In vitro thermal therapy of AT-1 Dunning prostate tumours

To advance the utility of prostate thermal therapy, this study investigated the thermal thresholds (temperature-time) for prostate tissue destructionin vitro. The AT-1 Dunning prostate tumour model was chosen for the study. Three hundred micron thick sections were subjected to controlled temperature-time heating, which ranged from low (40°C, 15 min) to high thermal exposures (70°C, 2 min) (n = 6). After subsequent tissue culture at 37°C, the sections were evaluated for tissue injury at 3, 24 and 72 h by two independent methods: histology and dye uptake. A graded increase in injury was identified between the low and high thermal exposures. Maximum histologic injury occurred above 70°C, 1 min with >95% of the tissue area undergoing significant cell injury and coagulative necrosis. The control and 40°C, 15 min sections showed histologic evidence of apoptosis following 24 and 72 h in culture. Similar signs of apoptosis were minimal or absent at higher thermal histories. Vital-dye uptake quantitatively confirmed complete cell death after 70°C, 2 min. Using the dye data, Arrhenius analysis showed an apparent breakpoint at 50°C, with activation energies of 135.8 kcal/mole below and 4.7 kcal/mole above the threshold after 3 h in culture. These results can be used as a conservative benchmark for thermal injury in the cancerous prostate. Further characterization of the response to thermal therapy in an animal model and in human tissues will be important in establishing the efficacy of the procedure

[1]  Z. Petrovich,et al.  Transrectal hyperthermia as palliative treatment for advanced adenocarcinoma of prostate and studies of cell-mediated immunity. , 1993, Urology.

[2]  Y. Takano,et al.  Apoptosis induced by mild hyperthermia in human and murine tumour cell lines: A study using electron microscopy and DNA gel electrophoresis , 1991, The Journal of pathology.

[3]  R. Witherington,et al.  Transscrotal approach for insertion of three-component inflatable penile prosthesis. , 1989, Urology.

[4]  J C Bischof,et al.  Evaluation of thermal therapy in a prostate cancer model using a wet electrode radiofrequency probe. , 2001, Journal of endourology.

[5]  A. Zlotta,et al.  Percutaneous transperineal radiofrequency ablation of prostate tumour: safety, feasibility and pathological effects on human prostate cancer. , 1998, British journal of urology.

[6]  I. Buckley A light and electron microscopic study of thermally injured cultured cells. , 1972, Laboratory investigation; a journal of technical methods and pathology.

[7]  Buckley Ik A light and electron microscopic study of thermally injured cultured cells. , 1972, Laboratory investigation; a journal of technical methods and pathology.

[8]  E. Azzam,et al.  Hyperthermia and thermal tolerance in normal and ataxia telangiectasia human cell strains. , 1983, Cancer research.

[9]  J C Bischof,et al.  Supraphysiological thermal injury in Dunning AT-1 prostate tumor cells. , 1998, Journal of biomechanical engineering.

[10]  D D Watson,et al.  Electrode radius predicts lesion radius during radiofrequency energy heating. Validation of a proposed thermodynamic model. , 1990, Circulation research.

[11]  J. Bischof,et al.  Thermal therapy of prostate tumor tissue in the dorsal skin flap chamber. , 2002, Microvascular research.

[12]  J. Folkman The vascularization of tumors. , 1976, Scientific American.

[13]  David G. Bostwick,et al.  Temperature-correlated histo pathologic changes following microwave thermoablation of obstructive tissue in patients with benign prostatic hyperplasia , 1996 .

[14]  D. Bostwick,et al.  Temperature-correlated histopathologic changes following microwave thermoablation of obstructive tissue in patients with benign prostatic hyperplasia. , 1996, Urology.

[15]  F. Montorsi,et al.  Transrectal microwave hyperthermia for advanced prostate cancer: long-term clinical results. , 1992, The Journal of urology.

[16]  Henriques Fc,et al.  Studies of thermal injury; the predictability and the significance of thermally induced rate processes leading to irreversible epidermal injury. , 1947 .

[17]  Sharon Thomsen,et al.  Rate Process Analysis of Thermal Damage , 1995 .

[18]  T. Otsuka,et al.  Hyperthermia induces apoptosis in malignant fibrous histiocytoma cells in vitro , 1996, International journal of cancer.

[19]  B. Hooper Optical-thermal response of laser-irradiated tissue , 1996 .

[20]  Z. Petrovich,et al.  Regional Hyperthermia in Patients with Recurrent Genitourinary Cancer , 1991, American journal of clinical oncology.

[21]  J C Bischof,et al.  Dynamics of cell membrane permeability changes at supraphysiological temperatures. , 1995, Biophysical journal.

[22]  T. Kigure,et al.  Microwave ablation of the adrenal gland: experimental study and clinical application. , 1996, British journal of urology.

