TY - JOUR
T1 - Application of HIPEC simulations for optimizing treatment delivery strategies
AU - Löke, Daan R.
AU - Kok, H. Petra
AU - Helderman, Roxan F. C. P. A.
AU - Bokan, Bella
AU - Franken, Nicolaas A. P.
AU - Oei, Arlene L.
AU - Tuynman, Jurriaan B.
AU - Tanis, Pieter J.
AU - Crezee, Johannes
N1 - Funding Information: This research was funded by the Dutch Cancer Society, UVA grant number [10595 & 13420]. Publisher Copyright: © 2023 The Author(s). Published with license by Taylor & Francis Group, LLC.
PY - 2023
Y1 - 2023
N2 - Introduction: Hyperthermic IntraPEritoneal Chemotherapy (HIPEC) aims to treat microscopic disease left after CytoReductive Surgery (CRS). Thermal enhancement depends on the temperatures achieved. Since the location of microscopic disease is unknown, a homogeneous treatment is required to completely eradicate the disease while limiting side effects. To ensure homogeneous delivery, treatment planning software has been developed. This study compares simulation results with clinical data and evaluates the impact of nine treatment strategies on thermal and drug distributions. Methods: For comparison with clinical data, three treatment strategies were simulated with different flow rates (1600-1800mL/min) and inflow temperatures (41.6–43.6 °C). Six additional treatment strategies were simulated, varying the number of inflow catheters, flow direction, and using step-up and step-down heating strategies. Thermal homogeneity and the risk of thermal injury were evaluated. Results: Simulated temperature distributions, core body temperatures, and systemic chemotherapeutic concentrations compared well with literature values. Treatment strategy was found to have a strong influence on the distributions. Additional inflow catheters could improve thermal distributions, provided flow rates are kept sufficiently high (>500 mL/min) for each catheter. High flow rates (1800 mL/min) combined with high inflow temperatures (43.6 °C) could lead to thermal damage, with (Formula presented.) values of up to 27 min. Step-up and step-down heating strategies allow for high temperatures with reduced risk of thermal damage. Conclusion: The planning software provides valuable insight into the effects of different treatment strategies on peritoneal distributions. These strategies are designed to provide homogeneous treatment delivery while limiting thermal injury to normal tissue, thereby optimizing the effectiveness of HIPEC.
AB - Introduction: Hyperthermic IntraPEritoneal Chemotherapy (HIPEC) aims to treat microscopic disease left after CytoReductive Surgery (CRS). Thermal enhancement depends on the temperatures achieved. Since the location of microscopic disease is unknown, a homogeneous treatment is required to completely eradicate the disease while limiting side effects. To ensure homogeneous delivery, treatment planning software has been developed. This study compares simulation results with clinical data and evaluates the impact of nine treatment strategies on thermal and drug distributions. Methods: For comparison with clinical data, three treatment strategies were simulated with different flow rates (1600-1800mL/min) and inflow temperatures (41.6–43.6 °C). Six additional treatment strategies were simulated, varying the number of inflow catheters, flow direction, and using step-up and step-down heating strategies. Thermal homogeneity and the risk of thermal injury were evaluated. Results: Simulated temperature distributions, core body temperatures, and systemic chemotherapeutic concentrations compared well with literature values. Treatment strategy was found to have a strong influence on the distributions. Additional inflow catheters could improve thermal distributions, provided flow rates are kept sufficiently high (>500 mL/min) for each catheter. High flow rates (1800 mL/min) combined with high inflow temperatures (43.6 °C) could lead to thermal damage, with (Formula presented.) values of up to 27 min. Step-up and step-down heating strategies allow for high temperatures with reduced risk of thermal damage. Conclusion: The planning software provides valuable insight into the effects of different treatment strategies on peritoneal distributions. These strategies are designed to provide homogeneous treatment delivery while limiting thermal injury to normal tissue, thereby optimizing the effectiveness of HIPEC.
KW - Hyperthermic intrapertioneal chemotherapy (HIPEC)
KW - cancer biology
KW - computational fluid dynamics(CFD)
KW - computational modeling
KW - drug dynamics
KW - treatment planning software
UR - http://www.scopus.com/inward/record.url?scp=85164856100&partnerID=8YFLogxK
U2 - https://doi.org/10.1080/02656736.2023.2218627
DO - https://doi.org/10.1080/02656736.2023.2218627
M3 - Article
C2 - 37455017
SN - 0265-6736
VL - 40
JO - International journal of hyperthermia
JF - International journal of hyperthermia
IS - 1
M1 - 2218627
ER -