References
- Armitage P. Statistical Methods in Medical Research. Blackwell Scientific, Boston and Melbourne 1980; 97–97
- Dewey W.C. The search for critical targets by heat. Radiation Research 1989a; 120: 191–204
- Dewey W.C. Mechanisms of thermal radiosensitization. Hyperthermia and Oncology, Vol. 2, Biology of Thermal Potentiation of Radiotherapy, M. Urano, E. Douple. VSP, Utrecht 1989b; 1–15
- 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. Effect of hyperthermia at 42 and 45°C on repair of radiation-induced DNA strand breaks in CHO cells. International Journal of Radiation Biology 1982; 41: 603–614
- Dikomey E., Jung H. Correlation between polymerase β activity and thermal radiosensitization in Chinese hamster ovary cells. Recent Research in Cancer Research, Vol. 109, Preclinical Hyperthermia, W. Hinkelbein, G. Bruggmoser, R. Engelhardt, M. Wannenmacher. Springer-Verlag, Berlin/Heidelberg 1988; 35–41
- Gibbs F.A., Jr. Externally induced hyperthermia. Innovations in Radiation Oncology, H.R. Withers, L.J. Peters. Springer-Verlag, Berlin/Heidelberg 1988; 291–301
- Grau C., Bentzen S.M., Overgaard J. Cytotoxic effects of misonidazole and cyclophosphamide on aerobic and hypoxic cells in a C3H mammary carcinoma in vivo. British Journal of Cancer 1990; 61: 61–64
- Grau C., Overgaard J. Effect of cancer chemotherapy on the hypoxic fraction of a solid tumor measured using a local tumor control assay. Radiotherapy and Oncology 1988; 13: 301–309
- 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., Leeper D.B. Combinations of hyperthermia (40°, 45°C) with radiation. Radiology 1976; 121: 451–454
- Henle K.J., Leeper D.B. The modification of radiation damage in CHO cells by hyperthermia at 40 and 45°C. Radiation Research 1977; 70: 415–424
- Henle K.J., Leeper D.B. Interactional of sublethal and potentially lethal 45°-hyperthermia and radiation damage at 0, 20, 37 or 40°C. European Journal of Cancer 1979; 15: 1387–1394
- Hunt J.W. Principles of ultrasound used for generating localized hyperthermia. An Introduction to the Practical Aspects of Clinical Hyperthermia, S.B. Field, J.W. Hand. Taylor & Francis, London 1990; 371–422
- Jones E.L., Douple E.B. Effect of step-down heating on brachytherapy in a murine tumor system. Radiation Research 1990; 124: 141–146
- Jorritsma J.B.M., Burgman P., Kampinga H.H., Konings A.W.T. DNA polymerase activity in heat killing and hyperthermic radiosensitization of mammalian cells as observed after fractionated heat treatments. Radiation Research 1986; 105: 307–319
- 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
- Leeper D.B. Molecular and cellular mechanisms of hyperthermia alone or combined with other modalities. Hyperthermic Oncology 1984 Vol. 2, J. Overgaard. Taylor & Francis, London 1985; 9–40
- Li G.C., Hahn G.M. A proposed operational model of thermotolerance based on effects of nutrients and the initial treatment temperature. Cancer Research 1980; 40: 4501–4508
- Lindegaard J.C., Overgaard J. Factors of importance for the development of the step-down heating effect in a C3H mammary carcinoma in vivo. International Journal of Hyperthermia 1987; 3: 79–91
- Lindegaard J.C., Overgaard J. Effect of step-down heating on hyperthermic radiosensitization in an experimental tumor and a normal tissue in vivo. Radiotherapy and Oncology 1988; 11: 143–151
- Lindegaard J.C., Overgaard J. Step-down heating in a C3H mammary carcinoma in vivo. Effects of varying the time and temperature of the sensitizing treatment. International Journal of Hyperthermia 1990; 6: 607–618
- Mills M.D., Meyn R.E. Hyperthermic potentiation of unrejoined DNA strand breaks following irradiation. Radiation Research 1983; 95: 327–338
- 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. Evidence for an upper temperature limit for thermotolerance development in L1A2 cells in vitro. International Journal of Hyperthermia 1986; 2: 299–309
- Overgaard J. Simultaneous and sequential hyperthermia and radiation treatment of an experimental tumor and its surrounding normal tissue in vivo. International Journal of Radiation Oncology, Biology and Physics 1980; 6: 1507–1517
- Overgaard J. Effect of hyperthermia on the hypoxic fraction in an experimental mammary carcinoma in vivo. British Journal of Radiology 1981; 54: 245–249
- Overgaard J. Rationale and problems in the design of clinical studies. Hyperthermic Oncology 1984 Vol. 2, J. Overgaard. Taylor & Francis, London 1985; 325–338
- Overgaard J. Some problems related to the clinical use of thermal isoeffect doses. International Journal of Hyperthermia 1987; 3: 329–336
- Overgaard J. The current and potential role of hyperthermia in radiotherapy. International Journal of Radiation Oncology Biology Physics 1989; 16: 535–549
- Overgaard J., Grau C., Lindegaard J.C., Horsman M.R. The potential of using hyperthermia to eliminate radioresistant hypoxic cells. Radiotherapy and Oncology 1991; 20: 113–116
- Roti Roti J.L., Laszlo A. The effects of hyperthermia on cellular macromolecules. Hyperthermia and Oncology, Vol. 1, Thermal Effects on Cells and Tissues, M. Urano, E. Douple. VSP, Utrecht 1988; 13–56
- Waters R.L., Lyons B.W., Axtell-Bartlett A. Inhibition of repair of radiation-induced DNA damage by thermal shock in Chinese hamster ovary cells. International Journal of Radiation Biology 1987; 51: 505–517