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Cancer Investigation Volume 2, 1984 - Issue 1
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Original Article

Combined Hyperthermia and Radiation Therapy in Cancer Treatment: Current Status

Jae Ho Kim Department of Radiation Therapy, Memorial Sloan-Kettering Cancer Center, 1275 York Avenue, New York, New York, 10021
Pages 69-80 | Published online: 11 Jun 2009

References

  • Coley W B. The treatment of inoperable sarcoma with the mixed toxins of erysipelas and Bacillus prodigiosus: Immediate and final results in one hundred and forty cases. JAMA 1898; 31: 389–395, 31:456–465, 1898
  • Warren S L. Preliminary study of the effect of artificial fever upon hopeless tumor cases. Am J Roentg 1925; 33: 75
  • Crile G. Selective destruction of cancers after exposure to heat. Ann Surg 1962; 156: 404–414
  • Chen T T, Heidelberger C. Quantitative studies on malignant transformation of mouse prostate cells by carcinogenic hydrocarbons in vitro. Int J Cancer 1969; 4: 166–178
  • Levine E M, Robbins E B. Differentia] temperature sensitivity of normal and cancer cells in culture. J Cell Comp Physiol 1980; 76: 373–380
  • Giovanella B C, Stehlin J S, Yim S O. Correlation of the thermosensitivity of cells to their malignant potential. Ann NY Acad Sci 1980; 335: 206–214
  • Kase C, Hahn C M. Differential heat response of normal and transformed human cells in tissue culture. Nature (London) 1975; 255: 228–229
  • Hahn G M. Comparison of the malignant potential of 10 T-1/2 cells and transformants with their survival responses to hyperthermia and to amphotericin B. Cancer Res 1980; 40: 3763–3767
  • Gerweck L E, Gillette E L, Dewey W C. Effect of heat and radiation on synchronous Chinese hamster cells: Killing and repair. Radiat Res 1974; 59: 139–140
  • Kim S H, Kim J H, Hahn E W. The enhanced killing of irradiated HeLa cells in synchronous culture by hyperthermia. Radiat Res 1976; 66: 337–345
  • Kal H B, Hatfield M, Hahn G M. Cell cycle progression of murine sarcoma cells after x-irradiation or heat shock. Radiology 1975; 117: 215–217
  • Sapareto S A, Hopwood L E, Dewey W C, et al. Effects of hyperthermia on survival and progression of Chinese hamster ovary cells. Cancer Res 1978; 38: 393–400
  • Dickson J A, Calderwood S K. In vivo hyperthermia of Yoshida tumor induces entry of non-proliferating cells into cycle. Nature (London) 1976; 263: 772–774
  • Naeslund J, Swenson K E. Investigations of the pH of malignant tumors in mice and humans after the administration of glucose. Acta Obst Gyn Scand 1953; 32: 359–367
  • Ashby B S. pH Studies in human malignant tumors. Lancet 1966; 2: 312–315
  • Overgaard J. Influence of extracellular pH on the viability and morphology of tumor cells exposed to hyperthermia. J Natl Cancer Inst 1976; 56: 1243–1250
  • Gerweck L E. Modification of cell lethality of elevated temperatures: The pH effect. Radiat Res 1972; 70: 224–235
  • Hofer K G, Mivechi N F. Tumor cell sensitivity to hyperthermia as a function of extracellular and intracellular pH. J Natl Cancer Inst 1980; 65: 621–625
  • Gerweck L E. Effect of microenvironmental factors on the response of cells to single and fractionated heat treatments. Natl Cancer Inst Monogr 1982; 61: 19–26
  • Schulman N, Hall E J. Hyperthermia: The effect on proliferative and plateau phase cell culture. Radiology 1974; 113: 297–309
  • Kim S H, Kim I H, Hahn E W. Enhanced killing of hypoxic tumor cells by hyperthermia. Br J Radiol 1975; 48: 872–874
