Demonstration of the density dependence of x-ray flux in a laser-driven hohlraum.

Experiments have been conducted using laser-driven cylindrical hohlraums whose walls are machined from Ta2O5 foams of 100 mg/cc and 4 g/cc densities. Measurements of the radiation temperature demonstrate that the lower density walls produce higher radiation temperatures than the high density walls. This is the first experimental demonstration of the prediction that this would occur [M. D. Rosen and J. H. Hammer, Phys. Rev. E 72, 056403 (2005)10.1103/PhysRevE.72.056403]. For high density walls, the radiation front propagates subsonically, and part of the absorbed energy is wasted by the flow kinetic energy. For the lower wall density, the front velocity is supersonic and can devote almost all of the absorbed energy to heating the wall.

Effects of total body irradiation followed by bone marrow transplantation on the disposition kinetics of methotrexate in the rat.

The effects of total body irradiation followed by bone marrow transplantation on the disposition kinetics of intravenously-administered methotrexate have been studied in the Wistar-Furth rat. Eight test animals received total body irradiation (1000 rads) followed by intravenous administration of 3 X 10(8) bone marrow cells per kg body weight. Eight control animals were sham-irradiated and received an equal volume of blank suspension medium. One day after these treatments each rat received methotrexate (25 mg/kg) by rapid intravenous injection and serial blood samples were obtained over a 3 hour period. Serum methotrexate concentrations were measured by high performance liquid chromatography and pharmacokinetic parameters were calculated after NONLIN analysis of data. No significant differences were observed in total body clearances of test and control animals. As methotrexate in the rat is cleared predominantly by renal excretion of unchanged drug, these findings suggest that this process is not affected by radiation. Significantly larger volumes of distribution were observed in test animals. Increased extent of distribution in irradiated animals could be a result of a radiation-induced increase in membrane permeability and/or increased blood flow to irradiated areas. Future studies should assess the clinical significance of such findings.

Effects of total body irradiation followed by bone marrow transplantation on the disposition kinetics of mitomycin-C in the rat.

The effects of total body irradiation followed by bone marrow transplantation on the disposition kinetics of intravenously-administered mitomycin-C have been studied in the Wistar-Furth rat. Five test animals received total body irradiation (1000 rads) followed by intravenous administration of 3 X 10(8) bone marrow cells per kg body weight. Five control animals were sham-irradiated and received an equal volume of blank suspension medium. One day after these treatments, each rat received mitomycin-C (10 mg/kg) by rapid intravenous injection and serial blood samples were obtained. Serum mitomycin-C concentrations were measured by high performance liquid chromatography and pharmcokinetic parameters were calculated after NONLIN analysis of data. Smaller total body clearances in test animals were probably due to radiation-induced inhibition of microsomal enzyme activity. Reduced volumes of distribution were observed in test animals although the reason for this is unclear. Future studies should assess the clinical significance of these results.