙威、丁硫克百威、速灭威这4种药剂的敏感性下降了66.7%~71.4%。对2006年南京江浦种群用吡虫啉连续筛选15代的结果表明,1~15代抗性上升433倍,抗性现实遗传力为0.2295,存在抗性风险。另外,还讨论了白背飞虱的综合防治。  相似文献   

2.
灰飞虱对几类杀虫剂的抗性和敏感性   总被引:7,自引:3,他引:4  
采用点滴法和稻茎浸渍法分别测定了2006年4月采自江苏省无锡市和浙江省湖州市灰飞虱种群对9种杀虫剂的抗性及17种杀虫剂的敏感性。点滴法测定结果表明,无锡种群和湖州种群对吡虫啉均产生了高水平抗性,抗性倍数分别为79.6倍和44.6倍;对残杀威的抗性倍数分别为76.6倍和40.1倍,属高水平抗性;对甲萘威的抗性倍数分别为29.8倍和45.3倍,属中等-高水平抗性;对二嗪磷、杀螟硫磷、仲丁威、丁硫克百威、醚菊酯、氰戊菊酯的抗性倍数为1.4~8.1倍,属敏感-低水平抗性。毒力测定结果表明氟虫腈、丁烯氟虫腈对无锡和湖州灰飞虱3龄若虫的毒力最高,LC50值为0.21~041 mg/L;噻虫嗪、烯啶虫胺、毒死蜱、吡蚜酮、异丙威、敌敌畏为田间药效试验的推荐用药。还讨论了灰飞虱抗药性的治理。  相似文献   

3.
褐飞虱对氟虫腈和新烟碱类药剂的抗性动态变化   总被引:5,自引:1,他引:4  
于2006-2008年采用稻茎浸渍法监测了我国主要水稻种植区大田褐飞虱种群对苯基吡唑类杀虫剂(氟虫腈)、新烟碱类及昆虫生长调节剂类杀虫剂(噻嗪酮)的抗性动态变化。结果表明,2008年褐飞虱对氟虫腈的抗性水平随其迁飞途径而出现急剧上升态势,其中,从我国南方稻区迁入长江中下游流域等6省10地种群和回迁至广东韶山、深圳两种群对氟虫腈抗性分别上升至中等水平抗性(15.0~32.5倍)和高水平抗性(66.9~73.7倍),明显高于2006年5省6地(2.6~5.8倍)和2007年9省11地(3.2~8.4倍)大田褐飞虱种群的抗性水平。上述结果预示2009年、2010年两年在全国稻区可能暴发褐飞虱对氟虫腈更高水平的抗性。自从2005年10-11月褐飞虱对新烟碱类的吡虫啉产生极高水平抗性(277~811倍)以来,近3年来抗性虽有一定程度下降,但仍处于高水平-极高水平抗性阶段,其中,2008年我国8省13地褐飞虱种群的抗性仍高达210.1~381.7倍。褐飞虱对其他的新烟碱类药剂噻虫嗪、烯啶虫胺和呋虫胺的抗性水平分别为2.0~15.8、0.7~4.8和0.6~2.8倍。褐飞虱对噻嗪酮为敏感到中等水平抗性(3.0~11.9倍)。近几年来大量、广泛使用氟虫腈防治褐飞虱和稻纵卷叶螟两类迁飞性害虫是褐飞虱对其暴发抗性的重要原因。因此,必须及时制定全国范围防治两类迁飞性害虫的交替轮换用药抗性治理对策方案,才能延缓褐飞虱抗性的再次暴发。  相似文献   