  • Gerweck L E, Richardo B, Jennings M. The influence of variable oxygen concentration on the response of cells to heat or x-irradiation. Radiat Res 1981; 85: 314–320
  • Bass H, Moore J L, Coakley W T. Lethality in mammalian cells due to hyperthermia under oxic and hypoxic conditions. Int J Radiat Biol 1978; 33: 57–67
  • Kim S H, Kim J H, Hahn E W, et al. Selective killing of glucose and oxygen deprived HeLa cells by hyperthermia. Cancer Res 1980; 40: 3459–3462
  • Hahn G M, Li G C, Shiu E. Interaction of amphotericin B and 43°C hyperthermia. Cancer Res 1977; 37: 761–764
  • Hahn G M. Potential for therapy of drugs and hyperthermia. Cancer Res 1979; 39: 2264–2268
  • Yatvin M B, Clifton K H, Dennis W H. Hyperthermia and local anesthetics: Potentiation of survival of tumor bearing mice. Science 1979; 205: 195–196
  • Dennis W H, Yatvin M B. Correlation of hyperthermic sensitivity and membrane microviscosity in E coli 1 C1060. Int J Radiat Biol 1981; 39: 265–271
  • Robins H I, Dennis W H, Vorpahl J W, et al. Systemic lidocaine enhancement of tumor regression after hyperthermia. Natl Cancer Inst Monogr 1982; 61: 243–245
  • Hall E J, Astor M, Geard C, et al. Cytotoxicity of R0-07-0582; enhancement by hyperthermia and protection by cysteamine. Br J Cancer 1977; 35: 809–815
  • Hofer K G, Hofer M G, Ieracitono J, et al. Radiosensitization of hypoxic tumor cells by simultaneous administration of hyperthermia and nitroimidazole. Radiat Res 1977; 70: 362–377
  • Stratford I J, Adams G E. The effect of hyperthermia on differential cytotoxicity of a hypoxic cell radiosensitizer, R0-07-0582, on mammalian cells in vitro. Br J Cancer 1977; 35: 307–313
  • Adams G E, Stratford I J, Rajaratnam S. Interaction of the cytotoxic and sensitizing effects of electron-affinic drugs and hyperthermia. Natl Cancer Inst Monogr 1982; 61: 27–35
  • Kim J H, Kim S H, Hahn E W, et al. 5-Thio-D-glucose selectively potentiate hyperthermic killing of hypoxic tumor cells. Science 1978; 200: 206–207
  • Song C W, Guertin Dp, Levitt S R. Potentiation of cytotoxicity of 5-Thio-D-glucose on hypoxic cells by hyperthermia. Int J Radiat Oncol Biol Phys 1979; 5: 965–970
  • Floridi A, Paggi M G, Marcante M L, et al. Lonidamine, a selective inhibitor of aerobic glycolysis of murine tumor cells. J Natl Cancer Inst 1981; 66: 497–499
  • Kim J H, Kim S H, Alfieri A A, et al. Lonidamine, a hyperthermic sensitizer in HeLa cells and in Meth-A fibrosarcoma in vivo. Proceedings of the symposium on Lonidamine: A Clinical Evaluation in Cancer Therapy. VancouverCanada 1982
  • Belt J A, Thomas J A, Buschbaum R N, et al. Inhibition of lactate transport and glycolysis in Ehrlich ascites tumor cells by bioflavonoids. Biochemistry 1979; 18: 3506–3511
  • Kim J H, Kim S H, Alfieri A A, et al. Inhibitors of lactate transport as a hyperthermic sensitizer in HeLa cells. Cancer Res, in press
  • Li G C, Shiu E C, Hahn G M. Similarities in cellular inactivation by hyperthermia or by ethanol. Radiat Res 1980; 82: 257–268
  • Henle K J, Dethlefsen L A. Heat fractionation and thermotolerance: A review. Cancer Res 1978; 38: 1843–1851
  • Gerner E W, Boone R, Connor W G, et al. A transient thermotolerant survival response produced by single thermal doses in HeLa cells. Cancer Res 1976; 36: 1035–1040
  • Law M P, Coultas P C, Field S B. Induced thermal tolerance in the mouse ear. Br J Radiol 1979; 52: 308–314
  • Overgaard J, Suit H D, Walker A M. Multifractionated hyperthermia treatment of malignant and normal tissue in vivo. Cancer Res 1980; 40: 2025–2050
  • Jung H. Interaction of thermotolerance and thermosensitizafion induced in DHO cells by combined hyperthermic treatments at 40 and 43°C. Radiat Res 1982; 91: 433–445
