Title :
Finite element analysis of tissue deformation with a radiofrequency ablation electrode for strain imaging
Author :
Jiang, Jingfeng ; Varghese, Tomy ; Chen, Quan ; Hall, Timothy J. ; Zagzebski, James A.
Author_Institution :
Wisconsin Univ., Madison, WI
fDate :
2/1/2007 12:00:00 AM
Abstract :
Recent studies have shown that radiofrequency (R-F) electrode displacement or deformation-based strain imaging can be used as an alternate imaging modality to monitor and to evaluate ablative therapies for liver tumors. This paper describes a biomechanical model used to study RF electrode deformation-based strain imaging, in conjunction with a simulated medical ultrasound linear array transducer. The computer simulations reported here are important steps toward understanding this biomechanical system in vivo, thus providing a basis for improving system design, including the motion tracking algorithm and image guidance for performing RF electrode displacement-strain imaging in vivo
Keywords :
biomechanics; biomedical electrodes; biomedical imaging; biothermics; deformation; finite element analysis; liver; patient treatment; radiofrequency heating; tumours; RF electrode displacement-strain imaging; biomechanical model; finite element analysis; image guidance; motion tracking algorithm; radiofrequency ablation electrode; simulated medical ultrasound linear array transducer; tissue deformation; Biomedical electrodes; Biomedical monitoring; Capacitive sensors; Computerized monitoring; Deformable models; Finite element methods; Image analysis; In vivo; Radio frequency; Ultrasonic imaging; Animals; Catheter Ablation; Computer Simulation; Elasticity; Finite Element Analysis; Humans; Microelectrodes; Models, Biological; Stress; Stress, Mechanical; Surgery, Computer-Assisted; Ultrasonography, Interventional;
Journal_Title :
Ultrasonics, Ferroelectrics, and Frequency Control, IEEE Transactions on
DOI :
10.1109/TUFFC.2007.242
