Natl Toxicol Program Tech Rep Ser. 1988 Jan;333:1-168.
N-Phenyl- 2- naphthylamine, formerly used as a antioxidant in the rubber industry, was selected for toxicology and carcinogenesis studies because at the time of nomination (1976) it had a large annual production and widespread human exposure. Additional reasons for selection included it structural similarity and possible metabolism to the known human urinary bladder carcinogen, 2-naphthylamine. Toxicology and carcinogenesis studies were conducted by feeding diets containing N-phenyl-2-naphthylamine (approximately 98% pure and containing less than 1 ppm 2-naphthylamine) at various concentrations to groups of F344/N rats and B6C3F1 mice of each sex for 14 days, 13 weeks, or 2 years. Fourteen-Day and Thirteen-Week Studies: In 14-day studies, 3/5 male and 4/5 female rats that received 50,000 ppm N-phenyl-2-naphthylamine died before the end of the studies. Final mean body weights of rats that received 12,500 ppm or more were considerably lower (18%-57%) than those of the controls. Arched backs, rough coats, and diarrhea were observed for males that received 12,500 ppm or more and for females that received 25,000 or 50,000 ppm. All mice were alive at the end of the studies, and no compound-related clinical signs of toxicity were observed in mice given feed containing up to 20,000 ppm. In 13-week studies, deaths occurred in 4/10 male and 9/10 female rats that received the highest dose (40,000 ppm) of N-phenyl-2-naphthylamine. Final mean body weights of rats that received 5,000-40,000 ppm were 9%-60% lower than those of the controls. The liver weight to body weight ratios increased with increasing dose, with the ratios for male rats at 10,000 ppm or more and for female rats at 5,000 ppm being greater (P<0.05) than those of controls. A compound-related nephropathy occurred in rats and was characterized by renal tubular epithelial degeneration and hyperplasia. Other effects in rats included hematopoietic hypoplasia or atrophy of the femoral bone marrow, testicular hypospermatogenesis, lymphoid degeneration of the thymus, and lymphoid depletion of the spleen. In mice, 2/10 males and 7/10 females that received 40,000 ppm died before the end of the 13-week studies. The final mean body weights of mice that received 10,000, 20,000, or 40,000 ppm were 9%-32% lower than those of the controls. The liver weight to body weight ratios for mice increased with increasing dose. Those for male mice at 10,000 ppm or more and for female mice at 20,000 ppm or more were greater (P<0.05) than those for the controls. Nephropathywas observed at increased incidences and severity in dosed mice. Because of kidney lesions, liver enlargement, lower weight gain, and increased mortality in the shorter term studies, dietary concentrations of N-phenyl-2-naphthylamine selected for the 2-year studies in rats and mice were 0, 2,5000, and 5,000 ppm. Body Weight and Survival in the Two-Year Studies: The mean body weights of dosed rats were lower than those of the controls throughout the studies (12% and 16% lower for dosed males and 15% and 31% lower for dosed females at the end of the studies). The average daily feed