紫茎泽兰乙醇提取物对棉铃虫生长发育和繁殖力的影响

采用室内生物测定法研究了紫茎泽兰Eupatorium adenophorum Spreng乙醇提取物对棉铃虫Helicoverpa armigera (Hübner)生长发育和繁殖力的影响。结果表明,当给棉铃虫幼虫饲喂含紫茎泽兰提取物浓度分别为0.088、0.44、2.2和11 g/kg的饲料时,棉铃虫的死亡率显著高于对照,而羽化率和蛹重均显著低于对照（P≤0.05）。在棉铃虫成虫产卵实验中,0.08、0.4和2 g/L紫茎泽兰提取物对产卵有一定引诱作用,而10 g/L则对产卵有驱避作用。取食浓度分别为0.08、0.4、2和10 g/L紫茎泽兰提取物的棉铃虫卵孵化率降低。表明取食紫茎泽兰提取物对棉铃虫的生长发育和繁殖有明显不利影响。     

黄杜鹃对美洲斑潜蝇的生物活性研究(英文)

试验结果表明 ,闹羊花素 Ⅲ 50 0mg/L对美洲斑潜蝇 2龄和 3龄幼虫的取食抑制率分别为 77 34%和6 7 6 6 % ,高于杀虫单的取食抑制率。对 2龄和 3龄幼虫的LC50 分别为 2 0 8 6 5mg/L和 30 0 6 2mg/L。药膜法测得对成虫 2 4h的LC50 为 159 0 7mg/L ;4 8h为 54 85mg/L。黄杜鹃花几种粗提物也表现出不同程度的取食抑制作用和毒杀作用。     

植物提取物对萝卜蚜的室内毒力研究

采用浸叶法和Potter喷雾法测定七种植物提取物对萝卜蚜 (Lipaphiserysim)的室内毒力效果。研究结果显示 :巴豆、博落回和醉鱼草提取物对萝卜蚜的致死中浓度LC50 分别为 1 86.94mg/L、2 0 0 .75mg/L和 1 5 7.73mg/L。     

爵床的甲醇提取物对小菜蛾的生物活性作用

为探明爵床(Justicia procumbens)甲醇提取物对小菜蛾的生物活性,采用室内生测法测定了爵床甲醇提取物对小菜蛾的触杀、拒食、胃毒、生长发育抑制和产卵忌避作用。结果表明,爵床甲醇提取物对小菜蛾幼虫具有较强的触杀、拒食、胃毒和生长发育抑制活性,对小菜蛾成虫具有较强的产卵忌避活性。在触杀试验中,药后1、2 d和3 d爵床甲醇提取物对小菜蛾3龄幼虫的致死中浓度(LC50)分别为5.17、4.05和3.06 mg/m L;在拒食试验中,药后1 d和2 d提取物对3龄幼虫的选择性拒食中浓度(AFC50)分别为2.64和3.13 mg/m L,药后1 d和2 d提取物对3龄幼虫的非选择性拒食中浓度(AFC50)分别为3.70、4.54 mg/m L;在胃毒试验中,药后4、5、6 d和7 d提取物对3龄幼虫的致死中浓度(LC50)分别为8.13、3.65、2.88、2.23 mg/m L;在生长发育抑制试验中,药后1 d和2 d提取物对3龄幼虫的抑制中浓度(IC50)分别为2.02、1.40 mg/m L;在产卵忌避试验中,药后1、2 d和3 d提取物对小菜蛾成虫的选择性产卵忌避中浓度(AOC50)分别为2.61、3.66、4.58 mg/m L,药后1、2和3 d提取物对小菜蛾成虫的非选择性产卵忌避中浓度(AOC50)分别为3.19、4.52、5.65 mg/m L。由此证实,爵床提取物对小菜蛾具有显著的毒杀活性,具有开发为新型高效、低毒植物源农药的潜在价值。     

