Zinc 5-nitroisophthalate

Administrative data

Key value for chemical safety assessment

Effects on fertility

Description of key information

No toxicity data on fertility impairment with zinc 5-nitroisophthalate is available, thus the reproductive toxicity will be addressed with existing data on the dissociation products zinc and 5-nitroisophthalic acid.

Effect on fertility: via oral route

Endpoint conclusion:

no adverse effect observed

Effect on fertility: via inhalation route

Endpoint conclusion:

no study available

Effect on fertility: via dermal route

Endpoint conclusion:

no study available

Additional information

No toxicity data on fertility impairment with zinc 5-nitroisophthalate is available, thus the reproductive toxicity will be addressed with existing data on the dissociation products zinc and 5-nitroisophthalic acid. The approach for the assessment entity approach and read-across is described in detail in the document attached in IUCLID section 13.

 

 

5-nitroisophthalic acid/m-nitrobenzoic acid

In Combined Repeated Dose Toxicity Study with the Reproduction/ Developmental Toxicity Screening Test, Crl:CD (SD) male and female rats were treated with m-nitrobenzoic acid in the concentration of 0, 20, 100 and 500 mg/kg bw/day orally by gavage.

In F0 generation, when treated with 500 mg/kg/day, three female rats died, Salivation in male and female rat was noted, restrained body weight gain in male rat and decrease in the food consumption on day 8 in male and female rat were observed. Similarly, Decrease in the RBC, Hgb and Hct level in male and female rat, Increase in A/G ratio, Pi, K and Decrease in Blood Urea Nitrogen, total protein, Cl level in male rat and Increase in ALT level in female rat were observed in 500 mg/kg/day. In addition, Increase in Relative brain, liver and kidney weight and Decrease in absolute and relative testes and epididymides weight during test and recovery and absolute thymus weight during test in male rat and Increase in relative liver and spleen weight during test and recovery and absolute spleen and kidney weight in recovery and Decrease in absolute thymus weight during test in female, Squamous hyperplasia, Erosion and Focal inflammatory cell infiltration in the forestomach, Small and soft testes, Small epididymides, Degeneration in seminiferous tubular epithelium of testes, decrease sperm and cell debris in epididymides duct and an increase in the trabecular bone in femur bone in male rat and squamous hyperplasia and erosion in forestomach during test and an increase in trabecular bone in femur bone during test and recovery in female rat treated with 500 mg/kg/day.

Decrease in gestation index, delivery index, number of corpora lutea, number of implantation sites, implantation index and number of pups delivered in F0 female and a decrease in number of pups delivered, number of live pups on day 0 and number of live pups on day 4 were observed in F1 generation treated with 500 mg/kg bw/day female rats. Based on the observations made, the reproductive No Observed Adverse Effect Level (NOAEL) was considered to be 100 mg/kg body/day for F0 and F1 generation when Crl:CD (SD) male and female rats were treated with m-nitrobenzoic acid.

 

Zinc

Animal data

The reproductive toxicity of zinc compounds has been investigated in one and two generation reproductive toxicity studies in which rats or mice were dosed by gavage or via the diet with soluble zinc compounds (i. e., zinc chloride, zinc sulphate) at exposure levels up to 14 mg Zn/kg bw/day (gavage) or 200 mg Zn/kg bw/day (diet) (Khan et al., 2001, 2003, 2007; Samanta et al, 1986). Further information on potential effects of zinc compounds on male or female reproductive organs could be retrieved from subchronic toxicity studies as conducted by Maita et al.(1981) and Edwards and Buckley (1995).

Maita et al. (1981) reported that mice and rats fed with zinc sulphate in dietary concentrations up to 30,000 mg/kg feed did not produce adverse effects on either male or female sex organs after 13 weeks of exposure. This dietary level was equal to ca. 1100 mg or 565 mg Zn/kg bw/day for mice and rats, respectively. Edwards and Buckley (1995) showed that rats exposed to 13 or 60 mg Zn/kg bw/day in the diet over a period of 90 days did not show any detrimental effects on sex organs. In the exposure group of 335 mg Zn/kg bw/day, all males showed hypoplasia in testes and seminiferous tubules in males hypoplastic uterus in females, but these findings are not considered reliable as the animals of this high dose group were generally of poor health conditions and killed for humane reasons prior to study termination.

In addition to those key reproductive toxicity studies(Khan et al.,2001, 2003, 2007; Samanta et al, 1986), some additional studies indicating high oral doses of zinc (i.e., exposures greater that 25 mg day/kg bw/day) to impair fertility as indicated by a decreased number of implantations sites and increased number of resorptions are of note:

A study was carried out to determine the effect of zinc supplementation on the number of implantation sites and resorptions in pregnant rats. The control group consisting of 12 pregnant females was maintained on 10 % vegetable protein diet (containing 30 ppm zinc) from Day 1 through Day 18 of pregnancy. The experimental group consisting of 13 animals was also maintained on the same diet, but received additionally 150 ppm zinc as a 2% zinc sulphate solution administered daily orally. All the animals were sacrificed on Day 18 of pregnancy, and their uteri examined for implantation sites and resorptions. Of a total number of 101 implantation sites in the 12 control animals there were two resorptions, one in each of two animals. In marked contrast, in the 13 zinc supplemented animals, there were 11 resorptions out of 116 implantations. Eight of the animals had at least one resorption each. This difference was statistically significant. The result indicates that oral administration of moderately high levels of zinc (150 ppm) may be associated with harmful effects in the course of pregnancy of rat (Kumar et al., 1976). The low protein diet may have affected the physiology of the animals resulting in an increased sensitivity for zinc. As this hypothesis cannot be further assessed and also considering the limited available study information, this study is only of limited validity for the assessment of effects of zinc exposure on fertility (EU RAR, 2004).