4.
【目的】系统评价市场上常用杀虫剂对褐飞虱不同虫态的作用特性,为选择对口药剂进行防治提供依据。【方法】采用稻苗浸渍法,在室内条件下测定了9种新烟碱类药剂和10种其他类型杀虫剂对褐飞虱不同虫态的杀虫活性、速效性和持效性。【结果】1)杀虫活性:不同杀虫剂活性存在显著差异。其中,烯啶虫胺、噻虫胺、毒死蜱、氟啶虫胺腈、呋虫胺和环氧虫啶活性最好,其次为哒嗪硫磷、乙基多杀菌素、吡蚜酮、异丙威,阿维菌素;其余药剂中噻虫嗪、甲维盐、氟啶虫酰胺对2~3龄若虫有一定活性而对4~5龄虫活性差,噻嗪酮、吡虫啉、噻虫啉、啶虫脒、氯噻啉对两种虫态的活性均较差。2)速效性:毒死蜱、哒嗪硫磷的速效性最好,异丙威、呋虫胺、烯啶虫胺、噻虫胺等次之,吡蚜酮最差。3)持效性:吡蚜酮、呋虫胺、烯啶虫胺、噻虫胺、环氧虫啶持效期>15 d,其中吡蚜酮最好,药后0、5和10 d连续3批接的试虫死亡率无显著差异。4)成虫:呋虫胺、烯啶虫胺、噻虫胺、环氧虫啶、毒死蜱、异丙威、吡蚜酮对雌雄成虫均有效,类似于若虫。5)卵:毒死蜱、烯啶虫胺、呋虫胺和噻虫胺对卵及孵化的若虫均有效;吡蚜酮、环氧虫啶、异丙威等无明显杀卵活性,但吡蚜酮对孵化若虫有较好的杀虫活性。【结论】19种药剂中,适于褐飞虱防治的有吡蚜酮、烯啶虫胺、呋虫胺、噻虫胺、环氧虫啶、氟啶虫胺腈、毒死蜱、哒嗪硫磷、异丙威共9种。其中,吡蚜酮持效性最佳且对卵之外各虫态活性较好,但速效性最差。呋虫胺、烯啶虫胺、噻虫胺和环氧虫啶等的速效性、持效性均较突出,且前三者对各虫态均有效。氟啶虫胺腈杀虫活性和速效性均好,但持效性差于新烟碱类。毒死蜱和哒嗪硫磷可单独或在防治其他害虫时兼防治褐飞虱,其中毒死蜱速效性最好,适合于大虫量时快速压低虫量。异丙威杀虫活性弱于新烟碱类,但速效性强于新烟碱类药剂,适合与吡蚜酮等混用或复配。此外,用于鳞翅目害虫防治的乙基多杀菌素、阿维菌素、甲维盐对褐飞虱有一定活性,适合防治其他害虫时兼治褐飞虱。而其余药剂如吡虫啉、噻嗪酮、噻虫嗪等7种药剂不适用于褐飞虱的防治。  相似文献   