[23]  W. Berndt Renal Slices and Perfusion , 1987 .

[24]  J. Oesterling,et al.  Prostate Cancer Clinical Guidelines Panel Summary report on the management of clinically localized prostate cancer. The American Urological Association. , 1995, The Journal of urology.

[25]  J. Bischof,et al.  Cryosurgical changes in the porcine kidney: histologic analysis with thermal history correlation. , 2002, Cryobiology.

[26]  W. Dewey,et al.  Variation in sensitivity to heat shock during the cell-cycle of Chinese hamster cells in vitro. , 1971, International journal of radiation biology and related studies in physics, chemistry, and medicine.

[27]  J C Bischof,et al.  Cryosurgery of dunning AT-1 rat prostate tumor: thermal, biophysical, and viability response at the cellular and tissue level. , 1997, Cryobiology.

[28]  J. Kerr,et al.  Cell death induced in a murine mastocytoma by 42-47 degrees C heating in vitro: evidence that the form of death changes from apoptosis to necrosis above a critical heat load. , 1990, International journal of radiation biology.

[29]  Z. Darżynkiewicz,et al.  The cell cycle related differences in susceptibility of HL-60 cells to apoptosis induced by various antitumor agents. , 1993, Cancer research.

[30]  D D Watson,et al.  Tissue Heating During Radiofrequency Catheter Ablation: A Thermodynamic Model and Observations in Isolated Perfused and Superfused Canine Right Ventricular Free Wall , 1989, Pacing and clinical electrophysiology : PACE.

[31]  R. Benz Structural requirement for the rapid movement of charged molecules across membranes. Experiments with tetraphenylborate analogues. , 1988, Biophysical journal.

[32]  D I Rosenthal,et al.  Radiofrequency tissue ablation: importance of local temperature along the electrode tip exposure in determining lesion shape and size. , 1996, Academic radiology.

[33]  E. Gerner,et al.  Hyperthermic potentiation. Biological aspects and applications to radiation therapy , 1977, Cancer.

[34]  S. Shariat,et al.  Transperineal radiofrequency interstitial tumor ablation of the prostate: correlation of magnetic resonance imaging with histopathologic examination. , 1997, Urology.

[35]  R Lazzara,et al.  Comparison of in vivo tissue temperature profile and lesion geometry for radiofrequency ablation with a saline-irrigated electrode versus temperature control in a canine thigh muscle preparation. , 1995, Circulation.

[36]  H. Goldfarb Bipolar laparoscopic needles for myoma coagulation. , 1995, The Journal of the American Association of Gynecologic Laparoscopists.

[37]  N. Marceau,et al.  Rate-limiting events in hyperthermic cell killing. , 1978, Radiation research.

[38]  C. Song,et al.  Thermal sensitivity and kinetics of thermotolerance in bovine aortic endothelial cells in culture. , 1991, International journal of hyperthermia : the official journal of European Society for Hyperthermic Oncology, North American Hyperthermia Group.

[39]  A. Roberts,et al.  Effect of marked hyperthermia upon the canine bladder. , 1972, The Journal of urology.

[40]  K. Shinohara,et al.  Heat-induced apoptosis and p53 in cultured mammalian cells. , 1997, International journal of radiation biology.

[41]  B. Rubinsky,et al.  Chemical adjuvant cryosurgery with antifreeze proteins , 1997, Journal of surgical oncology.

[42]  M. Harris Criteria of viability in heat-treated cells. , 1966, Experimental cell research.

[43]  A. J. Gandolfi,et al.  Use of renal slices and renal tubule suspensions for in vitro toxicity studies , 1993 .

[44]  E. Carstensen,et al.  Ultrasonic treatment of tumors: I. Absence of metastases following treatment of a hamster fibrosarcoma. , 1979, Ultrasound in medicine & biology.

[45]  A. Yerushalmi,et al.  Local microwave hyperthermia in the treatment of carcinoma of the prostate. , 1987, Oncology.

[46]  D B Denham,et al.  Interstitial laser hyperthermia model development for minimally invasive therapy of breast carcinoma. , 1998, Journal of the American College of Surgeons.

[47]  J. Valvano,et al.  BIOHEAT TRANSFER , 1999 .

[48]  W. Dewey,et al.  Time-temperature analysis of cell killing of BHK cells heated at temperatures in the range of 43.5°C to 57.0°C☆ , 1990 .

[49]  H. Goldfarb Nd:YAG laser laparoscopic coagulation of symptomatic myomas. , 1992, The Journal of reproductive medicine.

[50]  C. Servadio,et al.  Local hyperthermia for prostate cancer. , 1991, Urology.

[51]  A M Stoll,et al.  Mathematical model of skin exposed to thermal radiation. , 1969, Aerospace medicine.