Another study aimed at determining the effect of post-coitum, and pre- and post-coitum dietary zinc supplementation on the conception in the Charles-Foster rat. In the post-coitum study (test 1), two groups of 15 pregnant rats were fed 0 and 4,000 ppm zinc as zinc sulphate in diet (i.e., approximately 200 mg Zn/kg bw/day) from day 1 through day 18 of pregnancy. In the pre- and post-coitum study (test 2), two groups of 15 female rats were treated with same doses for 21 days pre-mating period, maximum 5 days of mating period and 18 days of post-coitum period. All the females were sacrificed on Day 18 of gestation and uterus content and fetuses were examined. In test 1, significant decrease in the incidences of conception and number of implantation sites per mated female was observed in the treatment group with respect to the control group. However, the difference in implantation sites when considered per pregnant female was not significant. In test 2, no significant difference in incidences of conception and implantation sites was observed in the control and treatment groups. In both the tests, there was no treatment-related change in the fetal and placental weights, stillbirths and malformed fetuses were absent and the number of resorption sites was negligible. Based on these results, dietary zinc supplementation at 4,000 ppm did not affect the fetal growth in pregnant rats. This dose, however, altered the normal conception when started after coitus but showed no effect when initiated sufficient time before coitus (Pal et al., 1987).

The available information suggests that high oral doses of zinc (i. e., exposure levels greater than 20 mg Zn/kg bw/day) may adversely affect spermatogenesis and result in impaired fertility indicated by decreased number of implantation sites and increased number of resorptions (US EPA, 2005). However, these effects were only observed in the presence of maternal toxicity as seen in the one or two generation studies conducted by Khan et al.(2001, 2003, 2007) or, in case of the study conducted by Kumar et al. (1976), when other study non-zinc relevant study specificities could have impacted the study outcome.

 

Human information

In reviews by the World Health Organisation in the Environmental Health Criteria for Zinc (WHO, 2001) and by the US Agency for Toxic Substances and Disease Registry in the Toxicity Profile for Zinc (ATSDR, 2005), existing human studies which examined the responses of women to zinc supplementation during pregnancy have been summarised. Studies on large controlled trials that were conducted to investigate the effects of dietary zinc supplementation in healthy pregnant women were peer reviewed. The reviewers concluded that zinc at a rate of 20mg/day and 30 mg/day did not result in any adverse reproductive effects during pregnancy (Hunt et al.,1984; Kynast and Saling et al.,1986).Two exemplar studies are summarised in the following:

A double blind trial was conducted in 56 pregnant women at risk of delivering a small for gestational-age baby to determine the effects of dietary zinc supplementation during the last 15-25 weeks of pregnancy following administration of 22.5 mg zinc/day. No adverse reproductive effects were observed (Simmer et al.,1991).

Pregnant women who received 0.3 mg zinc/kg bw/day as zinc sulphate capsules during the last two trimesters did not exhibit any changes in maternal body weight gain, blood pressure, postpartum haemorrhage or infection, indicating no adverse reproductive effects (Mahomed et al.,1989).

 

Zinc 5-nitroisophthalate

Since noreproductive toxicity studyis available specifically for zinc 5-nitroisophthalate, information on the individual constituents zinc and 5-nitroisophthalic acid will be used for the hazard assessment of 5-nitroisophthalate. For the purpose of hazard assessment of zinc 5-nitroisophthalate, the point of departure for the most sensitive endpoint of each constituent will be used for the DNEL derivation. In case of 5-nitroisophthalic acid in zinc 5-nitroisophthalate, the NOAEL of 100 mg/kg bw/day in repeated dose toxicity will be used.

Effects on developmental toxicity

Effect on developmental toxicity: via oral route

Endpoint conclusion:

no study available

Effect on developmental toxicity: via inhalation route

Endpoint conclusion:

no study available

Effect on developmental toxicity: via dermal route

Endpoint conclusion:

no study available

Justification for classification or non-classification

Due to an absence of adverse effects seen in the developmental toxicity/fertility screening study with zinc and 3-nitrobenzoic acid, a classification for reproductive toxicity in accordance with regulation (EC) 1272/2008 is not warranted. The effects seen in the study with 3 -nitrobenzoic acid at the maximum dose of 500 mg/kg bw/day has to be regarded as not relevant for hazard assessment purposes, since this dose lead to overt toxicity also leading to mortality of test animals. Consequently, any findings seen at that dose have to be regarded as a consequence of agonal conditions and not relevant for classification and labelling (cf. regulation (EC) 1272/2008, Annex 1, Part 3, Section 3.7.2.4.4).

Additional information