5.
【目的】 系统评价市场上常用杀虫剂对褐飞虱不同虫态的作用特性,为选择对口药剂进行防治提供依据。【方法】 采用稻苗浸渍法,在室内条件下测定了9种新烟碱类药剂和10种其他类型杀虫剂对褐飞虱不同虫态的杀虫活性、速效性和持效性。【结果】 1)杀虫活性:不同杀虫剂活性存在显著差异。其中,烯啶虫胺、噻虫胺、毒死蜱、氟啶虫胺腈、呋虫胺和环氧虫啶活性最好,其次为哒嗪硫磷、乙基多杀菌素、吡蚜酮、异丙威,阿维菌素;其余药剂中噻虫嗪、甲维盐、氟啶虫酰胺对2~3龄若虫有一定活性而对4~5龄虫活性差,噻嗪酮、吡虫啉、噻虫啉、啶虫脒、氯噻啉对两种虫态的活性均较差。2)速效性:毒死蜱、哒嗪硫磷的速效性最好,异丙威、呋虫胺、烯啶虫胺、噻虫胺等次之,吡蚜酮最差。3)持效性:吡蚜酮、呋虫胺、烯啶虫胺、噻虫胺、环氧虫啶持效期>15 d,其中吡蚜酮最好,药后0、5和10 d连续3批接的试虫死亡率无显著差异。4)成虫:呋虫胺、烯啶虫胺、噻虫胺、环氧虫啶、毒死蜱、异丙威、吡蚜酮对雌雄成虫均有效,类似于若虫。5)卵:毒死蜱、烯啶虫胺、呋虫胺和噻虫胺对卵及孵化的若虫均有效;吡蚜酮、环氧虫啶、异丙威等无明显杀卵活性,但吡蚜酮对孵化若虫有较好的杀虫活性。【结论】 19种药剂中,适于褐飞虱防治的有吡蚜酮、烯啶虫胺、呋虫胺、噻虫胺、环氧虫啶、氟啶虫胺腈、毒死蜱、哒嗪硫磷、异丙威共9种。其中,吡蚜酮持效性最佳且对卵之外各虫态活性较好,但速效性最差。呋虫胺、烯啶虫胺、噻虫胺和环氧虫啶等的速效性、持效性均较突出,且前三者对各虫态均有效。氟啶虫胺腈杀虫活性和速效性均好,但持效性差于新烟碱类。毒死蜱和哒嗪硫磷可单独或在防治其他害虫时兼防治褐飞虱,其中毒死蜱速效性最好,适合于大虫量时快速压低虫量。异丙威杀虫活性弱于新烟碱类,但速效性强于新烟碱类药剂,适合与吡蚜酮等混用或复配。此外,用于鳞翅目害虫防治的乙基多杀菌素、阿维菌素、甲维盐对褐飞虱有一定活性,适合防治其他害虫时兼治褐飞虱。而其余药剂如吡虫啉、噻嗪酮、噻虫嗪等7种药剂不适用于褐飞虱的防治。  相似文献   

6.
【目的】系统评价市场上常用杀虫剂对褐飞虱不同虫态的作用特性,为选择对口药剂进行防治提供依据。【方法】采用稻苗浸渍法,在室内条件下测定了9种新烟碱类药剂和10种其他类型杀虫剂对褐飞虱不同虫态的杀虫活性、速效性和持效性。【结果】1)杀虫活性:不同杀虫剂活性存在显著差异。其中,烯啶虫胺、噻虫胺、毒死蜱、氟啶虫胺腈、呋虫胺和环氧虫啶活性最好,其次为哒嗪硫磷、乙基多杀菌素、吡蚜酮、异丙威,阿维菌素;其余药剂中噻虫嗪、甲维盐、氟啶虫酰胺对2~3龄若虫有一定活性而对4~5龄虫活性差,噻嗪酮、吡虫啉、噻虫啉、啶虫脒、氯噻啉对两种虫态的活性均较差。2)速效性:毒死蜱、哒嗪硫磷的速效性最好,异丙威、呋虫胺、烯啶虫胺、噻虫胺等次之,吡蚜酮最差。3)持效性:吡蚜酮、呋虫胺、烯啶虫胺、噻虫胺、环氧虫啶持效期>15d,其中吡蚜酮最好,药后0、5和10 d连续3批接的试虫死亡率无显著差异。4)成虫:呋虫胺、烯啶虫胺、噻虫胺、环氧虫啶、毒死蜱、异丙威、吡蚜酮对雌雄成虫均有效,类似于若虫。5)卵:毒死蜱、烯啶虫胺、呋虫胺和噻虫胺对卵及孵化的若虫均有效;吡蚜酮、环氧虫啶、异丙威等无明显杀卵活性,但吡蚜酮对孵化若虫有较好的杀虫活性。【结论】19种药剂中,适于褐飞虱防治的有吡蚜酮、烯啶虫胺、呋虫胺、噻虫胺、环氧虫啶、氟啶虫胺腈、毒死蜱、哒嗪硫磷、异丙威共9种。其中,吡蚜酮持效性最佳且对卵之外各虫态活性较好,但速效性最差。呋虫胺、烯啶虫胺、噻虫胺和环氧虫啶等的速效性、持效性均较突出,且前三者对各虫态均有效。氟啶虫胺腈杀虫活性和速效性均好,但持效性差于新烟碱类。毒死蜱和哒嗪硫磷可单独或在防治其他害虫时兼防治褐飞虱,其中毒死蜱速效性最好,适合于大虫量时快速压低虫量。异丙威杀虫活性弱于新烟碱类,但速效性强于新烟碱类药剂,适合与吡蚜酮等混用或复配。此外,用于鳞翅目害虫防治的乙基多杀菌素、阿维菌素、甲维盐对褐飞虱有一定活性,适合防治其他害虫时兼治褐飞虱。而其余药剂如吡虫啉、噻嗪酮、噻虫嗪等7种药剂不适用于褐飞虱的防治。  相似文献   