石菖蒲根茎甲醇提取物对谷蠹的生物活性

采用冷浸法和溶剂萃取法,研究石菖蒲(Acorus gramineus Soland)根茎甲醇提取物对谷蠹Rhizopertha dominica(Fabricius)成虫的生物活性。结果表明,石菖蒲甲醇提取物以石油醚萃取物的生物活性最强,水层次之。石油醚萃取物对谷蠹具有较高的触杀、熏蒸、种群抑制活性和防治效果,并具有一定的驱避活性。药膜法触杀处理72h后对谷蠹的LC50和LC95分别为8.30μg/cm2,51.75μg/cm2。药纸熏蒸法6.25μL/L处理120h后对谷蠹的校正死亡率为94.25%。饲料拌药法250mg/kg处理对谷蠹的防效与5mg/kg马拉硫磷效果相当,且对F1代的种群抑制效果显著高于5mg/kg马拉硫磷处理。     

土荆芥的石油醚提取物及精油对冈比亚按蚊的杀虫活性

在室内条件下测试了土荆芥Chenopodium ambrosioides 叶片的石油醚提取物及精油对冈比亚按蚊Anopheles gambiae 0～2 d龄成虫和1～4龄幼虫的毒性。每一龄期各取30头幼虫分别接触50,100,250,500,750和1 000 mg/L提取物和精油,于24 h和48 h后记录死亡幼虫的数目。30头成虫在密封的长方形玻璃笼子中分别接触0.8,1.6,2.4 μL/L土荆芥精油蒸气, 24 h后记录死亡率。结果表明,测试的提取物和精油对冈比亚按蚊的各龄幼虫和成虫均具有毒性。48 h致死中浓度（LC50）的测试结果表明,石油醚提取物对1龄幼虫的毒性最强（14.89 mg/L）,其次是对4龄幼虫（18.90 mg/L）,对3龄幼虫的毒性最低（183.77 mg/L）; 精油对4龄幼虫毒性最强（36.62 mg/L）,其次是对1龄幼虫（90.75 mg/L）。推算的土荆芥精油对冈比亚按蚊的LC50为1.01 μL/L。本研究揭示了土荆芥对冈比亚按蚊的防治潜力。     

藁本提取物杀虫活性初步研究

分别采用点滴法、三角瓶熏蒸法和小叶碟添加法测定了藁本（Ligusticum sinense Oliv．）提取物对粘虫（Mythimna separata Walker）和小菜蛾（Plutella xylostella L．）幼虫的触杀、熏蒸和拒食活性,同时也测定了对黄粉虫（Tenebrio molitor L．）蛹的生长发育有抑制作用,并对其致毒症状、作用方式进行了初步探讨。结果表明,不同溶剂提取物中,丙酮冷浸提取物对粘虫毒杀活性较高;其丙酮提取物对粘虫和小菜蛾3龄幼虫均具有较高触杀及熏蒸活性,24h触杀LD50分别为0．062 3mg干样／头和0．150 2mg干样／头;12h熏蒸LC530分别为24．3422 mg干样／L和10．601 5mg干样／L;对黄粉虫（Tenebrio molitor L）蛹的生长发育有抑制作用,ID50为6．5157mg干样／头;粘虫中毒后先后表现出兴奋、痉挛、麻痹等症状,最后死亡;对黄粉虫蛹生长发育的抑制作用类似于保幼激素活性。     

八角叶片提取物对榕管蓟马成虫的生物活性

本文采用"Y"型管法和三角瓶熏蒸法研究了八角叶的4种溶剂提取物对榕管蓟马成虫的驱避和杀虫作用。结果表明,八角叶的4种溶剂提取物对榕管蓟马成虫均具有驱避和杀虫作用。其中,丙酮、无水乙醇和乙酸乙酯3种溶剂提取物的驱避和杀虫作用较强,浓度为1.60mg/cm2处理的驱避等级均达到Ⅳ级,而相同浓度石油醚提取物的驱避等级仅为Ⅱ级。在杀虫活性方面,用3.54mg/cm2提取物处理36h后,榕管蓟马成虫的校正死亡率除石油醚提取物外均达93.67%以上。另外,八角叶4种溶剂提取物对榕管蓟马成虫的LC50测定表明,丙酮提取物对榕管蓟马成虫的杀虫效果最好。本文结果将为榕管蓟马成虫的防治及植物源杀虫剂的开发提供实验基础。     

