Title :
Mathematically Modeling the Effects of Electrically Stimulating Skeletal Muscle
Author :
Davidson, J.B. ; Kim, J. ; Cheng, L.K. ; Rohrle, O. ; Shorten, P.R. ; Soboleva, T.K. ; Clarke, R.D. ; Pullan, A.J.
Author_Institution :
Bioeng. Inst., Auckland Univ.
fDate :
Aug. 30 2006-Sept. 3 2006
Abstract :
A framework for modeling the activation of skeletal muscle is presented for studying functional electrical stimulation. A mathematical model of the cellular responses of skeletal muscle, created at AgResearch (Ruakura, New Zealand www.agresearch.co.nz), has been integrated with an anatomical, finite element model of the semitendinosus muscle, which was constructed from CT scans of the hind limb of a sheep. The tibial nerve was also constructed from digitized CT scans, and has been modeled using the Hodgkin Huxley neural model. The relevant cellular equations have been solved over these geometries. The results obtained, i.e speed of action potential propagation through the nerve and muscle, and the duration of twitch force, agree with published values
Keywords :
bioelectric phenomena; cellular biophysics; computerised tomography; finite element analysis; muscle; neuromuscular stimulation; physiological models; Hodgkin Huxley neural model; anatomical model; cellular equations; digitized CT scans; finite element model; functional electrical stimulation; hind limb; semitendinosus muscle; skeletal muscle modeling; tibial nerve; Computed tomography; Fatigue; Finite element methods; Geometry; Mathematical model; Muscles; Neurons; Protocols; Recruitment; Surface fitting;
Conference_Titel :
Engineering in Medicine and Biology Society, 2006. EMBS '06. 28th Annual International Conference of the IEEE
Conference_Location :
New York, NY
Print_ISBN :
1-4244-0032-5
Electronic_ISBN :
1557-170X
DOI :
10.1109/IEMBS.2006.259944