7.
我国主要稻区褐飞虱对常用杀虫剂的抗性监测   总被引:11,自引:1,他引:10  
为了明确目前褐飞虱对常用药剂的抗性现状,以便制定防治褐飞虱的科学用药策略,于2010-2011年间,在室内采用稻茎浸渍法监测了我国主要稻区19个褐飞虱种群对五种常用杀虫剂的抗性。结果表明,2010年全部监测种群对噻嗪酮均处于中等水平抗性(RR为11.3~23.4倍),2011年除广西桂林、江西上高2个褐飞虱种群为中等水平抗性(15.3~19.7倍)外,其他80%监测种群均已达高水平抗性(40.7~119.7倍),抗性明显上升;两年19个褐飞虱监测种群对吡虫啉均为高到极高水平抗性(82.3~1935.8倍),与2006-2009年相比,吡虫啉抗性有再次升高趋势;2010年褐飞虱对噻虫嗪的抗性为低到中等水平抗性(6.1~14.4倍),2011年除广西桂林种群为低水平抗性外,其他8个种群均为中到高水平抗性(12.8~62.3倍),较前一年明显上升;两年18个监测种群对毒死蜱均处于敏感到低水平抗性阶段;对吡蚜酮的抗性2010年7个监测种群为敏感-低水平抗性(1.9~5.1倍),2011年全部褐飞虱监测种群均已达中等水平抗性(15.7~25.4倍),暗示随着吡蚜酮的大量广泛使用,褐飞虱对其抗性较高,需要引起生产上的密切关注。为科学治理水稻褐飞虱,应严格执行无交互抗性的杀虫剂间的合理轮用或混用。  相似文献   

8.
 在室内采用稻茎浸渍法进行了灰飞虱对氟虫腈抗性风险评估、抗性遗传分析和杀虫剂的敏感性研究。于2005年采自无锡麦田的灰飞虱种群在室内饲养43代期间用氟虫腈筛选了41代,结果此灰飞虱种群的抗性从8.4倍上升到2305倍。根据Tabashnik介绍的方法计算,现实遗传力(h2)分别为0.0388(1~31代)、0.2636(32~43代)和0.1113(1~43代), 表明灰飞虱对氟虫腈具有一定的抗性风险。采用稻茎浸渍法测定了2007-2008年江苏无锡和浙江长兴两地灰飞虱种群对15种杀虫剂的敏感性, 结果表明,苯基吡唑类杀虫剂氟虫腈、丁烯氟虫腈和乙虫腈的毒力最高(LC50=0.2~1.7 mg/L),其次为烯啶虫胺、噻虫嗪、毒死蜱、吡蚜酮(LC50=1.7~9.7 mg/L),其余杀虫剂的毒力较低;按照年度间敏感性变化,发现2008年无锡灰飞虱种群对氟虫腈和乙虫腈的敏感性比2007年降低了1.1倍。近年来氟虫腈已广泛用于防治这种害虫,但乙虫腈几乎没有使用。因此,对氟虫腈敏感性降低的大田灰飞虱种群似乎对乙虫腈存在交互抗性。通过抗(R)、感(S)亲本、正反交(F1、 F1′)、自交(F2)及回交(BC)后代对氟虫腈的剂量反应研究了灰飞虱对氟虫腈的抗性遗传特性,结果表明,其抗性为常染色体的不完全显性遗传\[D(F1)=0.20, D(F1′)=0.38\],抗性由2个或2个以上等位基因控制。还对灰飞虱的抗性治理进行了讨论。  相似文献   