泽兰实蝇雌成虫的寄主选择行为

【背景】泽兰实蝇是紫茎泽兰的专性寄生天敌,已成为控制紫茎泽兰的重要因子。泽兰实蝇的寄主选择力对其控制紫茎泽兰至关重要,但相关报道还很少。【方法】采用"Y"形嗅觉仪在实验室内测定泽兰实蝇雌成虫对寄主植物——紫茎泽兰及其他植物的选择行为,以及紫茎泽兰受重金属胁迫后泽兰实蝇对其选择的变化。【结果】不同日龄的泽兰实蝇雌成虫对紫茎泽兰的选择性不具有显著差异;交配与否对雌成虫的寄主选择没有显著影响;雌成虫对紫茎泽兰的选择显著高于黄蒿、水葫芦和蓝花鼠尾草等非寄主植物;雌成虫对花期及机械损伤的紫茎泽兰选择更显著;紫茎泽兰经重金属镉(Cd)、铅(Pb)和锌(Zn)单一及复合处理后,泽兰实蝇雌成虫对其选择性显著降低。【结论与意义】泽兰实蝇雌成虫的寄主选择性随植物种类、寄主植物(紫茎泽兰)的生育期、健康状况及重金属胁迫而变化,这有助于更好地利用泽兰实蝇控制紫茎泽兰。     

紫茎泽兰提取物对3种杂草的化感胁迫作用

为探讨紫茎泽兰(Eupatorium adenophorum)提取物对植物种子萌发和早期幼苗生长的影响及其生理机理,以稗草(Echinochloa crusgalli)、灰绿藜(Chenopodium glaucum)和反枝苋(Amaranthus retroflexus)3种常见的田间杂草为材料,采用根悬空培养等方法,研究了不同浓度紫茎泽兰提取物对3种杂草种子萌发和幼苗生长、根尖组织结构、根系边缘细胞(root border cell,RBC)生理特性和根冠果胶甲基酯酶(pectin methyl esterase,PME)活性的影响。结果发现:紫茎泽兰提取物对3种植物种子萌发均具有明显的抑制作用;1000 mg/L紫茎泽兰提取物处理后,3种杂草幼苗的根尖均有不同程度的伤害,如根尖肿胀、抽缩或变形;根尖表层细胞脱落、内层细胞排列混乱。紫茎泽兰提取物处理能显著抑制3种杂草幼苗根尖RBC的数量(分别比对照降低了44.5%、48.3%和64.0%);诱导RBC凋亡(凋亡率分别达到81.7%、91.3%和97.1%)并显著增加RBC的黏胶层厚度(分别比对照增加了99.0%、65.5%和61.1%)及诱导PME活性升高。这些结果表明:紫茎泽兰提取物抑制了3种杂草根边缘细胞的产生,并诱导了根尖边缘细胞凋亡,因而破坏了根边缘细胞对根尖的保护系统,最终抑制了根系的生长发育。研究为将紫茎泽兰提取物用于植物源除草剂的开发提供了理论依据。     

Imported longhorned weevil (Coleoptera: Curculionidae) injury to soybean: physiological response and injury guild-level economic injury levels

The imported longhorned weevil, Calomycterus setarius Roelofs, is an occasional pest of soybean, Glycine max (L.), and can cause substantial defoliation of seedling soybean when the weevil is present in large numbers. Because weevil populations can reach high levels, the potential exists for significant seedling injury, so economic injury levels (EILs) are needed for imported longhorned weevil on seedling soybean. Because the bean leaf beetle, Cerotoma trifurcata (Forster), also is present on seedling soybean, injury by this insect should be included in EIL calculations. This study was conducted to (1) determine daily soybean consumption rates of imported longhorned weevil; (2) compare soybean injury responses between weevil injured and noninjured soybeans; and (3) develop multiple species EILs for imported longhorned weevil and bean leaf beetle. Field and laboratory studies were conducted in 1997 to determine weevil daily consumption rates. Field experiments were conducted in 1998 to examine physiological responses of soybean to weevil injury. Field and laboratory consumption rates were 0.16 and 0.21 cm2 per day, respectively. There were no significant differences in physiological responses (i.e., photosynthetic rates, stomatal conductance, and transpiration rates) between noninjured soybean leaflets (caged) and weevil-injured leaflets. Multiple-species EILs were developed for imported longhorned weevil and bean leaf beetle on VC through V3 soybean.     

