国家毒理学规划关于饮用水中25种地下水污染物化学混合物对F344/N大鼠和B6C3F(1)小鼠毒性研究的技术报告。

Toxicity report series Pub Date : 1993-08-01
R. Yang
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Water consumption decreased with dose and was 24% to 28% less than that of the controls at the highest concentration. Changes in organ weights occurred primarily in high-dose rats and included increased absolute and relative liver and kidney weights in females, increased relative kidney weight in males, and decreased absolute and relative thymus weights in males and females. Hematologic assessments indicated that rats receiving 378 ppm developed a microcytic anemia consistent with that accompanying iron depletion. Multiple foci of inflammation occurred in the liver of exposed rats. In high-dose females, these liver lesions were especially prominent and included bile duct and oval cell hyperplasia. Inflammation also occurred in the mesenteric lymph nodes, the adrenal gland, and the spleen. The amount of hemosiderin in the spleens of rats receiving the higher concentrations of the chemical mixture was less than normal. 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引用次数: 0

摘要

对25种地下水污染物的化学混合物进行了毒性研究,使用的剂量水平被认为与环境有关。混合物含有19种有机化合物和6种金属(如下图所示);选择这些化合物主要是根据它们在美国环境保护署对危险废物处理场附近地下水污染的调查中出现的频率。本报告主要关注雄性和雌性F344/N大鼠和B6C3F(1)小鼠26周的饮用水毒性研究。评估的终点包括组织病理学、临床病理学、神经行为研究和生殖毒性。本报告简要回顾了使用相同化学混合物的其他研究,包括暴露于化学混合物13周的B6C3F(1)小鼠的精子发生评估,Sprague-Dawley大鼠和CD-1(R)瑞士小鼠的连续繁殖研究,暴露于化学混合物长达31.5周的B6C3F(1)小鼠的骨髓毒性研究,暴露于化学混合物长达13周的B6C3F(1)小鼠的免疫抑制研究。鼠伤寒沙门菌和大肠杆菌的体外诱变性试验,以及F344/N大鼠和B6C3F(1)小鼠在2周的饮用水研究中骨髓和外周血基因损伤的测定。在一项为期26周的饮用水研究中,给大鼠注射复合污染物浓度为0、11、38、113或378 ppm的化学混合物,没有发生死亡,高剂量雄性的体重增加略低于对照组。饮水量随剂量的增加而减少,最高浓度时比对照减少24% ~ 28%。器官重量的变化主要发生在高剂量大鼠身上,包括雌性的绝对和相对肝脏和肾脏重量增加,雄性的相对肾脏重量增加,雄性和雌性的绝对和相对胸腺重量减少。