  • Li G C, Hahn G M. A proposed operational model of thermotolerance based on effects of nutrients and the initial treatment temperature. Cancer Res 1980; 40: 4501–4508
  • Gerner E W, Holmes D K, Stickney D G, et al. Enhancement of hyperthermia induced cytotoxicity by the poly amines. Cancer Res 1980; 40: 432–438
  • Leeper D B, Karamuz J E, Henle K J. Hyperthermia induced alterations of macromolecular synthesis. Radiat Res 1977; 70: 610
  • McAllister L, Finkelstein D B. Heat shock proteins and thermal resistance in yeast. Biochem Biophys Res Commun 1980; 93: 819–824
  • Ben-Hur E, Elkind M M, Bronk B V. Thermally enhanced radioresponse of cultured Chinese hamster cells. Radiat Res 1974; 58: 38–51
  • Dewey W C, Freeman M L, Raaphorst G P, . Cell biology of hyperthermia and radiation. Radiation Biology in Cancer Research, R E Meyn, R Withers, et al. Raven Press, New York 1980; 585–619
  • Li G C, Evans R C, Hahn G M. Modification and inhibition of repair of potentially lethal x-ray damage of hyperthermia. Radiat Res 1976; 67: 491–501
  • Murthy A K, Harris J R, Belli J A. Hyperthermia and radiation response of plateau phase cells. Radiat Res 1977; 70: 241–247
  • Gerweck L E, Gillette E L, Dewey W C. Effect of heat and radiation on synchronous Chinese hamster cells; killing and repair. Radiat Res 1975; 64: 611–613
  • Dewey W C, Sapareto S A, Betten D A. Hyperthermic radiosensitization of synchronous Chinese hamster cells: Relationship between lethality and chromosomal aberrations. Radiat Res 1978; 76: 48–59
  • Robinson J E, Wizenberg M J, McCready W A. Combined hyperthermia and radiation suggest an alternative to heavy particle therapy for reduced oxygen enhancement ratio. Nature (London) 1974; 251: 521–522
  • Kim S H, Kim J H, Hahn E W. The radiosensitization of hypoxic tumor cells by hyperthermia. Radiology 1975; 114: 727–728
  • Durand R E. Effect of hyperthermia and/or irradiation in multi-cell spheroid systems. Proceedings of the International Symposium on Cancer Therapy by Hyperthermia and Radiation. American College of Radiology, Chicago 1975; 101–103
  • Gray L H, Conger A D, Ebert M, et al. The concentration of oxygen dissolved in tissues at the time of irradiation as a factor in radiotherapy. Br J Radiol 1953; 26: 638–648
  • Kim J H, Kim S H, Hahn E W. Hypoxic cell radiosensitization by moderate hyperthermia and glucose deprivation. Radiat Res 1983; 93: 416–420
  • Thrall D E, Gerweck L E, Gillette E L, Dewey W C. Response of cells in vitro and tissue in vivo to hyperthermia and x-irradiation. Adv Radiat Biol 1976; 6: 211–226
  • Stewart F A, Denekemp J. Combined x-rays and heating: Is there a therapeutic gain?. Cancer Therapy by Hyperthermia and Radiation, C Streffer. Urban & Schwarzenberg, Baltimore-Munich 1978; 249–250
  • Hahn E W, Alfieri A A, Kim J H. The significance of fractionation regimens in radiation and combined hyperthermia using a murine fibrosarcoma. Cancer 1978; 42: 2596–2599
  • Overgaard J. Simultaneous and sequential hyperthermia and radiation treatment of an experimental tumor and its surrounding normal tissue in vivo. Int J Radiat Oncol Biol Phys 1980; 6: 1507–1517
  • Stewart F A, Denekamp J. The therapeutic advantage of combined heat and x-rays on a mouse fibrosarcoma. Br J Radiol 1978; 51: 307–316
  • Alfieri A A, Hahn E W, Kim J H. The relationship between the time of fractionated and single doses of radiation and hyperthermia on the sensitization of an in vivo mouse tumor. Cancer 1975; 36: 893–903
