• DocumentCode
    86881
  • Title

    Validating a Population Model of Tactile Mechanotransduction of Slowly Adapting Type I Afferents at Levels of Skin Mechanics, Single-Unit Response and Psychophysics

  • Author

    Gerling, Gregory J. ; Rivest, Isabelle I. ; Lesniak, Daine R. ; Scanlon, Jacob R. ; Lingtian Wan

  • Author_Institution
    Dept. of Syst. & Inf. Eng., Univ. of Virginia, Charlottesville, VA, USA
  • Volume
    7
  • Issue
    2
  • fYear
    2014
  • fDate
    April-June 2014
  • Firstpage
    216
  • Lastpage
    228
  • Abstract
    Previous models of touch have linked skin mechanics to neural firing rate, neural dynamics to action potential elicitation, and mechanoreceptor populations to psychophysical discrimination. However, no one model spans all levels. The objective of work herein is to build a multi-level, computational model of tactile neurons embedded in cutaneous skin, and then validate its predictions of skin surface deflection, single-afferent firing to indenter shift, and population response for sphere discrimination. The model includes a 3D finite element representation of the distal phalange with hyper- and visco-elastic mechanics. Distributed over its surface, a population of receptor models is comprised of bi-phasic functions to represent Merkel cells´ transformation of stress/strain to membrane current and a leaky integrate-and-fire neuronal models to generate the timing of action potentials. After including neuronal noise, the predictions of two population encoding strategies (gradient sum and euclidean distance) are compared to psychophysical discrimination of spheres. Results indicate that predicted skin surface deflection matches Srinivasan´s observations for 50 micron and 3.17 mm diameter cylinders and single-afferent responses achieve R2 = 0.81 when compared to Johnson´s recordings. Discrimination results correlate with Goodwin´s experiments, whereby 287 and 365 m-1 spheres are more discriminable than 287 and 296 m-1.
  • Keywords
    bioelectric potentials; biomechanics; biomembranes; brain models; cellular biophysics; finite element analysis; neural nets; skin; stress-strain relations; touch (physiological); viscoelasticity; 3D finite element representation; Goodwin experiments; Johnson recordings; Merkel cell transformation representation; Srinivasan observations; action potential elicitation; action potential timing generation; biphasic functions; cutaneous skin; cylinder diameter; distal phalange; euclidean distance; gradient sum; hyper-elastic mechanics; indenter shift; leaky integrate-and-fire neuronal models; mechanoreceptor population response; membrane current; multilevel computational model; neural dynamics; neural firing rate; neuronal noise; population encoding strategy predictions; psychophysical discrimination; psychophysical sphere discrimination; psychophysics; receptor model population; single-afferent firing; single-afferent responses; single-unit response; size 3.17 mm; size 50 micron; skin mechanics; skin surface deflection prediction; slowly adapting type I afferents; stress/strain transformation; tactile mechanotransduction population model validation; tactile neuron embedding; tactile neuron model; touch models; viscoelastic mechanics; Biomechanics; Finite element analysis; Haptic interfaces; Mechanoreceptors; Physics; Psychology; Skin; SAI; Tactile; biomechanics; finite element model; leaky integrate-and-fire; mechanoreceptor; neural dynamics; psychophysics; sensation; skin mechanics;
  • fLanguage
    English
  • Journal_Title
    Haptics, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    1939-1412
  • Type

    jour

  • DOI
    10.1109/TOH.2013.36
  • Filename
    6523037