Supraphysiological thermal injury in Dunning AT-1 prostate tumor cells.

To investigate the potential application of thermal therapy in the treatment of prostate cancer, the effects of supraphysiological temperatures (40-70 degrees C) for clinically relevant time periods (approximately 15 minutes) were experimentally studied on attached Dunning AT-1 rat prostate cancer cells using multiple assays. The membrane and reproductive machinery were the targets of injury selected for this study. In order to assess membrane injury, the leakage of calcein was measured dynamically, and the uptake of PI was measured postheating (1-3 hours). Clonogenicity was used as a measure of injury to the reproductive machinery 7 days post-injury after comparable thermal insults. Experimental results from all three assays show a broad trend of increasing injury with an increase in temperature and time of insult. Membrane injury, as measured by the fluorescent dye assays, does not correlate with clonogenic survival for many of the thermal histories investigated. In particular, the calcein assay at temperatures of < or = 40 degrees C led to measurable injury accumulation (dye leakage), which was considered sublethal, as shown by significant survival for comparable insult in the clonogenic assay. Additionally, the PI uptake assay used to measure injury post-thermal insult shows that membrane injury continues to accumulate after thermal insult at temperatures > or = 50 degrees C and may not always correlate with clonogenicity at hyperthermic temperatures such as 45 degrees C. Last, although the clonogenic assay yields the most accurate cell survival data, it is difficult to acquire these data at temperatures > or = 50 degrees C because the thermal transients in the experimental setup are significant as compared to the time scale of the experiment. To improve prediction and understanding of thermal injury in this prostate cancer cell line, a first-order rate process model of injury accumulation (the Arrhenius model) was fit to the experimental results. The activation energy (E) obtained using the Arrhenius model for an injury criterion of 30 percent for all three assays revealed that the mechanism of thermal injury measured is likely different for each of the three assays: clonogenics (526.39 kJ/mole), PI (244.8 kJ/mole), and calcein (81.33 kJ/mole). Moreover, the sensitivity of the rate of injury accumulation (d omega/dt) to temperature was highest for the clonogenic assay, lowest for calcein leakage, and intermediate for PI uptake, indicating the strong influence of E value on d omega/dt. Since the clonogenic assay is linked to the ultimate survival of the cell and accounts for all lethal mechanisms of cellular injury, the E and A values obtained from clonogenic study are the best values to apply to predict thermal injury in cells. For higher temperatures (> or = 50 degrees C) indicative of thermal therapies, the results of PI uptake can be used as a conservative estimate of cell death (underprediction). This is useful until better experimental protocols are available to account for thermal transients at high temperature to assess clonogenic ability. These results provide further insights into the mechanisms of thermal injury in single cell systems and may be useful for designing optimal protocols for clinical thermal therapy.

[1]  S T Schuschereba,et al.  Survival of human epidermal keratinocytes after short-duration high temperature: synthesis of HSP70 and IL-8. , 1997, The American journal of physiology.

[2]  W. Linnemans,et al.  The effects of hyperthermia on the cytoskeleton: a review. , 1996, International journal of hyperthermia : the official journal of European Society for Hyperthermic Oncology, North American Hyperthermia Group.

[3]  D. Leeper,et al.  Effects of 42 degrees C hyperthermia on intracellular pH in ovarian carcinoma cells during acute or chronic exposure to low extracellular pH. , 1997, International journal of radiation oncology, biology, physics.

[4]  M. Meltz,et al.  Hyperthermic effects on viability and growth kinetics of human lymphoblastoid cells. , 1991, International journal of hyperthermia : the official journal of European Society for Hyperthermic Oncology, North American Hyperthermia Group.

[5]  Raphael C. Lee,et al.  Electrical Trauma: Response of cells to supraphysiological temperatures: experimental measurements and kinetic models , 1992 .

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

[7]  Kenneth R. Diller,et al.  Modeling of Bioheat Transfer Processes at High and Low Temperatures , 1992 .

[8]  T. Kato,et al.  Heat-induced apoptosis in human glioblastoma cell line A172. , 1998, Neurosurgery.

[9]  S. Rossi,et al.  Laparoscopic ablation of liver adenoma by radiofrequency electrocauthery. , 1995, Gastrointestinal endoscopy.

[10]  Y. Moroi,et al.  Augmentation of In vitro Cytolytic Activity of LAK Cells with Heated ATL‐Derived Cell Lines , 1993, The Journal of dermatology.

[11]  N. Marceau,et al.  Comparative evaluation of the mammalian cell thermal sensitivity to pulsed CO2-laser irradiation and hyperthermic water-bath treatment. , 1977, Radiation research.

