Inter- and Intraspecific Variation in Sex Hormone-Induced Sex-Reversal in Medaka, Oryzias latipes and Oryzias sakaizumii.

We compared sex-reversal ratios induced by 17α-methyltestosterone (MT) and 17ß-estradiol (E2) exposure in two inbred medaka strains: Hd-rR derived from Oryzias latipes and HNI-II from O. sakaizumii. All MT exposures (0.2-25 ng mL-1) induced complete XX sex-reversal in HNI-II. Although MT exposure at 0.2 ng mL-1 induced XX sex-reversal at > 95% in Hd-rR, other concentrations tested caused XX sex-reversal at lower frequencies (<50%). MT exposure at 1, 5, and 25 ng mL-1 induced XY sex-reversal in Hd-rR, but not in HNI-II. In Hd-rR, E2 exposure induced XY sex-reversal at > 10 ng mL-1, and in all fish feminization occurred 500 ng mL-1. In HNI-II, E2 induced XY sex-reversal at 50 and 250 ng mL-1, but only at rates below 20%. To clarify whether the strain differences in sex hormone-induced sex-reversal are characteristic of each species, we examined the effects of MT and E2 exposure on sex differentiation in five and two additional strains or wild stocks/populations of O. latipes and O. sakaizumii, respectively. MT exposure induced low XX and high XY sex-reversal rates in O. latipes, except in the Shizuoka population, but the trend was reversed in O. sakaizumii. Furthermore, E2-induced XY sex-reversal rates varied intraspecifically in O. latipes. Our results demonstrated that sensitivity to MT and E2 varied within O. latipes species. To evaluate the ecological impacts of environmental chemicals using medaka, it is important to define not only the species, but the strains, stocks, and populations to obtain accurate results.

Electrodialytic extraction of anionic pharmaceutical compounds from a single drop of whole blood using a supported liquid membrane.

A method to introduce target analytes to a chromatograph from a single drop of whole blood was investigated for minimally invasive monitoring of anionic pharmaceuticals. In this work, salicylate and loxoprofen were examined as organic anions. A micro ion extractor (MIE) has been developed for extraction of inorganic trace anions from whole blood, but this device is not suitable for extraction of pharmaceuticals. In the present study, we improved and optimized the MIE device for organic anion extraction. Various supported liquid membranes were evaluated for use as the ion transfer membrane, with each membrane placed between a droplet sample (donor) and an acceptor solution. A supported liquid membrane of porous polypropylene impregnated with 1-butanol was selected. In addition, the methods for electric field creation and electrode contact were examined to improve the characteristics of the MIE device. The current and extraction time were also optimized. With the optimized method, salicylate and loxoprofen were successfully extracted from a single drop of whole blood. Changes in the concentrations of these pharmaceuticals in blood over time were monitored after administration. As only 25µL of whole blood was required for analysis, repeat measurements could be conducted to monitor changes in the concentrations. This MIE will be useful for monitoring pharmaceutical concentrations in blood.

Micro Ion Extractor for Single Drop Whole Blood Analysis.

A micro ion extractor (MIE) was developed for trace anion determination by ion chromatography-mass spectrometry from a single drop (25 µL) of whole blood without pretreatment. Target analytes were iodide and thiocyanate, which play key roles in thyroid hormone production. Whole blood (25 µL) was pipetted from an earlobe or finger prick and placed in the 16 µL cavity of the device. A reproducible fraction of iodide and thiocyanate was transferred through a membrane to an acceptor solution layer by electromigration for 60 s. An isolator solution layer and a cation exchange membrane is provided between the acceptor and the anode to prevent gas formation or redox processes in the acceptor. The acceptor contents are transferred online to the ion chromatograph. Isolator solution composition and applied voltage were optimized. Recoveries from samples from 16 different volunteers of both sexes and differing ages were the same within ±10% relative standard deviation. Dietary effects on blood iodide and thiocyanate levels are reported. The very low sample requirement permitted multiple sample collections per day. The MIE device is expected to be useful for clinical studies that require several/many temporally spaced blood samples by keeping the invasive nature of blood collection as minimal as possible.