Determination of potential dermal exposure rates of phosphorus flame retardants via the direct contact with a car seat using artificial skin.

Dermal exposure to phosphorus flame retardants (PFRs) has received much attention as a major alternative exposure route in recent years. However, the information regarding dermal exposure via direct contact with a product is limited. In addition, in the commonly used dermal permeability test, the target substance is dissolved in a solvent, which is unrealistic. In this study, a dermal permeability test of PFRs in three car seats was performed using artificial skin. The PFR concentrations in the car seats are 0.12 wt% tris(2-chloroethyl) phosphate (TCEP), 0.030-0.25 wt% tris(2-chloroisopropyl) phosphate (TCPP), 0.15 wt% triphenyl phosphate (TPhP), 0.89 wt% cresyl diphenyl phosphate (CsDPhP), 0.074 wt% tricresyl phosphate (TCsP), and 0.46-4.7 wt% diethylene glycol bis [di (2-chloroisopropyl) phosphate (DEG-BDCIPP). The mean skin permeation rates for a contact time of 24 h are 14 (TCEP), 5.4-160 (TCPP), 0.67 (CsDPhP), 0.38 (TPhP), and 3.3-58 ng cm-2 h-1 (DEG-BDCIPP). The concentrations of TCsP in receptor liquid were lower than the limit of quantification at the contact time of 24 h. The skin permeation rates were significantly affected by the type of car seat (e.g., fabric or non-fabric). The potential dermal TCPP exposure rate for an adult via direct contact with the car seat during the average daily contact time (1.3 h), which was the highest value assessed in this study, was estimated to be 16,000 ng kg-1 day-1, which is higher than that related to inhalation and dust ingestion reported as significant exposure route of PFRs in previous studies. These facts reveal that dermal exposure associated with direct contact with the product might be an important exposure pathway for PFRs.

Effects of supplemental ß-carotene on colostral immunoglobulin and plasma ß-carotene and immunoglobulin in Japanese Black cows.

Data from 26 Japanese Black cows were collected to clarify the effects of supplemental ß-carotene on colostral immunoglobulin (Ig) and plasma ß-carotene and Ig in the cows. Cows were assigned to control or ß-carotene groups from 21 days before the expected calving date to 60 days after parturition. Supplemental ß-carotene was provided at 500 mg/day in the ß-carotene group. Supplemental ß-carotene drastically increased plasma ß-carotene concentrations in the cows from parturition to 60 days after parturition, and plasma ß-carotene concentrations in the control and ß-carotene groups at parturition were 202 and 452 µg/dl, respectively. Supplemental ß-carotene had no effects on plasma IgG1 , IgA or IgM concentrations at parturition. Supplemental ß-carotene increased colostral IgG1 concentrations in the cows, but colostral ß-carotene, IgA and IgM concentrations were not affected by supplemental ß-carotene. These results indicate that supplemental ß-carotene is effective to enhance colostral IgG1 concentrations and plasma ß-carotene concentrations in Japanese Black cows.