Armin Gamer

Development of a Short-Term Inhalation Test in the Rat Using Nano-Titanium Dioxide as a Model Substance

Evidence suggests that short-term inhalation studies may provide comparable prediction of respiratory tract toxicity to 90-day studies, presenting the opportunity to save time and resources in screening inhalation toxicity of test substances. The aim of this study was to develop a short-term inhalation test that could be employed to provide early evidence on respiratory tract effects which might occur from long-term exposure to aerosols of nano-materials. Male Wistar rats were exposed to aerosols of 0 (control), 2, 10 and 50 mg/m3 nano-titanium dioxide (TiO2) by inhalation for 6 h/day for 5 days. Necropsies were performed either immediately after the last exposure or after 3 and 16 days post exposure (study days 5, 8 and 21, respectively). Treatment with nano-TiO2 resulted in morphological changes in the lung, with 50 mg/m3 nano-TiO2 producing an increase in lung weight. Lung inflammation was associated with dose-dependent increases in bronchoalveolar lavage fluid (BALF) total cell and neutrophil counts, total protein content, enzyme activities and levels of a number of cell mediators. No indications of systemic effects could be found by measurement of appropriate clinical pathology parameters. Cell replication (determined by incorporation of 5-bromo-2′-deoxyuridine) was increased at all nano-TiO2 dose levels in large/medium bronchi and terminal bronchioles. The effects on the parameters measured were most prominent either on study day 5 or 8, with some endpoints returning to control levels by day 21. Overall, the pulmonary effects of nano-TiO2 observed in this short-term study were comparable to those previously reported in subchronic inhalation studies.

Generation and Characterization of Test Atmospheres with Nanomaterials

To ensure the product safety of nanomaterials, BASF has initiated an extensive program to study the potential inhalation toxicity of nanosize particles. As preparation work for upcoming inhalation studies, the following manufactured nanomaterials have been evaluated for their behavior in an exposure system designed for inhalation toxicity studies: titanium dioxide, carbon black, Aerosil R104, Aerosil R106, aluminum oxide, copper(II) oxide, amorphous silicon dioxide, zinc oxide, and zirconium(IV) oxide. As the physicochemical properties and the complex nature of ultrafine aerosols may substantially influence the toxic potential, the particle size, specific surface area, zeta potential, and morphology of each of the materials were determined. Aerosols of each material were generated using a dry powder aerosol generator and by nebulization of particle suspensions. The mass concentration of the particles in the inhalation atmosphere was determined gravimetrically and the particle size was determined using a cascade impactor, an optical particle counter, and a scanning mobility particle sizer. The dispersion techniques used generated fine aerosols with particle size distributions in the respiratory range. However, as a result of the significant agglomeration of nanoparticles in the test materials evaluated, no more than a few mass percent of the materials were present as single nanoparticles (i.e., < 100 nm). Considering the number, a greater percentage of nanoparticles was present. Based on the obtained results and experience with the equipment, a technical setup for inhalation studies with nanomaterials is proposed. Furthermore, a stepwise testing approach is recommended that also could reduce the number of animals used in testing.

Experience with local lymph node assay performance standards using standard radioactivity and nonradioactive cell count measurements

The local lymph node assay (LLNA) is the preferred test for identification of skin‐sensitizing substances by measuring radioactive thymidine incorporation into the lymph node. To facilitate acceptance of nonradioactive variants, validation authorities have published harmonized minimum performance standards (PS) that the alternative endpoint assay must meet. In the present work, these standards were applied to a variant of the LLNA based on lymph node cell counts (LNCC) run in parallel as a control with the standard LLNA with radioactivity measurements, with threshold concentrations (EC3) being determined for the sensitizers. Of the 22 PS chemicals tested in this study, 21 yielded the same results from standard radioactivity and cell count measurements; only 2‐mercaptobenzothiazole was positive by LLNA but negative by LNCC. Of the 16 PS positives, 15 were positive by LLNA and 14 by LNCC; methylmethacrylate was not identified as sensitizer by either of the measurements. Two of the six PS negatives tested negative in our study by both LLNA and LNCC. Of the four PS negatives which were positive in our study, chlorobenzene and methyl salicylate were tested at higher concentrations than the published PS, whereas the corresponding concentrations resulted in consistent negative results. Methylmethacrylate and nickel chloride tested positive within the concentration range used for the published PS. The results indicate cell counts and radioactive measurements are in good accordance within the same LLNA using the 22 PS test substances. Comparisons with the published PS results may, however, require balanced analysis rather than a simple checklist approach. Copyright

Interlaboratory Validation of 1% Pluronic L92 Surfactant as a Suitable, Aqueous Vehicle for Testing Pesticide Formulations Using the Murine Local Lymph Node Assay

