Disodium Capryloyl Glutamate

Oocyte maturation is a fundamental step of the reproductive cycle (Moor and Crosby, 1986).  In vitro bovine oocyte maturation tests use the same method that is used for assisted reproduction purposes in animal breeding and closely mimics the in vivo processes of oocyte maturation, giving rise to the formation of viable embryos and offspring (Galli & Lazzari, 2008).  Furthermore, the process of maturation is affected by lower concentrations of chemicals compared to the fertilisation process and reveal toxic effects at much lower concentration of active chemicals as compared to the mitotic process in somatic cells (Lazzari et al. 2008).  The In vitro bovine oocyte test system has several advantages over rodent models, notably the timing of maturation is much shorter for rodents than for human and cow oocytes, the size of the bovine and human oocytes is very similar, while rodent oocytes are significantly smaller, the timing of early cleavage events is also more similar between cow and human, and finally gestation timing is nine months both in human and in cows, while only three weeks in rodents (Vizor and Wells, 2009).  Furthermore, the homologies between humans and cattle at a genomic level are higher than between human and rodents (Pirottin et al., 1999).  Therefore, whilst in vitro tests are not able to replicate the complexities of an in vivo test system they are indicative of reproductive toxicity and have been shown to have good correlation with in vivo results.  Accordingly, a bovine oocytes in vitro maturation test was conducted to evaluate the toxicity of the target and source substances to bovine oocytes.  The study exposes oocytes in vitro to the test substances after which the oocytes are monitored to determine whether they resume meiosis and achieve stage II of metaphase, which corresponds to the stage at which fertilisation and subsequent embryonic development would occur, particularly whether the oocytes undergo nuclear configuration changes during meiosis compared to the untreated controls.  Four substances were assessed:  The target substance, the DSCG source substance, sodium hydrogen N-(1-oxododecyl)-L-glutamate (EC 249-958-3) which differs from the target substance only in the length of the carbon chain (C₁₂), and a reaction mass of L-glutamic acid, N-(1-oxooctyl)-, sodium salt and Sodium hydrogen N-(1-oxotetradecyl)-L-gutamate which contains a C₁₄ chain.  Oocytes were stained and the oocyte nuclear morphology was evaluated by phase contrast microscopic at 200 - 400x magnification.  The concentration of 50 µM is the threshold below which the test detects reproductive toxicity.  For this reason, the test was designed in order to include a final dilution at a concentration lower than the 50 µM threshold.  Under the conditions of the study, no statistically significant variations were observed in the progression to metaphase II.  The study therefore concluded that the substances tested do not induce reproductive toxicity.  Furthermore, the study demonstrates that across a range of related substances with different length carbon chains no reproductive toxicity is observed at the critical oocyte maturation stage.

The available data therefore indicate that the target and source substances used for OECD 414 are not reproductive nor developmental toxicants. 

In a prenatal developmental toxicity study, the test substance was administered to pregnant Wistar rats daily by gavage from implantation to one day Iprior to the expected day of parturition (GD 6-19) to evaluate its potential maternal and prenatal developmental toxicity. Analyses confirmed the correctness of the prepared concentrations and the stability of the test substance in the vehicle.Generally, clinical observations including food consumption and body weight gain revealed no toxicologically relevant difference between the animals receiving 200, 600 or 2000 mg/kg bw/d test material and controls. Nearly all (23 out of 25) females of the high-dose group (2000 mg/kg bw/d) showed transient salivation during the treatment period. Salivation persisted in the respective animals only for some time after daily gavage dosing (maximum up to 2 hours) and was initially observed on GD 6. Transient salivation shortly after dosing most likely reflects a reaction of the animals to the taste and smell of the test substance. It is not considered to be a sign of systemic toxicity and was, therefore, not assessed as treatment-related and adverse. No differences of toxicological relevance between the control and the treated groups (200, 600 or 2000 mg/kg bw/d) were determined for any reproductive parameters, such as conception rate, mean number of corpora lutea, mean number of implantations, as well as pre- and postimplantation loss. Similarly, no influence of the test substance on fetal weight and sex distribution of the fetuses was noted at any dose. Overall, there was no evidence for toxicologically relevant adverse effects of the test substance on fetal morphology at any dose. The test results can be used also for the target substance. Detailed Read Across justification can be found in chapter 13 of Iuclid. At point 7.8.3 bridging studies to confirm the validity of Read-Across are reported.