Frank Kari

Toxicity and carcinogenicity of hydroquinone in F344/N rats and B6C3F1 mice

Toxicology and carcinogenesis studies were conducted by administering hydroquinone (more than 99% pure) by gavage to groups of F344/N rats and B6C3F1 mice of each sex for 14 days, 13 wk or 2 yr. 14-day studies were conducted by administering hydroquinone in corn oil to rats at doses ranging from 63 to 1000 mg/kg body weight and to mice at doses ranging from 31 to 500 mg/kg, 5 days/wk. In the 13-wk studies, doses for rats and mice ranged from 25 to 400 mg/kg. At those doses showing some indication of toxicity in the 14-day and 13-wk studies, the central nervous system, forestomach and liver were identified as target organs in both species and renal toxicity was observed in rats. Based on these results, 2-yr studies were conducted by administering 0, 25 or 50 mg hydroquinone/kg in deionized water by gavage to groups of 65 rats of each sex, 5 days/wk. Groups of 65 mice of each sex were given 0, 50 or 100 mg/kg on the same schedule. 10 rats and 10 mice from each group were killed and evaluated after 15 months. Mean body weights of high-dose male rats and high-dose mice were approx. 5-14% lower than those of controls during the second half of the study. No differences in survival were observed between dosed and control groups of rats or mice. Nearly all male rats and most female rats in all vehicle control and exposed groups had nephropathy, which was judged to be more severe in high-dose male rats. Hyperplasia of the renal pelvic transitional epithelium and renal cortical cysts were increased in male rats. Tubular cell hyperplasia of the kidney was seen in two high-dose male rats, and renal tubular adenomas were seen in 4/55 low-dose and 8/55 high-dose male rats; none was seen in vehicle controls or in female rats. Mononuclear cell leukaemia in female rats occurred with increased incidences in the dosed groups (vehicle control, 9/55; low dose, 15/55; high dose, 22/55). Compound-related lesions observed in the liver of high-dose male mice included anisokaryosis, syncytial alteration and basophilic foci. The incidences of hepatocellular neoplasms, primarily adenomas, were increased in dosed female mice (3/55; 16/55; 13/55). Follicular cell hyperplasia of the thyroid gland was increased in dosed mice.(ABSTRACT TRUNCATED AT 400 WORDS)

The sensitivity of the NTP bioassay for carcinogen hazard evaluation can be modulated by dietary restriction

Studies were undertaken to compare outcomes when four chemicals were evaluated under typical NTP bioassay conditions as well as by protocols employing dietary restriction. Four chemicals, using three different routes of exposure (in utero [accomplished by feeding the dam dosed feed], dosed feed, and gavage) were used to 1) evaluate the effect of diet restriction on the sensitivity of the bioassay toward chemically-induced chronic toxicity and carcinogenicity; and 2) evaluate the effect of weight-matched control groups on the sensitivity of the bioassays. Control and chemical exposed F344 rats and B6C3F1 mice (50-60/group) were fed NIH-07 diet either ad libitum or at restricted levels such that body weights were approximately 80% of ad libitum control weights. The dietary restricted groups were either sacrificed at the end of two or 3-years. Results consistently show that feed restriction decreased the incidence of neoplastic and non-neoplastic lesions at a variety of anatomic sites in both control and chemical exposed animals. Furthermore, the sensitivity of the bioassay to detect chemical carcinogenic response were altered by dietary restriction: three of the four chemicals were found to increase the incidence of neoplastic lesions at four sites when evaluated under standard ad libitum conditions for 104 weeks. When unexposed and exposed groups were both subjected to dietary restriction, none of these 4 sites were detected as a target for carcinogenesis after two or three years. Rather, two different sites of carcinogenesis were detected. When the top dosed ad libitum fed animals were compared against their weight-matched control groups, a total of 10 sites were identified as targets for carcinogenesis. These included all four sites identified under the ad libitum protocol, both sites identified under the feed restricted protocol, and an additional four sites that were not identified under the other two protocols. These studies show that dietary restriction of all animals can be expected of decrease the sensitivity of carcinogenesis bioassays. However, restricting only unexposed groups (weight matching) of control for non-specific weight loss in chemical exposed groups yielded the most sensitivity among our comparisons.

Long-term Exposure to the Anti-inflammatory Agent Phenylbutazone Induces Kidney Tumors in Rats and Liver Tumors in Mice

Long‐term toxicity and carcinogenicity of phenylbutazone, a nonsteroidal anti‐inflammatory drug, were evaluated in F344/N rats and B6C3F1 mice. In 2‐year studies, phenylbutazone was given in corn oil by gavage 5 days per week to groups of 50 rats of each sex at doses of 0, 50, or 100 mg/kg body weight, and to groups of 50 mice at doses of 0, 150, or 300 mg/kg body weight. Body weights and survival were similar among groups. Major target organs are kidneys in rats, and liver in mice. Kidney: inflammation, papillary necrosis, and mineralization in both sexes of rats, and hyperplasia and dilatation of the pelvis epithelium, and cysts in female rats. Uncommon tubular cell tumors of the kidney were found in 13 exposed rats: 5 in the 50 mg group and 4 in the 100 mg group of males; 4 in dosed female rats; none in controls. In female rats, dose‐related increases in hyperplasia of the pelvis transitional epithelium, and 2 carcinomas were discovered. Urinary bladder: papillomas of the transitional epithelium were seen in 2 low‐dose male and in 1 low‐dose female rats. Forestomach: ulcers in rats, with acanthosis, hyperkeratosis, and basal cell hyperplasia in female rats; however, no neoplasms were associated with these lesions. Liver: primarily in male mice exposed to. phenylbutazone, hemorrhage, centrilobular cytomegaly and karyomegaly, fatty metamorphosis, cellular degeneration, and coagulative necrosis were seen; clear cell foci were observed in male mice. In summary, under the conditions of these 2‐year oral intubation studies, phenylbutazone is associated with renal carcinogenicity in rats, as evidenced by increases in tubular cell neoplasms in both sexes. Evidence of carcinogenicity for male mice was shown by increased incidences and multiplicity of liver tumors. No carcinogenic activity was found for female mice.