  • Overgaard J. Influence of sequence and interval on the biological response to combined hyperthermia and radiation. Natl Cancer Inst Monogr 1982; 61: 325–332
  • Hall E J, Harisiadis L, Sung D, et al. Hyperthermia and low dose rate irradiation. Radiology 1978; 129: 195–198
  • Alfieri A A, Hahn E W, Hilaris B S, et al. Determination of the thermal enhancement ratio of interstitial radiotherapy and localized hyperthermia on two murine tumor systems, unpublished
  • Manning M R., Cetas T C, Gerner E W. Interstitial thermoradiotherapy. Natl Cancer Inst Monogr 1982; 61: 357–360
  • Marmor J B, Pounds D, Hahn G M. Treatment of superficial human neoplasms by local hyperthermia induced by ultrasound. Cancer 1979; 43: 196–205
  • Cony P M, Barlogie B, Tilchen E J, et al. Ultrasound induced hyperthermia for the treatment of human superficial tumors. Int J Radiat Oncol Biol Phys 1982; 8: 1225–1229
  • Lele P P, Parker K J. Temperature distributions in tissues during local hyperthermia by stationary or steered beams of unfocused or focused ultrasound. Br J Cancer 1982; 45: 108–121
  • Hunt J W. Applications of microwave, ultrasound, and radiofrequency heating. Natl Cancer Inst Monogr 1982; 61: 447–456
  • LeVeen H H, Ahmed N, Piccone V A, et al. Radiofrequency therapy: Clinical experience. Ann NY Acad Sci 1980; 335: 362–371
  • Storm F K, Harrison W H, Elliott R S, et al. Normal tissue and solid tumor effects of hyperthermia in animal models and clinical trials. Cancer Res 1979; 39: 2245–2251
  • Corry P M, Barlogie B, et al. The treatment of bulky human tumors with hyperthermia: I. A magnetic induction system. Presented at the 2nd Annual Meeting of the North American Hyperthermia Group, Salt Lake City, Utah, April 18, 1982
  • von Ardenne M, Kruger W. The use of hyperthermia within the frame of cancer multistep therapy. Ann NY Acad Sci 1980; 335: 356–361
  • Cheung A Y, Golding W M, Samaras G M. Direct contact applicators for microwave hyperthermia. J Microwave Power 1981; 16: 151–161
  • U R, Noell Kt, Woodward K T, et al. Microwave induced local hyperthermia in combination with radiotherapy for human malignant tumors. Cancer 1980; 45: 638–646
  • Gibbs F A. Clinical evaluation of a microwave/radiofrequency system (BSD Corporation) for induction of local and regional hyperthermia. J Microwave Power 1981; 16: 185–192
  • Kim J H, Antich P, Ahmed S, et al. Clinical experience with radiofrequency hyperthermia. J Microwave Power 1981; 16: 193–197
  • Kim J H, Hahn E W. Clinical and biological studies of localized hyperthermia. Cancer Res 1979; 39: 2258–2261
  • LeVeen H, Wapnik H, Piccone V, et al. Tumor eradication by radiofrequency therapy: Response in 21 patients. J Am Med Assoc 1976; 235: 2198–2200
  • Storm F K, Harrison W, Elliott R S, et al. Clinical radiofrequency hyperthermia by magnetic loop induction. J. Microwave Power 1981; 16: 179–183
  • Kim J H, Hahn E W, Ahmed S. Combination hyperthermia and radiation therapy for malignant melanoma. Cancer 1982; 50: 478–482
  • Perez C A, Kopecky W, Rao D V, et al. Local microwave hyperthermia and irradiation for future clinical trials. Int J Radiat Oncol Biol Phys 1981; 7: 765–772
  • Arcangeli G, Barni E, Cividalli A, et al. Effectiveness of microwave hyperthermia combined with ionizing radiation: Clinical results on neck node metastases. Int J Radiat Oncol Biol Phys 1980; 6: 143–148
  • Hornback N B, Shype R E, Shidnia H, et al. Preliminary clinical results of combined 433 MHz microwave therapy and radiation therapy on patients with advanced cancer. Cancer 1977; 40: 2854–2863

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