Relative Toxicity of Aldrin, Fenvalerate, Captan and Diazinon to the Freshwater Food-Fish, Clarias Batrachus

The median lethal concentrations (LC50s) of aldrin, fenvalerate, captan and diazinon were determined for Clarias batrachus by trimmed Spearman-Karber method. The potency ratios of toxicity among them were analysed by parallel-line bioassay with quantal responses. The LC50s for 40 day of exposure of aldrin, fenvalerate, captan and diazinon were 0.00036,0.0094, 0.5473 and 2.4186 ppm respectively. These values were lower than those obtained for an exposure of 96 hour. It shows the greater toxicity of the pesticides in a long-term exposure. The relative toxic potency of aldrin fenvalerate, captan and diazinon was in a ratio of 6807:241:4:1 respectively. Thus the chemically different groups of pesticides exhibit an order of toxicity as aldrin > fenvalerate >captan > diazinon for the freshwater catfish, Clarias batrachus. It infers that the catfish is most sensitive to aldrin and least sensitive to diazinon. The comparison of the sensitivity of various species tested against these pesticidal chemicals has also been done to review the available information.

Diazinon-Induced Clastogenity and Pathological Changes in Ovaries and Testes of Clarias gariepinus

In most tropical developing countries, one of the problems facing aquaculture industry is the pollution of ponds and rivers with pesticides. Chemicals such as diazinon, an organophosphate pesticide, originating from agricultural activity enter the aquatic environment through atmospheric deposition, surface run-off or leaching. Pollutants enter the food chain through accumulation in soft bottom sediment and aquatic organisms. However, information on how these pesticides affect inhabiting organisms is often not available. In a triplicate experimental set-up, seventy-two (72) apparently healthy catfish comprising adult and juvenile of both sexes were therefore exposed to a previously determined no effect concentration (0.405 ppm) of diazinon. Another set of fish was exposed to 0.0625 μg sodium arsenite, a known clastogen, which was used as the positive control, while another set of catfish exposed to the culture water alone was the negative control. Adults and juveniles were exposed separately to avoid cannibalism. After 48 hours of exposure, micronuclei induction was determined in subsets of experimental groups, while exposure continued for 28 days. Catfish organs were harvested on days 21 and 28 to determine the effect of long-term exposure to diazinon on histology. Water quality was also monitored before and during exposure in the experimental groups. The result established a significantly high mean micronucleated polychromatic erythrocytes (15.00) in catfish exposed to diazinon suggesting genetic damage (normal is ≤4). The MPE in sodium arsenite exposed fish was 28, while that of the control group was below 4. Effect of sex and age on micronuclei induction was not significant. Histological alteration observed in the ovary and testis was distorted matured cells and extensive testicular degeneration, respectively. The results show that diazinon has clastogenic effect, and may have endocrine disrupting properties because of the histological changes induced in the ovaries and testis.

High-Performance Liquid Chromatograph (HPLC) Equipped with a Neurophysiological Detector (NPD) as a Tool for Studying Olfactory System Intoxication by the Organophosphate (OP) Pesticide Diazinon and the Influence of OP Pesticides on Reproduction

A neurophysiological detector (NPD) is a hybridization of olfactory system neurons of the fish crucian carp, Carassius carassius L., with a computerized electronic device connected to a high-performance liquid chromatograph (HPLC). This system makes it possible to measure neurophysiological activities in the olfactory system of C. carassius L. after exposure of this fish to alarm pheromones. The construction of the system was presented for the first time at the 3rd International Symposium on Separation in Bio Sciences SBS 2003 in I. Brondz, et al., The Fish Olfactory System Used as an In-Line HPLC Neurophysiologic Detector NPD, 3rd Int. Symposium on Separation in Bio Sciences SBS 2003: A 100 Years of Chromatography, 13-18 May, Moscow, Russia, 2003, Abstract O- 27, p. 95. A complete paper was published in I. Brondz, et al., Neurophysiologic Detector (NPD)—A Selective and Sensitive Tool in High-Performance Liquid Chromatography, Chromatography B: Biomedical Sciences and Applications, Vol. 800, No. 1-2, 2004, pp. 41-47, and the hybridization of living cells with an electronic device has been discussed (I. Brondz, et al., International Scientific-Technical Conference Sensors Electronics and Microsystems Technology (SEMST-1), 1-5 June, (Odessa), Ukraine, 2004, Plenum Lecture, Abstract p. 17;I. Brondz, et al., The European Chemoreception Research Organization ECRO 2004 Congress, 12-15 September, (Dijon), France, 2004, Abstract P-3;and I. Brondz, et al., Biosensors as Electronic Compounds for Detector in the High-Performance Liquid Chromatography (HPLC), Electronic Components and Systems, Vol. 3, No. 103, 2006, pp. 25-27). In the present study, an HPLC equipped with an NPD was used to assess the influence of organophosphate (OP) pesticides on olfactory sensory nerves and the modification of nerve signals from the olfactory organ. The results show that exposure of the olfactory system to OP pesticides can lead to disruption of normal reflexes and to significant suppression of individual sexual activity and, as a result, to the suppression of a population.

