Prediction of tissue thermal damage
Abstract
This paper presents a method to characterize tissue thermal damage by taking into account the thermal-mechanical effect of soft tissues for thermal ablation. This method integrates the bio-heating conduction and non-rigid motion dynamics to describe thermal-mechanical behaviors of soft tissues and further extends the traditional tissue damage model to characterize thermal-mechanical damage of soft tissues. Simulations and comparison analysis demonstrate that the proposed method can effectively predict tissue thermal damage and it also provides reliable guidelines for control of the thermal ablation procedure.
References
[1] | Prakash P. Theoretical modeling for hepatic microwave ablation. Open Biomed Eng J. (2010) ; 4: : 27-38. |
[2] | Watanabe H, , Yamazaki N, , Kobayashi Y, , Miyashita T, , Ohdaira T, , Hashizume M, et al. Estimation of intraoperative blood flow during liver rf ablation using a finite element method-based biomechanical simulation. 2011 Annual International Conference of the Ieee Engineering in Medicine and Biology Society (Embc). (2011) : 7441-7445. |
[3] | Wu T, , Li P, , Shao Q, , Hong J, , Yang L, , Wu S. A simulation-experiment method to characterize the heat transfer in ex-vivo porcine hepatic tissue with a realistic microwave ablation system. Numerical Heat Transfer, Part A: Applications. (2013) ; 64: (9): 729-43. |
[4] | Rattanadecho P, , Keangin P. Numerical study of heat transfer and blood flow in two-layered porous liver tissue during microwave ablation process using single and double slot antenna. International Journal of Heat and Mass Transfer. (2013) ; 58: (1): 457-70. |
[5] | LAU CP, , TAI YT, , Lee PW. The effects of radiofrequency ablation versus medical therapy on the quality-of-life and exercise capacity in patients with accessory pathway-mediated supraventricular tachycardia: a treatment comparison study. Pacing and Clinical Electrophysiology. (1995) ; 18: (3): 424-32. |
[6] | Rounsevell R, , Forman JR, , Clarke J. Atomic force microscopy: mechanical unfolding of proteins. Methods. (2004) ; 34: (1): 100-11. |
[7] | Shen WS, , Zhang J. Modeling and numerical simulation of bioheat transfer and biomechanics in soft tissue. Mathematical and Computer Modelling. (2005) ; 41: (11-12): 1251-65. |
[8] | Xu F, , Lu T. Introduction to skin biothermomechanics and thermal pain, Springer; (2011) . |
[9] | Li X, , Zhong Y, , Jazar R, , Subic A. Thermal-mechanical deformation modelling of soft tissues for thermal ablation. Bio-Medical Materials And Engineering. (2014) ; 24: (6): 2299-310. |
[10] | Henriques F, , Jr, Moritz A. Studies of thermal injury: I. The conduction of heat to and through skin and the temperatures attained therein. A theoretical and an experimental investigation. The American Journal of Pathology. (1947) ; 23: (4): 530. |
[11] | Pearce JA. Comparative analysis of mathematical models of cell death and thermal damage processes. International Journal of Hyperthermia. (2013) ; 29: (4): 262-80. |