MICROPROCESSOR-CONTROLLED ND-YAG LASER FOR HYPERTHERMIA INDUCTION IN THE RIF-1 TUMOR

Near-infrared radiation from a Nd:YAG laser at 1,064 nm was used interstitially or superficially to induce hyperthermia in RIF-1 tumors in C3H male mice. A single 600-mu-m quartz fiber with a 0.5-cm cylindrical diffusor or a weakly diverging microlens at its distal end was used to deliver laser energy to tumors in the hind leg (mean volume = 100 mm3). Two thermocouples were inserted into each tumor. One thermocouple controlled a microprocessor-driven hyperthermia program (maximum output of 3.5 Watts) to maintain the desired temperature. Tumors were exposed to various temperature-time combinations (42-45-degrees-C/30 min). Our initial results indicated that excellent temperature control to within 0.2-degrees-C of the desired temperature at the feedback thermocouple was achievable during both superficial and interstitial heat treatments. Temperatures at the second thermocouple, however, were found to be lower by as much as 2.3-degrees-C (using the cylindrical diffusor) or higher by up to 4.6-degrees-C (using the microlens) when compared to the feedback thermocouple temperature. Several correlations were seen between total dose, tumor growth delay, percent skin necrosis, and temperature at the second thermocouple after several superficial and interstitial treatments. Statistically significant improvements in tumor growth delay (at 42 and 45-degrees-C) and increased percent skin necrosis at all temperatures were observed after superficial versus interstitial treatment.