Interstitial radiation and hyperthermia in the Dunning R3327 prostate tumour model: therapeutic efficacy depends on radiation dose-rate, sequence and frequency of heating.

To determine the most effective means by which to apply the combined treatments of local tumour hyperthermia (LTH) with interstitial low dose-rate irradiation (IRT) we examined the significance of such factors as dose-rate of radiation, and the sequence and frequency of hyperthermia applications in the anaplastic Dunning prostate tumour subline R3327-AT1. IRT was carried out by the insertion of a single Ir-192 seed into the center of the tumour. For LTH treatments, the tumour-bearing leg was positioned in a circulating constant temperature water bath (43.5 +/- 0.1 degrees C) for 35 min. Neither LTH treatment alone nor the insertion of a dummy seed produced any change in tumour growth compared with sham-treated controls. With regard to the sequence of heating and IRT our results showed that during a 72-h treatment time (30 Gy, 40 cGy/h) a single heat treatment given just before the start of IRT was more efficient (TER = 1.47) in terms of growth delay than LTH given in the middle or the end of radiation treatment (TER approximately 1.0). The growth delay for both the 20 and 40 cGy/h groups appear to be linear with increasing dose for the IRT as well as the IRT + LTH groups. The higher dose-rate was more effective especially with respect to long-term delay in tumour growth in some of the animals. As TER at 40 cGy/h decreased subsequently with increasing treatment time from 1.47 to 1.25 at 60 Gy, we conclude that for treatment times > 72 h, one LTH just before IRT might not be sufficient. If multiple heat treatments are applied during a comparable time course, two LTH treatments one just before the start, the other at the end yielded the greatest local tumour control. In contrast, three LTH given daily were not more effective than the one LTH given just before the start of IRT. These data indicate a clear thermal enhancement of low dose-rate irradiation, with maximal sensitization when hyperthermia was given just before IRT. For multiple heatings a better understanding of the underlying mechanisms of sequencing and timing hopefully provides guidelines how to apply optimally both modalities in the treatment of cancer.

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