consumption for rats was 94%-87% that of the controls for dosed males and 88% that of the controls for dosed females. The estimated average amount of N-phenyl-2-naphthylamine consumed per day was 100 mg/kg and 225 mg/kg for male rats and 120 mg/kg and 260 mg/kg for female rats. The survival of the high dose group of male rats was greater (P<0.05) than that of the controls after week 101 (male: control, 24/50; low dose, 28/50; high dose, 34/50; female: 26/50; 44/50; 38/50). Final mean body weights of high dose male and female mice were lower (male, 9%; female, 23%) than those of the controls. The estimated average daily feed consumption by dosed mice was within 10% that of the controls. The average amount of N-phenyl-2-naphthylamine consumed per day was approximately 500 or 1,000 mg/kg for male mice and 450 or 900 mg/kg for female mice. No significant differences in survival were observed between any groups of mice of either sex (male: control, 33/50; male mice. No significant differences in survival were observed between any groups of mice of either sex (male: control, 33/50; low dose, 36/50; high dose, 28/50; female: 36/50; 30/50; 35/50). Nonneoplastic and Neoplastic Effects in the Two-Year Studies: As in the 13-week studies, the kidney was the principal target for toxic effects of N-phenyl-2-naphthylamine. Mineralization of the kidney, necrosis of the renal papilla, and epithelial hyperplasia and calculi of the kidney pelvis were observed at increased incidences in high dose female rats. Hydronephrosis, atrophy, fibrosis, and chronic focal inflammation of the kidney were observed at increased incidences in high dose female rats. Cysts and acute suppurative inflammation of the kidney were observed at increased incidences in dosed male and high dose female rats. No compound-related renal neoplasms were observed in rats. Nuclear enlargement of renal tubular epithelial cells and nephropathy were observed at increased incidences in high dose female mice. Atypical tubular cell hyperplasia occurred in two high dose female mice. A tubular cell adenoma was found in one high dose female mouse, and a tubular cell adenocarcinoma was found in another high dose female mouse. No renal neoplasms were observed in dosed male mice. Neoplasms of several organs occurred in rats with negative trends and/or at significantly lower incidences in high dose groups. These included thyroid gland C-cell neoplasms in males and females and mammary gland fibroadenomas, pituitary gland adenomas, and mononuclear cell leukemia in females. The lack of carcinogenicity in rats may be related to an inability to metabolize this compound to the known animal and human carcinogen 2-napththylamine. Genetic Toxicity: N-Phenyl-2-naphthylamine was not mutagenic in the Salmonella typhimurium/microsome assay with strains TA97, TA98, TA100, or TA1535 with or without induced hamster or rat liver S9. The chemical did not induce chromosomal aberrations in cultured Chinese hamster ovary (CHO) cells with or without metabolic activation. No increase in sister chromatid exchanges (SCEs) was observed in the absence of metabolic activation; in the presence of rat liver S9, the SCE results were