Diazinon Toxicokinetics, Tissue Distribution and Anticholinesterase Activity in the Rat

The toxicokinetics, tissue distribution, and anticholinesteruse (antiChE ) activity of diazinon were investigated in the rat. Plasma concentrations most adequately fitted a two-compartment open model after iv administration of 10 mg/kg and a one-compartment model after oral administration of 80 mg/kg. Diazinon elimination half-life following iv and oral dosing was 4.70 and 2.86 h, respectively. The oral bioavailabllity was found to be low (35.5%). Hepatic extraction ratios after iv administration of 5 or 10 mg

Mechanism of Diazinon Adsorption on Iron Modified Montmorillonite

The study was carried out with the objective of developing suitable and sustainable low cost adsorbent materials for diazinon, an organophosphate pollutant used as a pesticide. Montmorillonite modified with iron was used. Two different types of iron-montmorillonite, each having different contents of iron and synthesized with different pH and levels of Fe hydrolysis were used. One was denoted “Fe-modified” and the other denoted as “FeOH-modified”. The color of the samples changed from greyish green to light-reddish brown after the modification. X-ray diffraction and physical observations were used for characterization of the samples. The d-spacing of the samples was greater than 15 ?, indicating the formation of iron hydroxides in the interlayer space of montmorillonite. The amount of adsorption was calculated from the difference between the initial and the final concentration of diazinon. The adsorption data were analyzed using the Langmuir adsorption isotherms. The amounts of diazinon adsorbed were 58.8 and 54.1 mmolkg-1 for Fe-modified and FeOH-modified respectively. The steep rise in their adsorption isotherms indicated the possibility of adsorption for low level of diazinon in polluted water.

Chronic Exposure to No-Effect Concentration of Diazinon Induced Histological Lesions in Organs of <i>Clarias</i><i>gariepinus</i>

In all parts of the world pesticides have been found in the aquatic ecosystem and scientific evidence has also shown that they can enter the food chain. Diazinon is an organophosphate pesticide, widely used in agriculture to control a wide variety of suckling and leaf eating insects and recently in fish culture to suppress some parasitic diseases;nevertheless, there is little study on its adverse effect on fish. In this study, seventy-two (72) apparently healthy catfish comprising adult and juvenile of both sexes were used to set up triplicate experimental groups of those exposed to culture water alone (control group), fish exposed to pre-determined no-effect concentration (0.405 ppm) of Diazinon (test group). The fish were exposed for 28 days and fish were sacrificed and organs harvested on days 21 and 28 to determine the effect of long-term exposure to diazinon on organ histology. Histological changes observed in diazinon-exposed catfish were hyperplasia and fusion of the gill epithelium, hyperplasia of mucoid producing cells and aggregation of melanin pigment in the skin. Histological lesions were also seen observed in other organs, including severe diffuse cellular swelling and fatty degeneration of the liver, interstitial congestion of the kidney, carbon deposit on the wall of the heart and multifocal haemorrhage. The water quality of the control was not significantly different from that of the test group throughout the experiment. The lesions detected in cells, tissue, or organs represent an integration of cumulative effects of physiological and biochemical stressors. The histological alterations observed in vital organ of fish show that exposure to “no-effect” concentration of diazinon induced structural damage in fish organs and are likely to affect the functionality of the organs. For example, the adverse effect on the gill might disrupt its feeding and oxygen uptake.

二嗪磷(diazinon)原药规格

二、规格1.原料本品含二嗪磷和有关杂质,外观为黄-褐色液体,无外来杂质和助剂。2.化学和物理要求从交付货物的任何部分所取的样品,都应符合原料规格及下列要求:

Rapid Gas Chromatographic Assay of Diazinon:Application to the Study of Diazinon Kinetics in Rats

A rapid method was developed for the determination of diazinon in plasma using gas chromatography with electron-capture detection (GC-ECD). Following a single extraction with hexane from 100μl of plasma, diazinon was quantitated on a 3% OV-17 column. The detection limit was 10 ng/ml and linearity was obtained in the range of 25 ng/ml-2500 ng/ml.The applicability of the assay to single-dose kinetics in rats is illustrated