9.
褐飞虱对吡虫啉敏感性的时空变化及现实遗传力   总被引:12,自引:0,他引:12  
为科学用药,采用稻茎浸渍法测定了我国7省(区)42个田间褐飞虱种群对吡虫啉的敏感性时空变化。结果表明,在1996-2003年,除了1997年广西桂林种群为低水平抗性(6.3倍)外,苏、皖、桂3省13个种群对吡虫啉为敏感至敏感性下降(<5倍);然而,2005年苏、浙、皖、赣、湘、桂6省(区)16个大田种群对吡虫啉的抗性迅速上升,达高水平至极高水平抗性(79~811倍);2006年,除江苏通州大田种群的抗性为627倍外,苏、浙、皖、赣、湘、桂、闽7省(区)11个种群的抗性为150~322倍,比2005年有一定程度下降,这可能与暂停使用吡虫啉有关。室内用吡虫啉对褐飞虱筛选18代,其抗性由筛选前的208.3倍上升到筛选后的1110.8倍,抗性现实遗传力(h2)为0.1414。这暗示褐飞虱对吡虫啉产生高水平抗性后,如继续使用吡虫啉防治,其抗性可能会进一步上升。还讨论了稻褐飞虱抗药性的治理策略。  相似文献   

10.
浙江省褐飞虱抗药性监测与治理   总被引:2,自引:0,他引:2  
对浙江省稻区采集的水稻褐飞虱,应用稻茎浸渍法测定其对主要防治药剂的抗药性.结果表明,褐飞虱对吡虫啉仍维持高水平抗性,但抗性水平比2005年有下降,对噻嗪酮和氟虫腈仍为敏感。根据褐飞虱的抗药性水平,制定用药方案,是治理抗性褐飞虱,控制褐飞虱为害的有效措施。  相似文献   

11.
The cotton whitefly Bemisia tabaci, (Genn.) is an important pest of field crops, vegetables and ornamentals worldwide. Neonicotinoids are considered an important group of insecticides being used against B. tabaci for several years. B. tabaci has developed resistance to some of the compounds of the group. This study was designed to investigate if the selection of B. tabaci with acetamiprid would give a broad-spectrum of cross-resistance and to genetically classify the resistance. At G1 a low level of resistance to acetamiprid, imidacloprid, thiamethoxam, thiacloprid and nitenpyram was observed with resistance ratios of 3-fold, 8-, 9-, 6- and 5-fold, respectively, compared with a laboratory susceptible population. After selection for eight generations with acetamiprid, resistance to acetamiprid increased to 118-fold compared with the laboratory susceptible population. Selection also increased resistance to imidacloprid, thiamethoxam, thiacloprid, nitenpyram, endosulfan and bifenthrin but no change in susceptibility to fipronil was observed. Furthermore resistance in a field population was stable in the absence of acetamiprid selection pressure. Genetic crosses between resistant and susceptible populations indicated autosomal and incompletely recessive resistance. Further genetic analysis suggested that resistance could be controlled by a single factor. The high level of cross-resistance and stability of incomplete resistance in the field population is of some concern. However, lack of cross-resistance between acetamiprid and fipronil or unstable resistance in the resistant population could provide options to use alternative products which could reduce acetamiprid selection pressure.  相似文献   