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

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

[14]  W. Dewey,et al.  Evaluation of a role for intracellular Na+, K+, Ca2+, and Mg2+ in hyperthermic cell killing. , 1986, Radiation research.

[15]  M. Vitale,et al.  Supravital exposure to propidium iodide identifies apoptotic cells in the absence of nucleosomal DNA fragmentation. , 1996, Cytometry.

[16]  E. Gerner,et al.  Enhancement of hyperthermia-induced cytotoxicity by polyamines. , 1980, Cancer research.

[17]  M. Toner,et al.  Effectiveness of Poloxamer 188 in Arresting Calcein Leakage from Thermally Damaged Isolated Skeletal Muscle Cells a , 1994, Annals of the New York Academy of Sciences.

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

[19]  F. Sterzer,et al.  Microwave applicators for localized hyperthermia treatment of cancer of the prostate. , 1980, International journal of radiation oncology, biology, physics.

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

[21]  I. Zuna,et al.  Interstitial radiation and hyperthermia in the Dunning R3327 prostate tumour model: therapeutic efficacy depends on radiation dose-rate, sequence and frequency of heating. , 1996, International journal of radiation biology.

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

[23]  William B. Isaacs,et al.  Establishment and characterization of seven dunning rat prostatic cancer cell lines and their use in developing methods for predicting metastatic abilities of prostatic cancers , 1986 .

[24]  R. Higashikubo,et al.  Comparison of the cell kill measured by the Hoechst-propidium iodide flow cytometric assay and the colony formation assay. , 1983, Cell and tissue kinetics.

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

[26]  I. Friedberg,et al.  Heat-induced alterations in cell membrane permeability and cell inactivation of transformed mouse fibroblasts. , 1986, International journal of hyperthermia : the official journal of European Society for Hyperthermic Oncology, North American Hyperthermia Group.

[27]  Sandro Rossi,et al.  Percutaneous ultrasound-guided radiofrequency electrocautery for the treatment of small hepatocellular carcinoma , 1993 .

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

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

[30]  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 .

[31]  M. Yatvin,et al.  Role of cellular membranes in hyperthermia: some observations and theories reviewed. , 1993, International journal of hyperthermia : the official journal of European Society for Hyperthermic Oncology, North American Hyperthermia Group.

[32]  Determination of potential doubling times in human melanoma cell cultures subjected to irradiation and/or hyperthermia by flow cytometry. , 1994, Radiation research.

[33]  D. Chalmers,et al.  Local hyperthermia for prostatic disease: in vitro studies on human prostatic cancer cell lines. , 1992, British journal of urology.

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

[35]  J. Lepock,et al.  Protein denaturation in intact hepatocytes and isolated cellular organelles during heat shock , 1993, The Journal of cell biology.

[36]  P. Yi,et al.  Hyperthermia-induced intracellular ionic level changes in tumor cells. , 1983, Radiation research.

[37]  G. Hahn,et al.  Use of N-σ-dansyl-L-lysine and flow cytometry to identify heat-killed mammalian cells , 1985 .

[38]  P. Lin,et al.  Modification of rat thymocyte membrane properties by hyperthermia and ionizing radiation. , 1978, International journal of radiation biology and related studies in physics, chemistry, and medicine.

[39]  C. Streffer,et al.  The cytoskeleton and proliferation of melanoma cells under hyperthermal conditions. A correlative double immunolabelling study. , 1992, Strahlentherapie und Onkologie : Organ der Deutschen Rontgengesellschaft ... [et al].

[40]  T. Tsong Effect of phase transition on the kinetics of dye transport in phospholipid bilater structures. , 1975, Biochemistry.

[41]  J. Lepock,et al.  Thermotropic lipid and protein transitions in chinese hamster lung cell membranes: relationship to hyperthermic cell killing. , 1983, Canadian journal of biochemistry and cell biology = Revue canadienne de biochimie et biologie cellulaire.

[42]  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.

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

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

[45]  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.

[46]  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.

[47]  S. P. Tomasovic,et al.  Neutral red uptake and clonogenic survival assays of the hyperthermic sensitization of tumor cells to tumor necrosis factor. , 1989, Radiation research.

[48]  S. Sawada,et al.  Cell-cycle dependence of heat-induced interphase death in mouse L5178Y cells. , 1991, Radiation research.

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

[50]  T. Puck,et al.  ACTION OF X-RAYS ON MAMMALIAN CELLS , 1956, The Journal of experimental medicine.