Radiofrequency ablation for liver tumors abutting complex blood vessel structures: treatment protocol optimization using response surface method and computer modeling

Zheng Fang; Hongjun Wei; Hanwei Zhang; Michael A J Moser; Wenjun Zhang; Zhiqin Qian; Bing Zhang

doi:10.1080/02656736.2022.2075567

Radiofrequency ablation for liver tumors abutting complex blood vessel structures: treatment protocol optimization using response surface method and computer modeling

Int J Hyperthermia. 2022;39(1):733-742. doi: 10.1080/02656736.2022.2075567.

Authors

Zheng Fang^{1

2}, Hongjun Wei³, Hanwei Zhang³, Michael A J Moser⁴, Wenjun Zhang¹, Zhiqin Qian³, Bing Zhang²

Affiliations

¹ Department of Mechanical Engineering, University of Saskatchewan, Saskatoon, Canada.
² Intelligent Energy-based Tumor Ablation Laboratory, School of Mechatronic Engineering and Automation, Shanghai University, Shanghai, China.
³ School of Mechanical and Power Engineering, East China University of Science and Technology, Shanghai, China.
⁴ Department of Surgery, University of Saskatchewan, Saskatoon, Canada.

PMID: 35610101
DOI: 10.1080/02656736.2022.2075567

Abstract

Objective: To achieve a result of a large tumor ablation volume with minimal thermal damage to the surrounding blood vessels by designing a few clinically-adjustable operating parameters in radiofrequency ablation (RFA) for liver tumors abutting complex vascular structures.

Methods: Response surface method (RSM) was employed to correlate the ablated tumor volume ( $R_{a}$ ) and thermal damage to blood vessels ( $D_{t}$ ) based on RFA operating parameters: ablation time, electrode position, and insertion angle. A coupled electric-thermal-fluid RFA computer model was created as the testbed for RSM to simulate RFA process. Then, an optimal RFA protocol for the two conflicting goals, namely (1) large tumor ablation and (2) small thermal damage to the surrounding blood vessels, has been achieved under a specific ablation environment.

Results: Linear regression analysis confirmed that the RFA protocol significantly affected $R_{a}$ and $D_{t}$ (the adjusted coefficient of determination $R_{adj}^{2}$ = 93.61% and 95.03%, respectively). For a proposed liver tumor scenario (liver tumor with a dimension of 4 $\times$ 3 $\times$ 2.9 cm³ abutting a complex vascular structure), an optimized RFA protocol was found based on the regression results in RSM. Compared with a reference RFA protocol, in which the electrode was centered in the tumor with a 12-min ablation time, the optimized RFA protocol has increased $R_{a}$ from 98.1% to 99.6% and decreased $D_{t}$ from 4.1% to 0.4%, achieving nearly the complete ablation of proposed liver tumor and ignorable thermal damages to vessels.

Conclusion: This work showed that it is possible to design a few clinically-adjustable operating parameters of RFA for achieving a large tumor ablation volume while minimizing thermal damage to the surrounding blood vessels.

Keywords: Radiofrequency ablation; blood vessels; heat sink; liver tumor; treatment protocol optimization.

Publication types

Research Support, Non-U.S. Gov't

MeSH terms

Catheter Ablation* / methods
Clinical Protocols
Computer Simulation
Computers
Humans
Liver / pathology
Liver / surgery
Liver Neoplasms* / pathology
Liver Neoplasms* / surgery
Radiofrequency Ablation*