Radiation research
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Flow cytometry and cell sorting techniques have been used together with repeated measurement in an attempt to define better the radiation survival response of asynchronously dividing Chinese hamster V79-171 cells under aerobic and hypoxic conditions. Although the first two decades of cell inactivation have been examined, particular attention has been given to the low-dose range of a few grays, as used in individual radiation therapy treatments. ⋯ The data are consistent with the hypothesis that the observed substructure simply reflects the presence of subpopulations of sensitive (G1-, G2-phase) and resistant (late S-phase) cells, which are resolved in these measurements. These results may have significance for certain situations in radiation therapy and in biophysical modeling of the radiation response.
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To determine the effect of oncogene expression on gamma radiation sensitivity of hematopoietic compared to fibroblastic cells, we selected clonal sublines of an interleukin-3 (IL-3)-dependent hematopoietic progenitor cell line 32D cl 3 and NIH/3T3 embryo fibroblastic cells following transfection with each oncogene linked to the mycophenolic acid resistance gene. Each mycophenolic acid-resistant subclone demonstrated high levels of specific poly(A)+ mRNA for each oncogene. The parent line 32D cl 3 demonstrated similar radiosensitivity at 116 cGy/min (D0 126, n 1.17) compared to 5 cGy/min (D0 123, n 1.65). ⋯ Expression in NIH/3T3 of transfected oncogenes v-abl, v-fms, v-fos, or H-ras increased radioresistance at low dose rate (D0 208.6, n 1.61; D0 206.6, n 1.51; D0 167.5, n 1.85; and D0 206.8, n 1.08, respectively). Thus expression of each of several oncogenes induces resistance to gamma irradiation at 5 cGy/min in hematopoietic and fibroblast cell lines. These data may help explain the clinical recurrence of oncogene-expressing leukemia and lymphoma cells after marrow stem cell ablative doses of low-dose-rate total-body irradiation.
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A new complex of tetrachloroplatinum(II) and the azoic diazo dye, Fast Black K, Pt(Fast Black)2, was made in an attempt to produce an uncharged molecule which could readily gain access into cells and could bring a high concentration of tetrachloroplatinum into the vicinity of the DNA. Even the lowest concentration of Pt(Fast Black)2 tested in the superhelical pBR322 plasmid DNA assay in vitro completely converted the superhelical DNA to the circular and linear forms by 24 h. When the cytotoxicity of the Pt(Fast Black)2 and Fast Black were tested in exponentially growing EMT6 cells. ⋯ These results indicate that Pt(Fast Black)2 may be suitable for clinical development because it causes both significant direct cytotoxicity and enhancement of radiation killing. The fact that its cytotoxicity is markedly increased at an acidic pH and its radiation enhancing effects are greatest in combination with relatively low single-fraction radiation doses make it especially interesting. The cytotoxicity of Pt(Fast Black)2 may be influenced by the tumor environment, and the radiosensitizing properties appear well suited for use with radiation fraction sizes that are employed in the clinic.
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These experiments were designed to study the kinetics and magnitude of cell repair and repopulation in tissues whose damage results in the tumor bed effect. The right hind thighs of mice were irradiated with single doses or two equal gamma-ray fractions. Interfraction intervals ranging from 30 min to 24 h (to measure the kinetics of repair from sublethal damage) and 6 and 12 weeks (to determine the extent of repopulation) were used. ⋯ Some recovery, 3.2-4.6 Gy above a single radiation dose, occurred when the interval between two fractions was 24 h. With increasing interfraction intervals of 6 and 12 weeks further dose sparing occurred in the amount of 5.0-6.9 and 7.5-8.3 Gy, respectively. The data suggest that repopulation is the major contributor to the radiation dose-sparing recovery of stromal tissue and that some proliferative response may occur as early as 1 day after the first irradiation.