The import of skin tissue dynamics in tactile sensing

Udaya B. Rongala; Andre Seyfarth; Vincent Hayward; Henrik Jörntell

doi:10.1016/j.xcrp.2024.101943

The import of skin tissue dynamics in tactile sensing

Udaya B. Rongala, Andre Seyfarth, Vincent Hayward, Henrik Jörntell

Neural Basis of Sensorimotor Control

Research output: Contribution to journal › Article › peer-review

Abstract

The mammalian skin is a densely innervated soft tissue where neural mechanoreceptors embedded in the skin report to the brain the mechanical events arising at its surface. Up to now, models of the transformations of these events into neural signals relied on quasi-static or viscoelastic mechanical models of the skin tissue. Here we developed a model, which, in addition to elasticity and viscosity, accounted for mass to accurately reproduce the propagation of mechanical waves observed in vivo. Skin dynamics converted sensory inputs into rapidly evolving spatiotemporal patterns that magnified the information made available to a population of mechanoreceptors. Accounting for dynamics in the skin tissue thus greatly enhanced the separability of tactile inputs and was efficient for a large range of mechanical parameter values. This advantage vanished when these parameters were set to approximate the quasi-static or viscoelastic cases.

Original language	English
Article number	101943
Journal	Cell Reports Physical Science
Volume	5
Issue number	5
DOIs	https://doi.org/10.1016/j.xcrp.2024.101943
Publication status	Published - 2024 May

Subject classification (UKÄ)

Medical Laboratory Technologies

Free keywords

haptics
mechanoreceptor
neurophysiology
principal component analysis
sensory information
skin tissue dynamics
spiking
tactile
tactile coding

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10.1016/j.xcrp.2024.101943

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title = "The import of skin tissue dynamics in tactile sensing",

abstract = "The mammalian skin is a densely innervated soft tissue where neural mechanoreceptors embedded in the skin report to the brain the mechanical events arising at its surface. Up to now, models of the transformations of these events into neural signals relied on quasi-static or viscoelastic mechanical models of the skin tissue. Here we developed a model, which, in addition to elasticity and viscosity, accounted for mass to accurately reproduce the propagation of mechanical waves observed in vivo. Skin dynamics converted sensory inputs into rapidly evolving spatiotemporal patterns that magnified the information made available to a population of mechanoreceptors. Accounting for dynamics in the skin tissue thus greatly enhanced the separability of tactile inputs and was efficient for a large range of mechanical parameter values. This advantage vanished when these parameters were set to approximate the quasi-static or viscoelastic cases.",

keywords = "haptics, mechanoreceptor, neurophysiology, principal component analysis, sensory information, skin tissue dynamics, spiking, tactile, tactile coding",

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AU - Rongala, Udaya B.

AU - Seyfarth, Andre

AU - Hayward, Vincent

AU - Jörntell, Henrik

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N2 - The mammalian skin is a densely innervated soft tissue where neural mechanoreceptors embedded in the skin report to the brain the mechanical events arising at its surface. Up to now, models of the transformations of these events into neural signals relied on quasi-static or viscoelastic mechanical models of the skin tissue. Here we developed a model, which, in addition to elasticity and viscosity, accounted for mass to accurately reproduce the propagation of mechanical waves observed in vivo. Skin dynamics converted sensory inputs into rapidly evolving spatiotemporal patterns that magnified the information made available to a population of mechanoreceptors. Accounting for dynamics in the skin tissue thus greatly enhanced the separability of tactile inputs and was efficient for a large range of mechanical parameter values. This advantage vanished when these parameters were set to approximate the quasi-static or viscoelastic cases.

AB - The mammalian skin is a densely innervated soft tissue where neural mechanoreceptors embedded in the skin report to the brain the mechanical events arising at its surface. Up to now, models of the transformations of these events into neural signals relied on quasi-static or viscoelastic mechanical models of the skin tissue. Here we developed a model, which, in addition to elasticity and viscosity, accounted for mass to accurately reproduce the propagation of mechanical waves observed in vivo. Skin dynamics converted sensory inputs into rapidly evolving spatiotemporal patterns that magnified the information made available to a population of mechanoreceptors. Accounting for dynamics in the skin tissue thus greatly enhanced the separability of tactile inputs and was efficient for a large range of mechanical parameter values. This advantage vanished when these parameters were set to approximate the quasi-static or viscoelastic cases.

KW - haptics

KW - mechanoreceptor

KW - neurophysiology

KW - principal component analysis

KW - sensory information

KW - skin tissue dynamics

KW - spiking

KW - tactile

KW - tactile coding

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DO - 10.1016/j.xcrp.2024.101943

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JO - Cell Reports Physical Science

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The import of skin tissue dynamics in tactile sensing

Abstract

Subject classification (UKÄ)

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