The dependence of p53 on the radiation enhancement of thermosensitivity at different let.

PURPOSE: The aim of this study is to investigate the dependence of p53-gene status on the radiation enhancement of thermosensitivity at different levels of linear energy transfer (LET). METHODS AND MATERIALS: We used two kinds of human glioblastoma transfectants of A-172 cells bearing the wild-type p53 gene, A-172/neo cells with control vector containing the neo gene and A-172/mp53 cells with both the dominant negative mutated p53 gene and neo gene. We exposed these cells to X-rays and accelerated carbon-ion (C-) beams (13-200 KeV/microm) followed by heating at 44 degrees C. Cellular sensitivities were determined using clonogenic assay. RESULTS: The radiation enhancement of thermosensitivity was LET-dependent for the A-172/neo cells, but this was not clearly demonstrated in the A-172/mp53 cells. The supraadditive radiation enhancement of thermosensitivity was observed in A-172/neo cells at the LET range of 13 to 70 KeV/microm, though only an additive effect was observed at higher LET. In A-172/mp53 cells, only an additive effect was observed through all the LET examined. CONCLUSION: These results indicate that the radiation enhancement of thermosensitivity is p53- and LET-dependent. Our results suggest that the combined use of high-LET radiation and hyperthermia brings useful application for cancer therapeutic purposes.

Hyperthermic enhancement of tumour growth inhibition by accelerated carbon-ions in transplantable human esophageal cancer.

The study examined the effects of combination of hyperthermia (42 degrees C) and 290 MeV/u carbon-ion (C-) beams or 200 kVp X-rays on tumour regrowth delay of transplantable human esophageal cancer as an in vivo model for radiotherapy of cancer. The C-beams were more effective in the tumour growth inhibition than X-rays. The relative biological effectiveness (RBE) of C-beams against X-rays was 2.00. It was observed that the interactive hyperthermic (42 degrees C, for 30 min) enhancement of tumour regrowth delay by high-linear energy transfer (LET) C-beams was similar to that of combination of low-LET X-rays with hyperthermia. The thermal enhancement ratios (TER) were 6.10 and 5.57 for X-rays and C-beams, respectively. These results suggest that hyperthermic treatment is effective in radiotherapy not only by low-LET radiation but also by high-LET radiation such as C-beams. In conclusion, the depression of the tumour growth by the combined treatment of hyperthermia (42 degrees C) and the C-beams strongly suggests the available possible application of interdisciplinary cancer therapy for refractory tumours.