TY - GEN
T1 - Creating fast finite element models from medical images
AU - Berkley, Jeffrey
AU - Oppenheimer, Peter
AU - Weghorst, Suzanne
AU - Berg, Daniel
AU - Raugi, Gregory
AU - Haynor, Dave
AU - Ganter, Mark
AU - Brooking, Cole
AU - Turkiyyah, George
PY - 2000
Y1 - 2000
N2 - The procedure for creating a patient-specific virtual tissue model with finite element (FE) based haptic (force) feedback varies substantially from that which is required for generating a typical volumetric model. In addition to extracting geometrical and texture map data to provide visual realism, it is necessary to obtain information for supporting a FE model. Among many differences, FE-based VR environments require a FE model with appropriate material properties assigned. The FE equation must also be processed in a manner specific to the surgical task in order to maximize deformation and haptic computation speed. We are currently developing methodologies and support software for creating patient-specific models from medical images. The steps for creating such a model are as foljows: 1) obtain medical images and texture maps of tissue structures; 2) extract tissue structure contours; 3) generate a 3D mesh from the tissue structure contours; 4) alter mesh based on simulation objectives; 5) assign material properties, boundary nodes and texture maps; 6) generate a fast (or real-time) FE model; and 7) support the tissue models with task-specific tools and training aids. This paper will elaborate on the above steps with particular reference to the creation of suturing simulation software, which will also be described.
AB - The procedure for creating a patient-specific virtual tissue model with finite element (FE) based haptic (force) feedback varies substantially from that which is required for generating a typical volumetric model. In addition to extracting geometrical and texture map data to provide visual realism, it is necessary to obtain information for supporting a FE model. Among many differences, FE-based VR environments require a FE model with appropriate material properties assigned. The FE equation must also be processed in a manner specific to the surgical task in order to maximize deformation and haptic computation speed. We are currently developing methodologies and support software for creating patient-specific models from medical images. The steps for creating such a model are as foljows: 1) obtain medical images and texture maps of tissue structures; 2) extract tissue structure contours; 3) generate a 3D mesh from the tissue structure contours; 4) alter mesh based on simulation objectives; 5) assign material properties, boundary nodes and texture maps; 6) generate a fast (or real-time) FE model; and 7) support the tissue models with task-specific tools and training aids. This paper will elaborate on the above steps with particular reference to the creation of suturing simulation software, which will also be described.
UR - http://www.scopus.com/inward/record.url?scp=0033642331&partnerID=8YFLogxK
U2 - 10.3233/978-1-60750-914-1-26
DO - 10.3233/978-1-60750-914-1-26
M3 - Conference contribution
C2 - 2000137394
AN - SCOPUS:0033642331
SN - 1586030140
SN - 9781586030148
T3 - Studies in Health Technology and Informatics
SP - 26
EP - 32
BT - Medicine Meets Virtual Reality 2000 - Envisioning Healing
PB - IOS Press
T2 - 8th Annual Meeting of Medicine Meets Virtual Reality, MMVR 2000
Y2 - 27 January 2000 through 30 January 2000
ER -