铜、锌、镉对唐鱼胚胎及初孵仔鱼的急性毒性及安全浓度评价

采用静水法生物测试研究铜（Cu2＋）、锌（Zn2＋）和镉（Cd2＋）对唐鱼（Tanichthys albonubes）胚胎和初孵仔鱼的急性毒性及安全浓度评价。结果显示,Cu2＋对唐鱼胚胎12、24h LC50分别为2.4092mg/L和0.4039mg/L;Zn2＋和Cd2＋对唐鱼胚胎24h LC50分别为372.9mg/L和50.0mg/L。Cu2＋对唐鱼初孵仔鱼12、24和48h LC50都是0.3228mg/L,其安全浓度为0.0986mg/L;Zn2＋对唐鱼初孵仔鱼24、48h LC50分别为72.44mg/L和25.17mg/L,其安全浓度为0.9116mg/L;Cd2＋对唐鱼初孵仔鱼24、48h LC50分别为36.5mg/L和20.59mg/L,其安全浓度为1.9654mg/L。结果表明,重金属元素对唐鱼胚胎和初孵仔鱼毒性依次为Cu2＋〉Cd2＋〉Zn2＋。     

Fumigant toxicity of plant essential oils against Camptomyia corticalis (Diptera: Cecidomyiidae)

The toxicity of 98 plant essential oils against third instars of cecidomyiid gall midge Camptomyia corticalis (Loew) (Diptera: Cecidomyiidae) was examined using a vapor-phase mortality bioassay. Results were compared with that of a conventional insecticide dichlorvos. Based on 24-h LC50 values, all essential oils were less toxic than dichlorvos (LC50, 0.027 mg/cm3). The LC50 of caraway (Carum carvi L.) seed, armoise (Artemisia vulgaris L.), clary sage (Salvia sclarea L.), oregano (Origanum vulgare L.), lemongrass [Cymbopogon citratus (DC.) Stapf], niaouli (Melaleuca viridiflora Gaertner), spearmint (Mentha spicata L.), cassia especial (Cinnamomum cassia Nees ex Blume), Dalmatian sage (Salvia offcinalis L.), red thyme (Thymus vulgaris L.), bay [Pimenta racemosa (P. Mill.) J.W. Moore], garlic (Allium sativum L.), and pennyroyal (Mentha pulegium L.) oils is between 0.55 and 0.60 mg/cm3. The LC50 of cassia (C. cassia, pure and redistilled), white thyme (T. vulgaris), star anise (Illicium verum Hook.f.), peppermint (Mentha X piperita L.), wintergreen (Gaultheria procumbens L.), cinnamon (Cinnamomum zeylanicum Blume) bark, sweet marjoram (Origanum majorana L.), Roman chamomile [Chamaemelum nobile (L.) All.], eucalyptus (Eucalyptus globulus Labill.), rosemary (Rosmarinus officinalis L.),Virginian cedarwood (Juniperus virginiana L.), pimento berry [Pimenta dioica (L.) Merr.], summer savory (Satureja hortensis L.), lavender (Lavandula angustifolia Mill.), and coriander (Coriandrum sativum L.) oils is between 0.61 and 0.99 mg/cm3. All other essential oils tested exhibited low toxicity to the cecidomyiid larvae (LC50, >0.99 mg/cm3). Global efforts to reduce the level of highly toxic synthetic insecticides in the agricultural environment justify further studies on the active essential oils as potential larvicides for the control of C. corticalis populations as fumigants with contact action.     

4种常用水产药物对青虾幼虾的毒性研究

采用静水法研究了4种常用水产药物对青虾幼虾的毒性。结果表明：水温29℃~30℃时,溴氯海因对青虾幼虾24 h、48 h和72 h的LC50分别为19.05 mg/L、11.75 mg/L、11.75 mg/L,安全浓度为1.24 mg/L;聚维酮碘对青虾幼虾的24 h、48 h和72 h的LC50分别为49.27 mg/L、44.61 mg/L、43.68 mg/L,安全浓度为10.52 mg/L;甲醛对青虾幼虾的24 h、48 h和72 h的LC50分别为72.47 mg/L、66.41 mg/L、53.71 mg/L,安全浓度为10.93 mg/L;高锰酸钾对青虾幼虾的24 h、48 h和72 h的半致死浓度（LC50）分别为6.06 mg/L、4.07 mg/L、3.79 mg/L,安全浓度为0.48 mg/L。4种药物对青虾幼虾的毒性依次为高锰酸钾〉溴氯海因〉聚维酮碘〉甲醛。     