The mouse local lymph node assay (LLNA) has become the preferred test for evaluating the dermal sensitization potential of chemicals and requirements are now emerging for its use in the evaluation of their formulated products, especially in the European Union. However, despite its widespread use and extensive validation, the use of this assay for directly testing mixtures and formulated products has been questioned, which could lead to repeat testing using multiple animal models. As pesticide formulations are typically a specific complex blend of chemicals for use as aqueous-based dilutions, traditional vehicles prescribed for the LLNA may change the properties of these formulations leading to inaccurate test results and hazard identification. The objective of this study was to evaluate the effectiveness of an aqueous solution of Pluronic L92 block copolymer surfactant (L92) as a vehicle in the mouse LLNA across five laboratories. Three chemicals with known sensitization potential and four pesticide formulations for which the sensitization potential in guinea pigs and/or humans had previously been assessed were used. Identical LLNA protocols and test materials were used in the evaluation. Assessment of the positive control chemicals, hexylcinnamaldehyde, formaldehyde, and potassium dichromate revealed positive results when using 1% aqueous L92 as the vehicle. Furthermore, results for these chemicals were reproducible among the five laboratories and demonstrated consistent relative potency determinations. The four pesticide formulations diluted in 1% aqueous L92 also demonstrated reproducible results in the LLNA among the five laboratories. Results for these test materials were also consistent with those generated previously using guinea pigs or from human experience. These data support testing aqueous compatible chemicals or pesticide formulations using the mouse LLNA, and provide additional support for the use of 1% aqueous L92 as a suitable, aqueous-based vehicle.

Effects of 5-Day Styrene Inhalation on Serum LH and Testosterone Levels and on Hypothalamic and Striatal Amino Acid Neurotransmitter Concentrations in Male Rats

The volatile chemical styrene may impair male fertility. Testicular testosterone (T) production is controlled by the hypothalamic/pituitary/gonadal axis. From the mediobasal hypothalamus (MBH), gonadotropin-releasing hormone (GnRH) is released, which stimulates luteinizing hormone (LH) secretion from the pituitary, which in turn enhances T production. GnRH release is controlled by glutamate (GLU) and gamma-aminobutyric acid (GABA). GLU and GABA neurons are regulated by T. Thus, reduced fertility of styrene-exposed male workers may result from altered GLU/GABA neurotransmission, causing insufficient GnRH, LH, and T secretion. Therefore, we compared LH and T levels of male rats that have inhaled styrene (0, 150, 500, 1500 ppm for 6 h on 5 consecutive days) to GLU and GABA concentrations in the MBH and striatum. Animals were killed directly following the last exposure (immediate group) or after 24 h (recovery group). No suppression of LH or T levels was observed after styrene inhalation. LH levels of the immediate groups with 500 or 1500 ppm exposure were slightly but signficantly elevated. Hypothalamic GLU and GABA concentrations remained unchanged. Increased striatal GABA concentrations were determined in recovery groups with 500 or 1500 ppm exposure. Striatal GLU concentrations remained unaffected. Thus, we demonstrate slightly increased LH and T levels in styrene-exposed male rats after inhalation of the two higher doses. This effect did not correlate with hypothalamic GLU and GABA concentrations. With the limitations inherent to any animal model, these data obtained from a 5-day exposure study with rats suggest, but do not unequivocally prove, that styrene may have also no reproductive toxicity effects in men chronically exposed to this chemical.

Developmental toxicity of oral n-butylamine hydrochloride and inhaled n-butylamine in rats

Pregnant Wistar rats were administered 0, 100, 400 or 1000 mg mono-n-butylamine hydrochloride/kg body weight/day by gavage on days 6 through 15 post coitum (sperm-positive=day 0), or inhaled mono-n-butylamine 0, 17, 50 or 152 ppm (whole-body exposure), 6 h/day on days 6 through 19 post coitum. Oral n-butylamine HCl 1000 mg/kg reduced maternal feed consumption, increased early post-implantation losses (embryonic resorptions), reduced fetal and placental weight, and retarded skeletal development (incomplete skull and sternebral ossification), and produced malformations (filiform/kinked tail, enlarged cardiac ventricular chamber(s), malpositioned heart, aortic arch atresia, diaphragmatic hernia); 100 mg/kg was the no-observed-adverse effect level (NOAEL) for prenatal developmental toxicity; 400 mg/kg, the maternal no-effect level, produced only malformations (aortic arch atresia, malpositioned heart, diaphragmatic hernia). Inhaled n-butylamine produced concentration-dependent nasal epithelial hyperplasia and squamous metaplasia, inflammation and necrosis; the maternal NOAEL was less than 17 ppm. There were no treatment-related signs of embryo/fetotoxicity, particularly, no effects on fetal morphology. The developmental NOAEL was 152 ppm. The neutralization of n-butylamine by hydrochloride converts it from a strong alkali causing tissue burns into a weak acid/base which is fetotoxic. Possible mechanisms of fetotoxicity are free radical production, metabolic acidosis, and lysosomotrophy.

Further experience with the local lymph node assay using standard radioactive and nonradioactive cell count measurements

In a previous study, the predictive capacity of a modified local lymph node assay (LLNA) based on cell counts, the LNCC, was demonstrated to be closely similar to that of the original assay. In addition, a range of substances, including some technical/commercial materials and a range of agrochemical formulations (n = 180) have also been assessed in both methods in parallel. The results in the LNCC and LLNA were generally consistent, with 86% yielding an identical classification outcome. Discordant results were associated with borderline data and were evenly distributed between the two methods. Potency information derived from each method also demonstrated good consistency (n = 101), with 93% of predictions being close. Skin irritation was observed only infrequently and was most commonly associated with positive results; it was not associated with the discordant results. Where different vehicles were used with the same test material, the effect on sensitizing activity was modest, consistent with historical data. Analysis of positive control data indicated that the LNCC and LLNA displayed similar levels of biological variation. When taken in combination with the previously published results on LLNA Performance Standard chemicals, it is concluded that the LNCC provides a viable non‐radioactive alternative to the LLNA for the assessment of substances, including potency predictions, as well as for the evaluation of preparations. Copyright