Continuous manual agitation significantly improves temperature distribution during closed hyperthermic intraperitoneal chemotherapy: Results of a porcine model.

Debate persists regarding the need for shaking during hyperthermic intraperitoneal chemotherapy. Studies assessing the thermal behaviors of the perfusate throughout the abdomen during hyperthermic intraperitoneal chemotherapy are limited. A closed hyperthermic intraperitoneal chemotherapy technique was performed in an institutional International Animal Care and Use Committee approved porcine model targeting a 41°C outflow temperature. Continuous temperature monitoring was conducted. Abdominal shaking was performed for 60 second intervals and temperatures were allowed to equilibrate without shaking between intervals. Temperature distributions and changes due to shaking were evaluated. These findings were validated against human subjects' data. The experimental procedure was conducted in 2 different animals and with 6 total shaking intervals assessed. Without shaking, temperatures were highly variable ranging between 38.0 to 42.2°C. Shaking the abdomen reduced the mean range of temperatures across all locations observed from 3.9°C to 0.8°C (P < .01). The locations of the most divergent temperatures varied based on perfusion cannula position. The point of minimum temperature heterogeneity was achieved in 28.3 (19.1-37.5) seconds. After shaking stopped, heterogeneity equal to the baseline measurements was seen on average within 25.7 (13.3-38.0) seconds. The outflow catheter differed from the system mean temperature by 1.4°C and from the coldest-reading probe by 2.8°C and outperformed the inflow catheter for all time points. With shaking these were significantly reduced to 0.4°C (P < .01) and 0.6°C (P < .01). The patient data mirrored that of the pig data. Shaking significantly reduces temperature variability within the abdomen during hyperthermic intraperitoneal chemotherapy, and significantly improves the ability of the outflow catheter to estimate internal temperatures.

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