BACKGROUND: High-frequency electricity is used in the majority of surgical interventions. However, modern computer-based training and simulation systems rely on physically unrealistic models that fail to capture the interplay of the electrical, mechanical and thermal properties of biological tissue. METHODS: We present a real-time and physically realistic simulation of electrosurgery by modelling the electrical, thermal and mechanical properties as three iteratively solved finite element models. To provide subfinite-element graphical rendering of vaporized tissue, a dual-mesh dynamic triangulation algorithm based on isotherms is proposed. The block compressed row storage (BCRS) structure is shown to be critical in allowing computationally efficient changes in the tissue topology due to vaporization. RESULTS: We have demonstrated our physics-based electrosurgery cutting algorithm through various examples. Our matrix manipulation algorithms designed for topology changes have shown low computational cost. CONCLUSIONS: Our simulator offers substantially greater physical fidelity compared to previous simulators that use simple geometry-based heat characterization.
BACKGROUND: High-frequency electricity is used in the majority of surgical interventions. However, modern computer-based training and simulation systems rely on physically unrealistic models that fail to capture the interplay of the electrical, mechanical and thermal properties of biological tissue. METHODS: We present a real-time and physically realistic simulation of electrosurgery by modelling the electrical, thermal and mechanical properties as three iteratively solved finite element models. To provide subfinite-element graphical rendering of vaporized tissue, a dual-mesh dynamic triangulation algorithm based on isotherms is proposed. The block compressed row storage (BCRS) structure is shown to be critical in allowing computationally efficient changes in the tissue topology due to vaporization. RESULTS: We have demonstrated our physics-based electrosurgery cutting algorithm through various examples. Our matrix manipulation algorithms designed for topology changes have shown low computational cost. CONCLUSIONS: Our simulator offers substantially greater physical fidelity compared to previous simulators that use simple geometry-based heat characterization.
Authors: Ganesh Sankaranarayanan; James D Adair; Tansel Halic; Mark A Gromski; Zhonghua Lu; Woojin Ahn; Daniel B Jones; Suvranu De Journal: Surg Endosc Date: 2010-08-24 Impact factor: 4.584
Authors: Ganesh Sankaranarayanan; Rajeswara R Resapu; Daniel B Jones; Steven Schwaitzberg; Suvranu De Journal: Surg Endosc Date: 2013-04-23 Impact factor: 4.584