An FE Simulation Study on Population Response of RA-I Mechanoreceptor to Different Widths of Square Indenter

Abstract: : Rapid adapting type-I (RA-I) receptor is one type of mechanoreceptors in the human skin. They are believed to be responsible for the detection of stimuli that produce minute skin motion (flutter, slip, microgeometric surface features). The neurophysiological experiments in the paper [J.R. Phillips et al. J. Neurophysiol., Vol. 46, pp. 1192-1203] raise a question about why the RA-I afferent (innervated into RA-I receptor) fails to represents the stimulus with the width less than 3 mm and why their response is… Show more

“…Although some very simple numerical models of tissue specimens have already been developed, they cannot study the whole process of human sensory-motor control. 15,38,39,47 This FE hand model has the potential to provide real-time neural spike information during active touch and other manipulation processes. The mechanical parameter which is related to human tactile perception such as strain energy density at the locations of mechanoreceptors can be derived to predict the neural signal.…”

Subject-Specific Finite Element Modelling of the Human Hand Complex: Muscle-Driven Simulations and Experimental Validation

“…Although some very simple numerical models of tissue specimens have already been developed, they cannot study the whole process of human sensory-motor control. 15,38,39,47 This FE hand model has the potential to provide real-time neural spike information during active touch and other manipulation processes. The mechanical parameter which is related to human tactile perception such as strain energy density at the locations of mechanoreceptors can be derived to predict the neural signal.…”

Subject-Specific Finite Element Modelling of the Human Hand Complex: Muscle-Driven Simulations and Experimental Validation

Predict Afferent Tactile Neural Signal for Artificial Nerve Based on Finite Element Human Hand Model