双酚A和壬基酚对隆线溞和微型裸腹溞的毒性

我们以隆线溞和微型裸腹溞为实验动物,进行了两种酚类内分泌干扰物双酚A（BPA）和壬基酚(NP)的毒性效应研究。急性实验测定出双酚A对隆线溞的24h和48h半数致死浓度（LC50）为：12.02mg/L和11.64mg/L,对微型裸腹溞24h和48h半数致死浓度LC50为：13.70mg/L和9.63mg/L。而壬基酚对隆线溞的24h和48h半数致死浓度（LC50）分别为：0.221mg/L和0.159mg/L,对微型裸腹溞的24h和48h半数致死浓度（LC50）分别为：0.334mg/L和0.126mg/L。实验表明微型裸腹溞对双酚A和壬基酚的敏感度高于隆线溞,能够很好的指示水环境的污染。慢性毒性实验发现双酚A对微型裸腹溞后代的雌雄比例有明显的影响,影响类似于hormesis现象。而壬基酚对隆线溞的慢性毒性研究发现,隆线溞的生活史、后代成活率均受到暴露的壬基酚浓度升高的不利影响。这些研究表明低浓度双酚A长期暴露的潜在毒性与高浓度壬基酚的急性毒性在这两种内分泌干扰物污染环境的研究中有重要意义。     

Acute toxicity of organophosphorus and pyrethroid insecticides to Bombyx mori

Acute toxicities of two organophosphorus insecticides (dichlorvos and phoxim), four pyrethroid insecticides (permethrin, tetramethrin, bifenthrin, and ethofenprox), and their combined uses to the third instar of the silkworm, Bombyx mori (L.), were determined by feeding the insect with the insecticide-treated mulberry, Morus albus (L.), leaves. Twenty-four and 48 h after treatment, toxicity levels of all insecticides to the silkworm were in the very high or high range, and the LC50 values of permethrin, tetramethrin, bifenthrin, ethofenprox, dichlorvos, and phoxim were 1.60 and 0.75, 3.86 and 2.83, 0.09 and 0.06, 2.87 and 0.80, 6.63 and 4.11, and 1.05 and 0.45 mg liter(-1), respectively. The toxicity levels of 50:50 binary mixtures of organophosphorus and pyrethroid insecticides to the silkworm were in the high or middle range. Twenty-four and 48 h after treatment, the LC50 values of 50:50 binary mixtures permethrin + phoxim, permethrin + dichlorvos, tetramethrin + phoxim, tetramethrin + dichlorvos, bifenthrin + phoxim, bifenthrin + dichlorvos, ethofenprox + phoxim, and ethofenprox + dichlorvos to the silkworm were 1.49 and 0.85, 1.24 and 0.79, 2.20 and 1.08, 14.62 and 13.16, 0.33 and 0.13, 0.12 and 0.10, 2.81 and 1.37, and 4.82 and 3.00 mg liter(-1), respectively. Based on the combinations coefficient values, the toxicities of binary mixtures of organophosphorus and pyrethroid insecticides had additive effect except for the binary mixture of etramethrin + dichlorvos, which showed antagonism effect.     

Acute and joint toxicity of three agrochemicals to Chinese tiger frog(Hoplobatrachus chinensis) tadpoles