血液学评估表明,接受378 ppm的大鼠出现小细胞性贫血,与伴随的铁耗尽一致。暴露大鼠肝脏出现多灶性炎症。在高剂量女性中,这些肝脏病变特别突出,包括胆管和卵圆细胞增生。炎症也发生在肠系膜淋巴结、肾上腺和脾脏。高剂量大鼠脾脏含铁血黄素含量明显低于正常水平。25种地下水污染物的化学混合物的成分包括丙酮、二氯1260、砷、苯、镉、四氯化碳、氯苯、氯仿、铬、1,1-二氯乙烷、1,2-二氯乙烷、1,1-二氯乙烯、1,2-反式二氯乙烯、邻苯二甲酸二(2-乙基己基)、乙苯、铅、汞、二氯甲烷、镍、苯酚、四氯乙烯、甲苯、1,1,1-三氯乙烷、三氯乙烯、二甲苯。在一项为期26周的研究中,小鼠暴露于饮用水中浓度为0、11、38、113和378 ppm的化学混合物中,在存活、体重增加、临床病理参数或组织病理学评估方面没有明显的不良影响。饮水量随剂量的增加而减少,高剂量小鼠的饮水量比对照组减少约40%。在神经行为评估中,在26周的饮用水研究中,每隔6周对大鼠或小鼠的前肢和后肢握力、后肢足展、运动活动、对热刺激的反应或惊吓反应进行评估,没有观察到明显的治疗相关效果。在26周的研究中,接受化学混合物的大鼠或小鼠的精子形态、活力或发情周期长度没有受到影响。在连续繁殖研究中,F(1) CD-1(R)瑞士小鼠的精子浓度下降,尽管CD-1& regg中对Sprague-Dawley大鼠或CD-1(R)瑞士小鼠的生育能力没有明显的不利影响;这些研究中的瑞士老鼠。连续饲养试验中,给药大鼠幼仔体重、活仔数、每窝雄仔数均有轻微下降;在378 ppm组中,F(0)代和F(1)代出生的窝中存活的雌性小鼠幼崽数量减少。这些观察的意义,如果有的话,是未知的。与对照组相比,接受378 ppm的F(1)小鼠的肝脏炎症发生率增加。在雌性B6C3F(1)小鼠中,在饮用水中接受浓度高达756 ppm的化学混合物2周或378 ppm的13周,免疫功能评估显示造血干细胞和抗原诱导的抗体形成细胞受到抑制。这表现在对非致死性小鼠疟疾毒株约氏疟原虫攻击的抵抗力受损。 在31.5周的研究中,接受浓度为378或756 ppm的化学混合物的雌性小鼠分离出的粒细胞-巨噬细胞祖细胞和红细胞前体细胞体外集落形成能力下降,证明了对造血干细胞不利影响的其他证据。该化学混合物对F344/N大鼠和B6C3F(1)小鼠骨髓的潜在遗传毒性作用在浓度高达756 ppm的2周饮用水研究中进行了评估。雄性小鼠骨髓中姐妹染色单体交换和微核多染红细胞少量增加,雌性小鼠骨髓中微核多染红细胞也增加。该混合物在鼠伤寒沙门菌TA98和TA100中均未引起突变,在有无代谢激活的大肠杆菌中均未引起DNA损伤。综上所述,大鼠饮用含有25种常见地下水污染物混合物的水,其潜在的环境相关性水平在肝脏、脾脏、淋巴结和肾上腺中发生炎症损害,并有缺铁性贫血的证据。炎性病变不能根据已知的化学混合物的个别成分的毒性作用来预测。在标准的毒性研究中,小鼠暴露于相似浓度的化学混合物中没有表现出不良反应,但在其他研究中,通常包括暴露于更高浓度或更长时间的暴露,小鼠出现了骨髓功能缺陷、遗传损伤、肝脏炎症和免疫抑制的证据。在大鼠中,组织学损伤(肝脏肉芽肿性炎症)的未观察到不良反应水平为11ppm;然而,在一项为期26周的标准研究中,在暴露于浓度高达378 PPM的化学混合物的小鼠中,没有发现组织学损伤的明确证据。注:这些研究部分由综合环境反应、赔偿和责任法案信托基金(超级基金)提供资金支持,并与美国公共卫生服务局有毒物质和疾病登记处达成机构间协议。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
NTP technical report on the toxicity studies of a Chemical Mixture of 25 Groundwater Contaminants Administered in Drinking Water to F344/N Rats and B6C3F(1) Mice.