judged to be equivocal. Data Audit: The data, documents, and pathology materials from the 2-year studies of N-phenyl-2-naphthylamine were audited at the NTP Archives. The audit findings show thatthe conduct of the studies is documented adequately and support the data and results given in this Technical Report. Conclusions: Under the conditions of these 2-year feed studies, there was no evidence of carcinogenic activity for male or female F344/N rats fed diets containing 2,500 or 5,000 ppm N-phenyl-2-naphthylamine. Decreased incidences of several neoplasms were observed in dosed rats: thyroid gland C-cell neoplasms in males and females and mononuclear cell leukemia, pituitary gland adenomas, and mammary gland fibroadenomas in females. There was no evidence of carcinogenic activity for male B6C3F1 mice fed diets containing 2,500 or 5,000 ppm N-phenyl-2-naphthylamine. There was equivocal evidence of carcinogenic activity of N-phenyl-2-naphthylamine for female B6C3F1 mice as indicated by the occurrence of two rare kidney neoplasms. Chemical-related nonneoplastic lesions (nephropathy, karyomegaly, and hyperplasia) occurred in the kidney of rats and mice. Synonyms: N-(2-naphthyl)aniline; 2-naphthylphenylamine; b-naphthylphenylamine; 2-phenylaminonaphthalene; phenyl-b-naphthylamine; N-phenyl-b-naphthylamine Trade Names: Aceto PBN; Agerite Powder: Antioxidant 116; Neosone D; Neozon D; Nilox PBNA; Nonox D; PBNA; Stabilizator AR
N-苯基-2-萘胺曾在橡胶工业中用作抗氧化剂,之所以被选来进行毒理学和致癌性研究,是因为在被提名时(1976年)其年产量高且人类接触广泛。选择它的其他原因包括其结构与已知的人类膀胱致癌物2-萘胺相似,且可能发生代谢。毒理学和致癌性研究通过向不同性别的F344/N大鼠和B6C3F1小鼠组投喂含有不同浓度N-苯基-2-萘胺(纯度约98%,2-萘胺含量低于1 ppm)的饲料进行,为期14天、13周或2年。
14天和13周研究:在14天研究中,接受50,000 ppm N-苯基-2-萘胺的3/5雄性大鼠和4/5雌性大鼠在研究结束前死亡。接受12,500 ppm及以上剂量的大鼠最终平均体重比对照组低得多(低18%-57%)。接受12,500 ppm及以上剂量的雄性大鼠以及接受25,000或50,000 ppm的雌性大鼠出现弓背、被毛粗糙和腹泻症状。所有小鼠在研究结束时均存活,给饲含高达20,000 ppm饲料的小鼠未观察到与化合物相关的毒性临床症状。在13周研究中,接受最高剂量(40,000 ppm)N-苯基-2-萘胺的4/10雄性大鼠和9/10雌性大鼠死亡。接受5,000 - 40,000 ppm的大鼠最终平均体重比对照组低9%-60%。大鼠肝脏重量与体重之比随剂量增加而升高,雄性大鼠在10,000 ppm及以上、雌性大鼠在5,000 ppm时该比值高于对照组(P<0.05)。大鼠出现了与化合物相关的肾病,其特征为肾小管上皮变性和增生。大鼠的其他影响包括造血功能减退或股骨骨髓萎缩、睾丸精子发生减少、胸腺淋巴样变性以及脾脏淋巴细胞减少。在小鼠中,接受40,000 ppm的2/10雄性小鼠和7/10雌性小鼠在13周研究结束前死亡。接受10,000、20,000或40,000 ppm的小鼠最终平均体重比对照组低9%-32%。小鼠肝脏重量与体重之比随剂量增加而升高。雄性小鼠在10,000 ppm及以上、雌性小鼠在20,000 ppm及以上时该比值高于对照组(P<0.05)。给药小鼠中肾病的发生率和严重程度增加。由于短期研究中出现肾脏病变、肝脏肿大、体重增加减少和死亡率增加,因此在大鼠和小鼠的2年研究中选择的N-苯基-2-萘胺饲料浓度为0、2,500和5,000 ppm。
2年研究中的体重和存活情况:在整个研究过程中,给药大鼠平均体重低于对照组(研究结束时给药雄性大鼠低12%和16%,给药雌性大鼠低15%和31%)。给药雄性大鼠的平均每日饲料消耗量为对照组的94%-87%,给药雌性大鼠为对照组的88%。雄性大鼠每天摄入N-苯基-2-萘胺的估计平均量为100 mg/kg和225 mg/kg,雌性大鼠为120 mg/kg和260 mg/kg。高剂量雄性大鼠组在第101周后的存活率高于对照组(P<0.05)(雄性:对照组,24/50;低剂量组,28/50;高剂量组,34/50;雌性:26/50;44/50;38/50)。高剂量雄性和雌性小鼠的最终平均体重低于对照组(雄性低9%;雌性低23%)。给药小鼠的估计平均每日饲料消耗量在对照组的10%以内。雄性小鼠每天摄入N-苯基-2-萘胺的平均量约为500或1,000 mg/kg,雌性小鼠为450或900 mg/kg。各性别小鼠组之间的存活率未观察到显著差异(雄性:对照组,33/50;低剂量组,36/50;高剂量组,28/50;雌性:36/50;30/50;35/50)。
2年研究中的非肿瘤性和肿瘤性影响:与13周研究一样,肾脏是N-苯基-2-萘胺毒性作用的主要靶器官。高剂量雌性大鼠肾脏矿化、肾乳头坏死、肾盂上皮增生和结石的发生率增加。高剂量雌性大鼠肾积水、萎缩、纤维化和慢性局灶性炎症的发生率增加。给药雄性大鼠和高剂量雌性大鼠肾脏囊肿和急性化脓性炎症的发生率增加。大鼠未观察到与化合物相关的肾脏肿瘤。高剂量雌性小鼠肾小管上皮细胞核增大和肾病的发生率增加。两只高剂量雌性小鼠出现非典型肾小管细胞增生。一只高剂量雌性小鼠发现肾小管细胞腺瘤,另一只高剂量雌性小鼠发现肾小管细胞腺癌。给药雄性小鼠未观察到肾脏肿瘤。大鼠多个器官的肿瘤出现阴性趋势和/或高剂量组发生率显著降低。这些包括雄性和雌性甲状腺C细胞肿瘤以及雌性乳腺纤维腺瘤
