References
- Connor W. G., Gerner E. W., Miller R. C., Boone M. L. M. Prospects for hyperthermia in human cancer therapy. Part II: Implications of biological and physical data for applications of hyperthermia to man. Radiology 1977; 123: 497–503
- Dewey W. C., Hopwood L. E., Sapareto S. A., Gerweck L. E. Cellular responses to combinations of hyperthermia and radiation. Radiology 1977; 123: 463–474
- Dikomey E. Differential cytotoxic effects of hyperthermia below and above 43°C alone or combined with X irradiation. Radiation Research 1981; 88: 489–501
- Field S. B., Morris C. C. The relationship between heating time and temperature: its relevance to clinical hyperthermia. Radiotherapy and Oncology 1983; 1: 179–186
- Field S. B., Morris C. C. Application of the relationship between heating time and temperature for use as a measure of thermal dose. Hyperthermic Oncology 1984, J. Overgaard. Taylor & Francis, London 1984; Volume 1: 183–186
- Henle K. J. Sensitization to hyperthermia below 43°C induced in Chinese hamster ovary cells by step-down heating. Journal of the National Cancer Institute 1980; 64: 1479–1483
- Henle K. J., Dethlefsen L. A. Time-temperature relationships for heat-induced killing of mammalian cells. Annals of the New York Academy of Sciences 1980; 335: 234–253
- Henle K. J., Dethlefsen L. A. Heat fractionation and step-down heating of murine mammary tumors in the foot. National Cancer Institute Monograph 1982; 61: 283–285
- Henle K. J., Leeper D. B. Combinations of hyperthermia (40°, 45°C) with radiation. Radiology 1976; 121: 451–454
- Hume S. P., Marigold J. C. L. The effect of step-down heating on mouse small intestinal mucosa. International Journal of Hyperthermia 1987; 3: 153–165
- Johnson H. A., Pavelec M. Thermal injury due to normal body temperature. American Journal of Pathology 1972a; 66: 557–564
- Johnson H. A., Pavelec M. Thermal noise in cells: a cause of spontaneous loss of cell function. American Journal of Pathology 1972b; 69: 119–129
- Joshi D. S., Jung H. Thermotolerance and sensitization induced in CHO cells by fractionated hyperthermic treatments at 38°-45°C. European Journal of Cancer 1979; 15: 345–350
- Jung H. Interaction of thermotolerance and thermosensitization induced in CHO cells by combined hyperthermic treatments at 40 and 43°C. Radiation Research 1982; 91: 433–446
- Jung H. A generalized concept for cell killing by heat. Radiation Research 1986; 106: 56–72
- Jung H., Kölling H. Induction of thermotolerance and sensitization in CHO cells by combined hyperthermic treatments at 40 and 43°C. European Journal of Cancer 1980; 16: 1523–1528
- Leith J. T., Miller R. C., Gerner E. W., Boone M. L. N. Hyperthermic potentiation. Biological aspects and applications to radiation therapy. Cancer (Philadelphia) 1977; 39: 766–779
- Li G. C., Cameron R. B., Sapareto S. A., Hahn G. M. Reinterpretation of Arrhenius analysis of cell inactivation by heat. National Cancer Institute Monograph 1982; 61: 111–113
- Lindegaard J. C., Overgaard J. Factors of importance for the development of the step-down heating effect in C3H mammary carcinoma in vivo. International Journal of Hyperthermia 1987; 3: 79–91
- Miyakoshi J., Hiraoka M., Takahashi M., Kano E., Abe M., Heki S.-L. Skin responses to step-up and step-down heating in C3H mice. International Journal of Radiation Oncology, Biology and Physics 1983; 9: 1527–1532
- Miyakoshi J., Ikebuchi M., Furukawa M., Yamagata K., Sugahara T., Kano E. Combined effects of X irradiation and hyperthermia (42 and 44°C) on Chinese hamster V-79 cells in vitro. Radiation Research 1979; 79: 77–88
- Nielsen O. S., Henle K. J., Overgaard J. Arrhenius analysis of survival curves from thermotolerant and step-down heated L1A2 cells in vitro. Radiation Research 1982; 91: 468–482
- Rofstad E. K., Brustad T. Differences in thermosensitization among cloned cell lines isolated from a single human melanoma xenograft. Radiation Research 1986; 106: 147–155
- Urano M., Kahn J. The effect of step-down heating on murine normal and tumour tissues. Radiation Research 1983; 94: 350–358