Toxicity studies were performed with a chemically defined mixture of 25 groundwater contaminants, using dose levels considered to have environmental relevance. The mixture contained 19 organic compounds and six metals (shown below); the selection of these compounds was based primarily on the frequency of their occurrence in United States Environmental Protection Agency surveys of groundwater contamination in the vicinity of hazardous waste disposal sites. This report focuses primarily on 26-week drinking water toxicity studies with male and female F344/N rats and B6C3F(1) mice. The endpoints evaluated included histopathology, clinical pathology, neurobehavioral studies, and reproductive toxicity. Additional studies using this same chemical mixture are briefly reviewed in this report and include an evaluation of spermatogenesis in B6C3F(1) mice exposed to the chemical mixture for 13 weeks, a continuous breeding study with Sprague-Dawley rats and CD-1(R) Swiss mice, studies of myelotoxicity in B6C3F(1) mice exposed to the chemical mixture for up to 31.5 weeks, studies of immunosuppression in B6C3F(1) mice exposed for up to 13 weeks, in vitro mutagenicity assays in Salmonella typhimurium and Escherichia coli, and measures of genetic damage in bone marrow and peripheral blood of F344/N rats and B6C3F(1) mice in 2-week drinking water studies. In a 26-week drinking water study in which rats were administered the chemical mixture at composite contaminant concentrations of 0, 11, 38, 113, or 378 ppm, no deaths occurred and the body weight gain of high-dose males was slightly less than that of the controls. Water consumption decreased with dose and was 24% to 28% less than that of the controls at the highest concentration. Changes in organ weights occurred primarily in high-dose rats and included increased absolute and relative liver and kidney weights in females, increased relative kidney weight in males, and decreased absolute and relative thymus weights in males and females. Hematologic assessments indicated that rats receiving 378 ppm developed a microcytic anemia consistent with that accompanying iron depletion. Multiple foci of inflammation occurred in the liver of exposed rats. In high-dose females, these liver lesions were especially prominent and included bile duct and oval cell hyperplasia. Inflammation also occurred in the mesenteric lymph nodes, the adrenal gland, and the spleen. The amount of hemosiderin in the spleens of rats receiving the higher concentrations of the chemical mixture was less than normal. Components of a chemical mixture of 25 groundwater contaminants include acetone, aroclor 1260, arsenic, benzene, cadmium, carbon tetrachloride, chlorobenzene, chloroform, chromium, 1,1-dichloroethane, 1,2-dichloroethane, 1,1-dichloroethylene, 1,2-trans-dichloroethylene, di(2-ethylhexyl) phthalate, ethylbenzene, lead, mercury, methylene chloride, nickel, phenol, tetrachloroethylene, toluene, 1,1,1-trichloroethane, trichloroethylene, xylenes. In a 26-week study in which mice were exposed to the chemical mixture at concentrations of 0, 11, 38, 113, and 378 ppm in drinking water, there were no clear adverse effects noted in survival, weight gain, clinical pathology parameters, or histopathologic evaluations. Water consumption decreased with increasing dose, and water consumption by high-dose mice was approximately 40% less than that by the controls. In neurobehavioral assessments, no clear treatment-related effects were observed in measures of forelimb and hindlimb grip strength, hindlimb footsplay, motor activity, response to a thermal stimulus, or startle response in rats or mice evaluated at 6-week intervals throughout the 26- week drinking water studies. There were no effects on sperm morphology or motility or on estrous cycle length in rats or mice receiving the chemical mixture during the 26-week studies. Sperm concentration was decreased in F(1) CD-1(R) Swiss mice during continuous breeding studies, although there were no clear adverse effects on the fertility of Sprague-Dawley rats or CD-1(R) Swiss mice in th CD-1® Swiss mice in these studies. Pup weight, the number of live males, and the number of male pups per litter were slightly decreased in dosed rats in the continuous breeding study in rats; the number of live female mouse pups in litters born of the F(0) and F(1) generations was decreased in the 378 ppm group. The significance of these observations, if any, is not known. F(1) mice receiving 378 ppm had increased incidences of hepatic inflammation compared to the controls. In female B6C3F(1) mice that received the chemical mixture in drinking water at concentrations as high as 756 ppm for 2 weeks or 378 ppm for 13 weeks, assessments of immune function showed suppression of hematopoietic stem cells and antigen-induced antibody-forming cells. This was manifested by impaired resistance to challenge with a nonlethal strain of mouse malaria, Plasmodium yoelii. Additional evidence of an adverse effect on hematopoietic stem cells was demonstrated by decreases in the in vitro colony-forming ability of granulocyte-macrophage progenitor cells and erythroid precursor cells isolated from female mice that had received the chemical mixture at a concentration of 378 or 756 ppm in 31.5 week studies. Potential genotoxic effects of the chemical mixture to the bone marrow of F344/N rats and B6C3F(1) mice were assessed in 2-week drinking water studies with concentrations as high as 756 ppm. Small increases in sister chromatid exchanges and micronucleated polychromatic erythrocytes occurred in the bone marrow of dosed male mice, and micronucleated polychromatic erythrocytes were also increased in dosed female mice. The chemical mixture did not induce mutations in Salmonella typhimurium strains TA98 and TA100 and did not induce DNA damage in Escherichia coli with or without metabolic activation. In summary, rats receiving drinking water containing a mixture of 25 common groundwater contaminants at levels of potential environmental relevance developed inflammatory lesions in the liver, spleen, lymph nodes, and adrenal gland, as well as evidence of an iron deficiency anemia. The inflammatory lesions could not be predicted based on the known toxic effects of the individual components of the chemical mixture. Mice exposed to similar concentrations of the chemical mixture did not show adverse effects in a standard toxicity study but developed deficits in bone marrow function, evidence of genetic damage, hepatic inflammation, and immunosuppression in other studies that generally included exposures to higher concentrations or exposures of longer duration. A no-observed-adverse-effect level for histologic injury (granulomatous inflammation of the liver) was 11 ppm in rats; however, no clear evidence for histologic injury was seen in mice exposed to concentrations of the chemical mixture as high as 378 ppm in a standard 26-week study. NOTE: These studies were supported in part by funds from the Comprehensive Environmental Response, Compensation, and Liability Act trust fund (Superfund) by an interagency agreement with the Agency for Toxic Substances and Disease Registry, U.S. Public Health Service.

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