分子印迹固相萃取-高效液相色谱法测定果蔬中4种有机磷类农药的残留量

以4种目标物丙溴磷、毒死蜱、二嗪磷、辛硫磷的混合物作为模板分子,乙二醇二甲基丙烯酸酯为交联剂、甲基丙烯酸为功能单体,通过水热聚合法制备分子印迹聚合物(MIPs),将MIPs填充在聚丙烯空柱中制备MIPs固相萃取(MIPs-SPE)柱。将果蔬样品洗净、晾干、粉碎后,分取5.00 g,加入2 g无水硫酸钠,研磨均匀。加入30 mL乙腈,超声1.5 h,离心10 min。分取1 mL上清液过活化好的MIPs-SPE柱,用4 mL正己烷淋洗,6 mL体积比9∶1的甲醇-乙酸混合溶液洗脱。收集洗脱液,于35℃氮气吹干,用1 mL乙腈定容,用高效液相色谱法分析。结果显示:MIPs可特异性识别4种目标物,对目标物的吸附量约非分子印迹聚合物(NIPs)的2.5倍,对硫磷、马拉硫磷、甲拌磷、甲基毒死蜱的吸附量显著低于目标物的;经MIPs-SPE柱净化后,样品大部分基质成分被去除,目标物测定无干扰。4种目标物的浓度在0.005~2.0μmol·L^(−1)内和对应的峰面积呈线性关系,检出限(3S/N)为0.0015~0.0040μmol·L^(−1);在0.01,0.5,1.0,2.0 mg·kg^(−1)加标浓度水平下,4种目标物的回收率为85.9%~102%,测定值的相对标准偏差(n=5)为3.0%~7.1%。方法用于4种果蔬样品的分析,在草莓样品中检出了丙溴磷(检出量为0.07 mg·kg^(−1)),甘蓝样品中检出了辛硫磷(检出量为0.05 mg·kg^(−1)),其他样品中均未检出这4种目标物。

5%二嗪磷·氯噻啉颗粒剂配方筛选

以二嗪磷和氯噻啉为有效成分配制成5%颗粒剂。试验通过对不同分散剂、乳化剂、稳定剂、pH调节剂、载体等的筛选,得到最佳配方。4%二嗪磷折百+1%氯噻啉折百+0.2%环氧大豆油+0.2%三乙醇胺+0.2%SP-OF3498D+0.4%500#+0.4%1601+凹凸棒土补足至100%。试验结果表明,该配方产品热储[(54±2)℃]分解率<5%,其余各项指标符合颗粒剂的标准要求。

4种杀虫剂对水生生物的急性毒性与安全评价

为评价农药在稻田使用后对水生生物的安全性,选择啶虫脒、丙溴磷、二嗪磷和马拉硫磷4种杀虫剂为供试药剂,分别采用静态法和半静态法研究其对斜生栅列藻(Scenedesmus obliquus)、大型溞(Daphnia magna Straus)和斑马鱼(Brachydanio rerio)3种水生生物的急性毒性,并进行环境安全性评价。结果表明:啶虫脒、丙溴磷、二嗪磷和马拉硫磷对斜生栅列藻的72h-EC50值分别为55.3,0.00509,0.249,1.69 mg·L-1,其毒性级别分别为低毒、高毒、高毒和中毒。啶虫脒、丙溴磷、二嗪磷和马拉硫磷对大型溞的48h-EC50值分别为49.2,0.00392,0.03080,0.00165 mg·L-1,其毒性级别分别为低毒、剧毒、剧毒和剧毒。啶虫脒、丙溴磷、二嗪磷和马拉硫磷对斑马鱼的96h-LC50值分别为49.8,0.706,5.12,10.9 mg·L-1,其毒性级别分别为低毒、高毒、中毒和低毒。

二嗪农在猪组织中的GC-NPD残留分析方法

建立了二嗪农在猪血浆、肌肉、肾脏、肝脏及脂肪中残留的 GC- NPD分析方法。以乙酸乙酯∶正己烷 (8∶ 2 )提取 ,加无水硫酸钠及活性炭 ,经振荡、离心、浓缩后 ,用乙腈和石油醚液液分配净化 ,经膜过滤。用 GC- NPD、HP- 1毛细管气相色谱柱进行色谱测定 ,内标法 (马拉硫磷 )定量。回收率分别为 :血浆 (90 .4 4± 0 .90 ) % ,肌肉 (92 .2 2± 1.4 5 ) % ,肾脏 (92 .0 3± 1.6 0 ) % ,肝脏 (89.84± 1.82 ) % ,脂肪 (86 .79± 2 .36 ) % ;变异系数分别为 :血浆 (5 .5 2± 1.31) % ,肌肉(5 .85± 1.87) % ,肾脏 (6 .19± 1.5 7) % ,肝脏 (7.11± 1.86 ) % ,脂肪 (6 .6 3± 1.99) %。内标的回收率 (90 .85± 1.4 1) % ,变异系数 (5 .4 5± 0 .96 ) %。最低检测限是 5 .0 ng/ g。结果表明 ,本检测方法具有简便。