Toxicity and carcinogenicity of nitrofurazone in F344/N rats and B6C3F1 mice

Toxicology and carcinogenesis studies were conducted by feeding diets containing nitrofurazone (99% pure) to groups of F344/N rats and B6C3F1 mice for 14 days, 13 wk or 2 yr. In the 14-day studies, in which doses ranged from 630 to 10,000 ppm, nitrofurazone was more toxic to mice than to rats. Accordingly, in the 13-wk studies, doses for rats ranged from 150 to 2500 ppm and for mice from 70 to 1250 ppm. At the higher doses, convulsive seizures and gonadal hypoplasia were observed in both species. Evidence of toxicity in rats also included degenerative arthropathy. For the 2-yr studies, rats were exposed to 0, 310 or 620 ppm nitrofurazone and the survival of male rats given 620 ppm was lower than that of controls (33/50, 30/50 and 20/50 in the control, 310- and 620-ppm groups, respectively). Nitrofurazone administration increased the incidences of mammary gland fibroadenomas in female rats (8/49, 36/50 and 36/50 in the control, 310- and 620-ppm groups, respectively). In male rats it was associated with a marginal increase in sebaceous gland adenomas and trichoepitheliomas of the skin, mesotheliomas of the tunica vaginalis, and tumours of the perputial gland. Nitrofurazone caused testicular degeneration (atrophy of germinal epithelium and aspermatogenesis) in rats, and degeneration of vertebral and knee articular cartilage in rats of both sexes. In mice, dietary concentrations of nitrofurazone for the 2-yr studies were 0, 150 or 310 ppm. In mice of each sex, nitrofurazone administration induced stimulus-sensitive convulsive seizures, primarily during the first year of study. In male mice, there was no evidence of any chemically-related carcinogenic effects, but there was a treatment-related decrease in survival (39/50, 31/50 and 27/50 in the control, 150- and 310-ppm groups, respectively). In female mice nitrofurazone induced ovarian lesions with increased incidences of benign mixed tumours (0/47, 17/50 and 20/50 in control, low- and high-dose groups, respectively) and granulosa cell tumours (1/47, 4/50 and 9/50 in control, low- and high-dose groups, respectively).

Mechanistic studies on genotoxicity and carcinogenicity of salicylazosulfapyridine an anti-inflammatory medicine

Salicylazosulfapyridine (SASP), which has been in clinical use for over 50 years, was reported by the National Toxicology Program to increase rat (F344 strain) urinary bladder and mouse (B6C3F1 hybrid) liver tumours under ad libitum (AL) feeding conditions, while under a feed restriction (FR) regimen, these tumours were not increased. The present investigations were undertaken to assess the implications of these results for the safety of SASP in humans. SASP and its 2 major metabolites, 5-aminosalicylic acid (ASA) and sulfapyridine (SP) were tested for in vivo induction of micronuclei in mouse bone marrow cells with or without prefolic treatment and for in vivo formation of DNA adducts in rat and mouse liver and urinary bladder. None exhibited mutagenicity or DNA reactivity. SASP and SP have induced sister chromatid exchanges and micronuclei (MN) in cultured human lymphocytes in the absence of liver activation enzymes and in B6C3F1 mice (but not in rats) MN in bone marrow and peripheral RBC. Treatment with folate reduces the frequency of MN. Perhaps the short (28 days) RBC lifespan in mouse underlies the sensitivity of this species. Thus, SASP without folate supplementation is an aneuploidogen. In a 2-year study in AL fed SASP-treated (high dose 337.5 mg/kg) rats, urinary pH was increased and urinary specific gravity was reduced at 60 weeks. At the end, this SASP group showed urothelial hyperplasia and papillomas in the urinary bladders of male rats primarily. In the FR high dose SASP group, the hyperplasia was reduced from 82% to 14%. At the end of 2 years, the incidence of multi-organ leukemia was reduced in both AL and FR high dose SASP groups. Thus, SASP caused intraluminal bladder changes in the rat (especially males) consisting of chronic urothelial stimulation, concretions, hyperplasia which resulted in neoplasia. In the mouse, because of species differences in liver ratios (mouse > rat) and, increasing (3 times higher) liver perfusion in the mouse, compared to the rat, there was hepatocellular toxicity and resulting preneoplasia and neoplasia within 2 years. These findings occurred in all AL SASP groups (flat curve without dose response); but were reduced under FR conditions. In this species, the multiorgan lymphoma incidence was reduced in both AL and FR high dose SASP groups. Thus, SASP and its major metabolites are not genotoxic. Folate deficiency associated with SASP administration is probably responsible for aneuploidy in lymphocytes and erythrocytes. SASP does not induce neoplasia directly in either livers, urinary bladders or other organs. Accordingly, SASP is judged to pose no carcinogenic risk to humans.