Title :
Simulations of Distributed Voltages in Full-Body Biomodels Using Symmetric Factorization With Massively Parallel Solvers in Response to External Pulsing
Author :
Mishra, Ashutosh ; Joshi, Ravindra P.
Author_Institution :
Dept. of Electr. Eng., Norfolk State Univ., Norfolk, VA
Abstract :
An improved model of our previous work is presented to compute spatial electric potentials in whole body biomodels. This is a distributed modeling scheme that employs symmetric factorization to decrease the memory requirement, reduce run-time overhead, and facilitate analyses of significantly larger biomodels. Such improved full-body modeling will help in the study of bioresponses to electrical stimuli in a more accurate, realistic, and comprehensive manner. For example, the voltages at various sites and tissue locations could be evaluated to probe the role of nanosecond high-intensity pulsed electric fields in blocking neural action potential propagation. Here, it is shown in rat and monkey biomodels that tissue and/or cell functionality at the spinal and thoracic regions is most likely to be affected in keeping with some recent experiments.
Keywords :
bioelectric potentials; biological tissues; cellular biophysics; medical computing; physiological models; Cholesky factorization; bioelectrics; cell functionality; distributed voltage simulations; electrical stimuli; full-body biomodels; monkey biomodel; neural action potential propagation; parallel computation; rat biomodel; spatial electric potentials; symmetric factorization; tissue functionality; Bioelectric phenomena; Computational modeling; Concurrent computing; Distributed control; Electric potential; Muscles; Neoplasms; Spinal cord injury; Symmetric matrices; Voltage; Bioelectrics; Cholesky factorization; full-body modeling; parallel computation; simulation;
Journal_Title :
Plasma Science, IEEE Transactions on
DOI :
10.1109/TPS.2008.2001066
