PURPOSE: Recent cell culture studies by us and others suggest that some human carcinoma cells are more sensitive to heat than are rodent cells following mild hyperthermia. In studying the cellular mechanism of enhanced thermosensitivity of human tumor cells to hyperthermia, prostatic carcinoma cells of human origin were found to be more sensitive to mild hyperthermia than other human cancer cells. The present study was designed to determine the magnitude of radiosensitization of human prostatic carcinoma cells by mild hyperthermia and to examine whether the thermal radiosensitization is related to the intrinsic thermosensitivity of cancer cells. METHODS AND MATERIALS: Two human prostatic carcinoma cell lines (DU-145 and PC-3) and other carcinoma cells of human origin, in particular, colon (HT-29), breast (MCF-7), lung (A-549), and brain (U-251) were exposed to temperatures of 40-41 degrees C. Single acute dose rate radiation and fractionated radiation were combined with mild hyperthermia to determine thermal radiosensitization. The end point of the study was the colony-forming ability of single-plated cells. RESULTS: DU-145 and PC-3 cells were found to be exceedingly thermosensitive to 41 degrees C for 24 h, relative to other cancer cell lines. Ninety percent of the prostatic cancer cells were killed by a 24 h heat exposure. Prostatic carcinoma cells exposed to a short duration of heating at 41 degrees C for 2 h resulted in a substantial enhancement of radiation-induced cytotoxicity. The thermal enhancement ratios (TERs) of single acute dose radiation following heat treatment 41 C for 2 h were 2.0 in DU-145 cells and 1.4 in PC-3 cells. The TERs of fractionated irradiation combined with continuous heating at 40 degrees C were similarly in the range of 2.1 to 1.4 in prostate carcinoma cells. No significant radiosensitization was observed in MCF-7 and HT-29 cells under the same conditions. CONCLUSION: The present data suggest that a significant radiosensitization of prostatic cancer cells could be obtained by the combined treatment of radiation and mild hyperthermia. Future clinical trials should be aimed at achieving mild heating and fractionated radiation therapy.
PURPOSE: Recent cell culture studies by us and others suggest that some humancarcinoma cells are more sensitive to heat than are rodent cells following mild hyperthermia. In studying the cellular mechanism of enhanced thermosensitivity of humantumor cells to hyperthermia, prostatic carcinoma cells of human origin were found to be more sensitive to mild hyperthermia than other humancancer cells. The present study was designed to determine the magnitude of radiosensitization of humanprostatic carcinoma cells by mild hyperthermia and to examine whether the thermal radiosensitization is related to the intrinsic thermosensitivity of cancer cells. METHODS AND MATERIALS: Two humanprostatic carcinoma cell lines (DU-145 and PC-3) and other carcinoma cells of human origin, in particular, colon (HT-29), breast (MCF-7), lung (A-549), and brain (U-251) were exposed to temperatures of 40-41 degrees C. Single acute dose rate radiation and fractionated radiation were combined with mild hyperthermia to determine thermal radiosensitization. The end point of the study was the colony-forming ability of single-plated cells. RESULTS: DU-145 and PC-3 cells were found to be exceedingly thermosensitive to 41 degrees C for 24 h, relative to other cancer cell lines. Ninety percent of the prostatic cancer cells were killed by a 24 h heat exposure. Prostatic carcinoma cells exposed to a short duration of heating at 41 degrees C for 2 h resulted in a substantial enhancement of radiation-induced cytotoxicity. The thermal enhancement ratios (TERs) of single acute dose radiation following heat treatment 41 C for 2 h were 2.0 in DU-145 cells and 1.4 in PC-3 cells. The TERs of fractionated irradiation combined with continuous heating at 40 degrees C were similarly in the range of 2.1 to 1.4 in prostate carcinoma cells. No significant radiosensitization was observed in MCF-7 and HT-29 cells under the same conditions. CONCLUSION: The present data suggest that a significant radiosensitization of prostatic cancer cells could be obtained by the combined treatment of radiation and mild hyperthermia. Future clinical trials should be aimed at achieving mild heating and fractionated radiation therapy.
Authors: A M Kukiełka; M Hetnał; T Dąbrowski; T Walasek; P Brandys; D Nahajowski; R Kudzia; D Dybek; M Reinfuss Journal: Strahlenther Onkol Date: 2013-12-08 Impact factor: 3.621
Authors: A M Kukiełka; M Hetnał; P Brandys; T Walasek; T Dąbrowski; E Pluta; D Nahajowski; R Kudzia Journal: Strahlenther Onkol Date: 2013-04-20 Impact factor: 3.621
Authors: Andrzej M Kukiełka; Vratislav Strnad; Paul Stauffer; Tomasz Dąbrowski; Marcin Hetnał; Damian Nahajowski; Tomasz Walasek; Piotr Brandys; Robert Matys Journal: J Contemp Brachytherapy Date: 2015-05-28
Authors: Ioannis Androulakis; Rob M C Mestrom; Miranda E M C Christianen; Inger-Karine K Kolkman-Deurloo; Gerard C van Rhoon Journal: Cancers (Basel) Date: 2022-03-10 Impact factor: 6.639