三种有机磷农药在双孢蘑菇及其栽培基质中的残留动态

为明确二嗪磷、毒死蜱和辛硫磷3种有机磷农药在双孢蘑菇栽培过程中的残留动态规律,采用在工厂化双孢蘑菇栽培基质(覆土和培养料)中拌料施药的方式,开展了田间试验,运用QuEChERS净化前处理技术结合UPLC-MS/MS分析,检测了3种农药在双孢蘑菇子实体和栽培基质中的残留动态。结果表明:建立的双孢蘑菇子实体、覆土和培养料3种基质中3种有机磷农药的液相色谱-串联质谱检测方法,经验证,在二嗪磷分别以0.0003、0.003、0.1 mg/kg为添加水平,毒死蜱和辛硫磷分别以0.0006、0.006、0.1 mg/kg为添加水平下,3种有机磷农药在双孢蘑菇、覆土和培养料3种基质中的平均回收率为76%~108%,相对标准偏差为2.2%~13%。检出限分别为:二嗪磷0.0001 mg/kg、毒死蜱和辛硫磷均为0.0002 mg/kg,定量限分别为:二嗪磷0.0003 mg/kg、毒死蜱0.0006 mg/kg和辛硫磷0.0006 mg/kg。在2和10mg/kg两个施药水平下,二嗪磷、毒死蜱和辛硫磷在双孢蘑菇栽培基质中的消解规律均符合一级反应动力学方程,在培养料中的消解半衰期分别为5.2、10.6、13.6 d和5.6、11.4、12.3 d;在覆土中的消解半衰期分别为25.9、41.7、27.2 d和41.7、48.1、36.8 d,且在培养料中的消解快于在覆土中的。在施药剂量不超过10 mg/kg的条件下,在双孢蘑菇子实体中毒死蜱残留量最高,为0.014 mg/kg,超过了欧盟规定的最大残留限量(MRL)标准,其余均低于现行日本、欧盟和美国规定的MRL值。

气质联用测定鱼体内毒死蜱和二嗪农生物富集量

采用匀浆萃取结合氟罗里硅土小柱净化，气相色谱．质谱联用定性定量分析，建立了鱼体不同组织中二嗪农和毒死蜱残留的检测方法，并应用于鲤鱼对2种农药的生物富集量测定。建立的测定方法对毒死蜱和二嗪农最低检测限分别为0．001mg／kg和0．005mg／kg，在添加浓度为0．05—1．00mg／kg时，该方法的回收率为80％-105％。经10d培养，鲤鱼肉、肝脏和鳃对水中毒死蜱和二嗪农均有很强的富集作用，鱼鳃中富集农药量最大，鱼体对毒死蜱的富集作用高于二嗪农。水中毒死蜱和二嗪农浓度分别为0．013—0．140mg／L和0．130—1．100mg／L时，鱼肉、肝和鳃对毒死蜱的富集因子分别为100．23—277．98L／kg，120．51—264．43L／kg和159．40—534．65L／kg；而对二嗪农的富集因子分别为18．04—64．22L／kg，24．04—46．77L／kg和45．92—65．79L／kg。

不同影响因素对二嗪磷微乳剂物理稳定性的影响

采用直接观测外观和测定透明温度范围的方法,对微乳剂的基本组成成分——表面活性剂、助溶剂、水对二嗪磷微乳剂物理稳定性的影响分别进行了研究。对各因素从性质和用量两方面进行了探讨,并研究了无机盐(NaCl)浓度对微乳剂透明温度范围的影响。结果表明:表面活性剂的亲水亲油平衡(HLB)值在12～15之间、助溶剂为乙醇或甲醇时配出的微乳剂较好;不同水质均可配出外观均相、透明的微乳剂,但硬水对微乳剂的冷贮稳定性有一定的影响;NaCl质量分数≤0.5%时的微乳剂其透明温度范围在-5～60℃。