We studied acute and joint toxicity of three different agrochemicals(chlorantraniliprole, flubendiamide-abamectin and penoxsulam) to Chinese tiger frog(Hoplobatrachus chinensis) tadpoles with the method of stability water tests. Results showed that the three agrochemicals increased tadpole mortality. For acute toxicity, the LC50 values after 24, 48 and 72 h of chlorantraniliprole, flubendiamide-abamectin and penoxsulam exposure were 5.37, 4.90 and 4.68 mg/L; 0.035, 0.025 and 0.021 mg/L; 1.74, 1.45 and 1.29 mg/L, respectively. The safety concentrations(SC) of chlorantraniliprole, flubendiamide-abamectin and penoxsulam to the tadpoles were 1.23, 0.30 and 0.003 mg/L, respectively. Based on these findings, chlorantraniliprole and penoxsulam were moderately toxic, while flubendiamide-abamectin was highly toxic. All pairwise joint toxicity tests showed moderate toxicity. The LC50 values after 24, 48 and 72 h of exposure were 7.08, 6.61 and 6.03 mg/L for chlorantraniliprole+penoxsulam, with corresponding values of 2.455, 2.328 and 2.183 mg/L for chlorantraniliprole+flubendiamide-abamectin, and 1.132, 1.084 and 1.050 mg/L for penoxsulam+flubendiamide-abamectin, with safe concentrations of 1.73, 0.63 and 0.30 mg/L, respectively. For toxic evaluations of pairwise combinations of the three agrochemicals, only the joint toxicity of chlorantraniliprole and flubendiamide-abamectin after 24 h was found to be synergistic, whereas all other tests were antagonistic. Our findings provide valuable information on the toxic effects of agrochemicals on amphibians and how various types of agrochemicals can be reasonably used in agricultural areas.     

Phosphorus benefits of different legume crops to subsequent wheat grown in different soils of Western Australia

Certain legume crops, including white lupin (Lupinus albus L.), mobilise soil-bound phosphorus (P) through root exudates. The changes in the rhizosphere enhance P availability to these crops, and possibly to subsequent crops growing in the same soil. We conducted a pot experiment to compare phosphorus acquisition of three legume species with that of wheat, and to determine whether the legume crops influence growth and P uptake of a subsequent wheat crop. Field pea (Pisum sativum L.), faba bean (Vicia faba L.), white lupin (Lupinus albus L.) and wheat (Triticum aestivum L.) were grown in three different soils to which we added no or 20 mg P kg^–1 soil (P0, P20). Growth, P content and rhizosphere carboxylates varied significantly amongst crops, soils and P levels. Total P content of the plants was increased with applied phosphorus. Phosphorus content of faba bean was 3.9 and 8.8 mg/pot, at P0 and P20, respectively, which was about double that of all other species at the respective P levels. Field pea and white lupin had large amounts of rhizosphere carboxylates, whereas wheat and faba bean had negligible amounts in all three soils at both P levels. Wheat grew better after legumes than after wheat in all three soils. The effect of the previous plant species was greater when these previous species had received P fertiliser. All the legumes increased plant biomass of subsequent wheat significantly over the unplanted pots in all the soils. Faba bean was unparalleled in promoting subsequent wheat growth on all fertilised soils. This experiment clearly demonstrated a residual benefit of the legume crops on the growth of the subsequent wheat crop due to enhanced P uptake. Faba bean appeared to be a suitable P-mobilising legume crop plant for use in rotations with wheat.     

Azadirachtin as a larvicide against the horn fly, stable fly, and house fly (Diptera: Muscidae)

Effects of azadirachtin, a triterpenoid extracted from neem seed, Azadirachta indica A. Juss., were similar to those of insect growth regulators against the immature stages of the born fly, Haematobia irritans (L.), the stable fly, Stomoxys calcitrans (L.), and the house fly, Musca domestica L. When an ethanolic extract of ground seed was blended into cow manure, LC50 and LC90's for larval horn flies were 0.096 and 0.133 ppm azadirachtin, respectively. An emulsifiable concentrate (EC) had an LC50 for larval horn flies of 0.151 ppm and an LC90 of 0.268 ppm. For larval stable flies, the EC formulation had an LC50 of 7.7 ppm and an LC90 of 18.7 ppm azadirachtin in manure. Against larval house flies, the LC50 and LC90 were 10.5 and 20.2 ppm, respectively. When the EC formulation was administered orally to cattle at a rate of greater than or equal to 0.03 mg azadirachtin per kg of body weight per day or when ground neem seed was given as a daily supplement of greater than or equal to 10 mg seed per kg body weight, horn fly development in the manure was almost completely inhibited. In contrast, ground seed mixed in cattle feed at the rate of 100-400 mg seed per kg of body weight per day caused less than 50% inhibition of stable flies in the manure.