Response of sensitive human ataxia and resistant T-1 cell lines to accelerated heavy ions

We have studied the radiation dose responses of two human fibroblast lines: cells from a patient with Ataxia telangiectasia (AT-2SF) and an established line of human T-1 cells. Aerobic and hypoxic 225 kVp X-ray survival curves were used as controls to the heavy ion exposures. Nearly monoenergetic accelerated neon and argon ions were used at the Berkeley Bevalac with various residual range values. The LET of the particles varied from 30 keV microns-1 to over 1,000 keV microns-1. All Ataxia survival curves were exponential functions of the dose. Their radiosensitivity reached peak values at 100-200 keV microns-1. Human T-1 cells have effective sublethal damage repair as has been evidenced by split dose experiments, and they are much more resistant to low LET than to high LET radiation. At high LET their radiosensitivity approached that of the Ataxia cells. The repair-misrepair model has been used to interpret these results. According to this model, the molecular repair processes culminate either in eurepair or in misrepair. We have obtained mathematical expressions that describe the cross sections and inactivation coefficients for both human cell lines as a function of the LET and the type of particle used. We assume that the lesions induced in T-1 and Ataxia cells are qualitatively similar and that each cell line attempts to repair these lesions. The result in most irradiated Ataxia cells, however, is either lethal misrepair or incomplete repair leading to cell death. T-1 cells have efficient repair mechanisms at low LET, and the repair-misrepair model suggests that at high LET the T-1 cells can still efficiently repair individual lesions, but that as the lesions become closely spaced along the tracks, the probability of misrepair increases.

Colorectal cancer and schistosomiasis

The risk of colorectal cancer is known to be increased in patients with long-standing schistosomal colitis. A retrospective review of clinical data and surgical specimens from 60 patients with schistosomal granulomatous disease of the large intestine but without carcinoma demonstrated that 36 of them had mild to severe grades of colonic epithelial dysplasia. This was either focal or diffuse in distribution and occurred in flat mucosa, in pseudopolyps, or in regenerating epithelium at the edges of ulcers. These dysplastic changes are regarded as the pathological basis for the malignant potential of schistosomal colitis, and they resemble the changes found in long-standing chronic ulcerative colitis.

Survival and kinetic response of V79-spheroids after exposure to heavy ion beams

Multicellular V79-spheroids and V79-monolayer cultures were irradiated with charged particle beams. The beams studied and their initial extraction energies were carbon (400 MeV/amu), neon (425 MeV/amu) and argon (570 MeV/amu). Survival was measured at a position in the plateau, and at a position in the middle of a 4 cm extended Bragg peak. Relative biological efficiency (r.b.e.) values for survival of spheroid cells at peak positions were high (4.1--4.2) in comparison to those obtained with monolayer cultures (1.8--2.4) of the same cell line. This finding is explained by the fact that three dimensional cell contact, which benefits survival after low LET radiation, does not influence survival after heavy ion irradiations in the Bragg peak. The peak-plateau r.b.e.-ratio was most advantageous for the carbon-ion beam (= 4.2). Whereas non-cycling inner spheroid cells showed hardly any kinetic changes up to 24 hours after heavy ion irradiation, outer cycling spheroid cells were arrested in G2 + M within a few hours after exposure.