Mechanisms of an increased level of serum iron in gamma-irradiated mice.

The potential mechanisms underlying the increase in serum iron concentration in gamma-irradiated mice were studied. The gamma irradiation dose used was 4 Gy, and cobalt-60 ((60)Co) source was used for the irradiation. The dose rate was 0.25 Gy/min. In the serum of irradiated mice, the concentration of ferrous ions decreased, whereas the serum iron concentration increased. The concentration of ferrous ions in irradiated mice returned to normal at 21 day post-exposure. The concentration of reactive oxygen species in irradiated mice increased immediately following irradiation but returned to normal at 7 day post-exposure. Serum iron concentration in gamma-irradiated mice that were pretreated with reduced glutathione was significant lower (p < 0.01) than that in mice exposed to gamma radiation only. However, the serum iron concentration was still higher than that in normal mice (p < 0.01). This change was biphasic, characterized by a maximal decrease phase occurring immediately after gamma irradiation (relative to the irradiated mice) and a recovery plateau observed during the 7th and 21st day post-irradiation, but serum iron recovery was still less than that in the gamma-irradiated mice (4 Gy). In gamma-irradiated mice, ceruloplasmin activity increased and serum copper concentration decreased immediately after irradiation, and both of them were constant during the 7th and 21st day post-irradiation. It was concluded that ferrous ions in irradiated mice were oxidized to ferric ions by ionizing radiation. Free radicals induced by gamma radiation and ceruloplasmin mutually participated in this oxidation process. The ferroxidase effect of ceruloplasmin was achieved by transfer of electrons from ferrous ions to cupric ions.

Development of serum zinc as a biological dosimeter in mice.

PURPOSE: To develop a new biological dosimeter based on serum zinc concentration. MATERIALS AND METHODS: Male mice (8 weeks old) were exposed to different doses (0, 1.0, 2.0, 4.0, or 8.0 Gy) of gamma rays from a (60)Co source. Blood was then collected from the orbital area of these mice, and the serum zinc concentration was detected using the 2-(5-bromo-2-pyridylazo)-5-diethylaminophenol colorimetric method. The data were analyzed using one-way analysis of variance. RESULTS: The serum zinc concentration in the irradiated mice decreased with increasing dose. Two dose-response relationships fitted to the linear quadratic curve were obtained: One immediately after exposure (y = 0.010x(2) - 0.133x + 0.663, r = 0.983) and the other on the seventh day after exposure (y = 0.008x(2) - 0.127x + 0.695, r = 0.990). The serum zinc concentration continued to decrease until 21 days after exposure. The absorbed doses estimated using both dose-response relationships were close to the actual doses. CONCLUSIONS: Serum zinc is a quick, effective, and sensitive biomarker for early biological doses assessment of mice irradiated by gamma radiation.

Development of serum copper-based biological dosimetry in whole body gamma irradiation of mice.

A new biological dosimeter based on serum copper has been developed. Serum copper in mice subjected to a 60Co source at a dose rate of 0.5 Gy min-1 was detected using the bis(cyclohexanone) oxaldihydrazone colorimetric method. The dose range was from 0.5­7 Gy. The results demonstrate that serum copper decreases with increasing dose. A linear dose response is obtained. The detection limit based on serum copper is the same as that with the lower limit of dose assessment; i.e., about 1 Gy. The decrease in serum copper continues until the 28th day after gamma radiation. The absorbed doses in mice assessed using the linear curve are close to "blind" doses of 4 and 6 Gy. Therefore, serum copper is a quick, simple, and accurate biomarker for early assessment of radiation exposure of mice in the range of 0.5­7 Gy.