生物质炭施用对韭菜和小青菜吸收富集二嗪磷的影响

为研究生物质炭施用对韭菜和小青菜吸收富集根部施用的5%二嗪磷颗粒剂的影响,在韭菜和小青菜移栽前2周基施生物质炭,分别于移栽后1 d和21 d进行高(0.100 g/kg)低(0.025 mg/kg)2个剂量根部施药处理,移栽后50 d采收,测定地上部分和地下部分农药残留量。结果表明:土壤中的农药通过植物根部吸收而导致地上部的污染,而土壤施用生物质炭抑制了农药的吸收。土壤施用生物质炭含量越高,植株中农药残留越低。当土壤施用生物质炭量分别为0.1%、0.5%和1.0%时,高剂量农药处理组(0.100 g/kg),韭菜叶中农药残留量依次为3.16 mg/kg、2.19 mg/kg和1.84 mg/kg,小青菜叶中残留量分别为4.79 mg/kg、3.45 mg/kg和2.63 mg/kg。相对于韭菜而言,小青菜更容易从土壤中吸收富集二嗪磷,土壤施用农药量为0.100 g/kg时,韭菜和小青菜植株从不添加生物质炭土壤中吸收富集农药量分别为5.19 mg/kg和5.99 mg/kg。

双酚A和敌匹硫磷对MCF-7细胞增殖的影响及其联合作用研究

背景与目的:研究双酚A(BPA)和敌匹硫磷单独和联合作用对MCF-7细胞增殖的影响。材料与方法:设BPA、敌匹硫磷1.0×10-12～1.0×10-5mol/L的不同浓度组(组间10倍浓度差),分别作用雌激素敏感型与不敏感型MCF-7细胞,观察其对细胞增殖的影响,及分别加入雌激素受体抑制剂ICI182780后,对细胞增殖影响的变化。实验并设立溶剂对照组。BPA和敌匹硫磷在1.0×10-8、5.0×10-9和2.5×10-9mol/L浓度时,两者联合作用MCF-7细胞,采用2×2析因设计分析对其增殖的影响。结果:BPA和敌匹硫磷在1.0×10-8mol/L时促增殖效应均达到最大,相对增殖率分别为2.473和2.167,与溶剂对照组比较差异均具有统计学意义(P<0.05);加入ICI182780后,二者对MCF-7的促增殖作用均减弱;二者在各浓度组对雌激素不敏感型MCF-7细胞均无明显促增殖效应;BPA和敌匹硫磷在1.0×10-8、5.0×10-9和2.5×10-9mol/L各浓度组均表现出明显拮抗作用。结论:BPA和敌匹硫磷具有明显的拟雌激素活性,并且通过雌激素受体途径对细胞发挥促增殖效应,二者的联合作用为拮抗作用。

10%二嗪磷颗粒剂防治春花生蛴螬田间药效试验

为验证10%二嗪磷颗粒剂对花生蛴螬防治效果,确定最佳剂量,我们进行了田间试验。结果表明,10%二嗪磷颗粒剂对花生蛴螬的最佳用量为500～1000g/667m2,平均防效在78.09%～91.43%之间,显示了该药剂具有较好的持效期及良好的推广、应用前景。

10%二嗪磷颗粒剂防治小地老虎田间药效试验

为验证10％二嗪磷颗粒刺防治地下害虫的效果，确定最佳刺量，进行了糯玉米地块防治小地老虎的田间药效试验，结果表明：10％二嗪磷颗粒剂对小地老虎的最佳用量为400～500g／667m^2，药后7d的防效达到89％左右，21d时防效达到100%，具有较好的速效性和持效性。

二嗪磷对鸟类脑组织乙酰胆碱酯酶活性的影响

为了初步研究有机磷农药二嗪磷对鸟类的毒性作用,采用室内饲喂染毒的方法,分析了二嗪磷对鹌鹑、鹧鸪及斑鸠3种鸟脑组织乙酰胆碱酯酶(AChE)活性的影响。鹌鹑、鹧鸪采用经食饲喂,染毒剂量分别为0、40、80、160、320、600mg·kg-1饲料和0、400、800、1600、3200、6000mg·kg-1饲料,试验周期8d;斑鸠采用拌种饲喂(1mL50%二嗪磷乳油拌500g麦种),染毒剂量为0、1.2、2.0、4.0、8.0mg·kg-1体重,一次性染毒后进行常规饲养,试验周期15d。结果表明,二嗪磷对3种鸟脑组织AChE活性均有一定程度的抑制作用:各染毒组死亡鸟AChE活性较对照降低显著(p<0.05,p<0.01),活性抑制率均超过40%;各染毒组存活鸟AChE活性较对照也有所降低,但活性抑制率均未超过20%.以上结果提示,抑制脑组织AChE活性可能是二嗪磷致鸟类死亡的重要原因。