12.
The Asian citrus psyllid, Diaphorina citri Kuwayama being a vector of huanglongbing (HLB), citrus greening disease is the most destructive pest of citrus and the management of D. citri is crucial for successful control of HLB. We evaluated adult populations of D. citri from twelve districts of Punjab, Pakistan for resistance to seven different insecticides. Different levels of resistance ratios were observed for all insecticides (chlorpyrifos, bifenthrin, imidacloprid, acetamiprid, thiamethoxam, nitenpyram and chlorfenapyr). Field collected populations of D. citri were highly resistant to imidacloprid as compared to the susceptible population. The resistance ratios were in range of 236.6–759.5, 55.5–212.8, 13.1–46.4, 31.4–216.7, 8.6–89.4-fold for imidacloprid, acetamiprid, chlorfenapyr, nitenpyram, and thiamethoxam, respectively and 39.8–107.1 and 32.7–124.5-fold in case of conventional insecticides i.e., bifenthrin and chlorpyrifos, respectively. Nitenpyram and thiamethoxam, with no or very low resistance should be used in combination or in rotation with other pest management tactics for managing resistance in D. citri. The correlation analysis of the LC50's of insecticides showing positive and negative correlations among different insecticides in all tested populations, suggests mechanism of cross-resistance. Imidacloprid showed a positive correlation with acetamaprid, but a negative correlation with thiamethoxam from the neonicotenoid group, while the resistance to chlorfenpyr positively correlated with chlorpyrifos and bifenthrin in the pyrethroid group. Multiple resistance mechanisms could be the reason behind the development of such a high resistance in the D. citri.  相似文献   

13.
Susceptibility to insecticides was investigated by collecting field populations of brown planthopper from different locations of southern Karnataka,India(Gangavati,Kathalagere,Kollegala,Soraba and Mandya).All the field populations differed in their susceptibility to insecticides.In general,Soraba and Mandya populations were more susceptible to insecticides compared to Gangavati and Kathalagere populations.The resistance ratios varied greatly among the populations viz.,chlorpyriphos(1.13-to 16.82-fold),imidacloprid(0.53-to 13.50-fold),acephate(1.34-to 5.32-fold),fipronil(1.13-to4.06-fold),thiamethoxam(1.01-to 2.19-fold),clothianidin(1.92-to 4.86-fold),dinotefuran(0.82-to 2.22-fold),buprofezin(1.06-to 5.43-fold)and carbofuran(0.41-to 2.17-fold).The populations from Gangavati,Kathalagere and Kollegala exhibited higher resistance to some of the old insecticides and low resistance to new molecules.  相似文献   

14.
The brown planthopper (Nilaparvata lugens Stål) is one of the most destructive pests of rice crops in Asian countries including China, Vietnam, Thailand, etc. Evolution of resistance in this pest insect to isoprocarb, buprofezin, pymetrozine, imidacloprid and other neonicotinoid insecticides has been reported. In order to investigate the current status of resistance to commonly used insecticides, nine field populations of N. lugens were collected from Central China, East China and South China, and resistance to insecticides was monitored from 2009 to 2012. All the 9 field populations collected in 2012 had developed extremely high resistance to imidacloprid, with resistance ratios (RR) ranging from 209.3 to 616.6. Resistance to imidacloprid was much higher in 2012 than in 2009. The RR of thiamethoxam varied from 17.4 to 47.1, and the RR of nitenpyram varied from 1.4 to 3.7 in 2012. Of the 9 field populations, six populations showed higher resistance to nitenpyram in 2012 than in 2011. RR for buprofezin varied from 110.1 to 221.6 in 2012 whereas resistance was at a medium level (RR 20.4 ∼ 39.4-fold) in 2009. RR for pymetrozine ranged from 34.9 to 46.8 in 2012. As for isoprocarb, RR ranged from 21.7 to 38.1 in 2012. The obvious increase in resistance to widely applied insecticides indicates that insecticide resistance management strategies are urgently needed to prevent or delay further increase of insecticide resistance in N. lugens.  相似文献   

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