Quantitative assessment of thermal ablation in small animal tumor models: implications for pre-clinical studies of combination treatments

• Published in: Physics in medicine & biology Vol. 70; no. 17; pp. 175021 - 175036
• Main Authors: Bottiglieri, Anna, Prakash, Punit
• Format: Journal Article
• Language: English
• Published: England IOP Publishing 07.09.2025
• Subjects: Animals; bioheat transfer modeling; Combined Modality Therapy; Disease Models, Animal; Hyperthermia, Induced - methods; imaging-based computational models; Neoplasms - blood supply; Neoplasms - pathology; Neoplasms - therapy; pre-clinical studies; radiofrequency ablation; Rats; Temperature; thermal ablation; tumor biophysics characteristics; imaging-based computational models; thermal ablation; bioheat transfer modeling; radiofrequency ablation; pre-clinical studies; tumor biophysics characteristics
• ISSN: 0031-9155; 1361-6560; 1361-6560
• DOI: 10.1088/1361-6560/adfeb2

Background . Radiofrequency (RF) and other thermal ablation modalities in combination with systemic therapies are the subject of investigations for the treatment of tumors at risk of recurrence after first line therapies. The potential of combined therapeutic approaches is studied largely in small animals where size constraints and tumor-specific physical characteristics may significantly influence the local heating. Spatial-temporal analyses of tissue temperature profiles (i.e, thermal dosimetry) are largely neglected in preclinical studies, thus limiting the reliable assessment and interpretation of biological outcomes. Approach . Imaging-based information and complementary experimental reports of the (1) heat transfer conditions on the external surface of the tumor, (2) RF applicator position, (3) tumor shape and dimension, and (4) blood flow in major intra-tumoral vessels acquired from a total of N = 15 rat tumor models were used to build computational models of a local RF-hyperthermia system within a subcutaneous tumor. Analysis of the influence of each variable on 3D temperature profiles and on the percentage of tumor volume above lethal (50 °C) and below irreversible thermal damage (43 °C) thresholds, V 50 and V 43 , were conducted at 15 min of coupled electromagnetic-thermal transfer simulations. Results: For each examined variable, changes in V 50 values ranged between (1) 9%–31%, (2) 9%–18%, (3) 4%–58%, and (4) 12%–19% and those in V 43 are between (1) 24%–74%, (2) 51%–78%, (3) 3%–86%, and (4) 58%–65% indicating sources of considerable variability in tissue thermal profiles. Conclusions. Information of ablation procedure parameters, i.e. estimates of the RF applicator location, and accessible measurements of tumor biophysical characteristics, i.e. tumor size, shape and blood flow profile in major arteries, should be consistently reported in experimental studies of local heating in small animals in order to study heat-induced bioeffects and compare the outcomes in combination approaches with systemic therapies.