Viscoelastic Characterization of the Primate Finger Pad In Vivo by Microstep Indentation and Three-Dimensional Finite Element Models for Tactile Sensation Studies

Kumar, Smriti; Liu, Gang; Schloerb, David W.; Srinivasan, Mandayam A.

doi:10.1115/1.4029985

Cited by 18 publications

(20 citation statements)

References 19 publications

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“…Three-dimensional (3D) models were also proposed under a flat load, a sharp wedge [11] and a line load [22]. For example, a 3D FE model was developed to predict the temporal force response of fingertip under both a line load and a cylinder load surface deflection [6].…”

Section: Related Workmentioning

confidence: 99%

“…A comprehensive understanding of human fingertip biomechanics is essential prior to full exploitation of its most potential in both clinical and industrial environment. Most existing studies concerning neural reaction properties under the fingertip skin only conduct experiments under a small indentation depth of 0~0.2 mm to 0.8~2.5 mm [6,7], while large deformations that may occur in the context of hand prostheses were not taken into account. Therefore, this study aims at achieving a quantitative characterisation of human fingertip's mechanical behaviour for the potential application of tactile rehabilita-tion in hand prostheses.…”

Section: Introductionmentioning

confidence: 99%

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Haptics model for human fingertips based on gaussian distribution

Fang

Zhou

et al. 2019

IFS

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Functionality and cosmetics are two concerns for future hand prosthesis development and they both can be improved by a combination with artificial soft materials which can mimic human skin. To bridge the gap between the human and artificial side, it is essential to have a comprehensive understanding of the human skin's biomechanics, especially the fingertip's hapticsrelated mechanism. Available studies characterise the mechanical behaviour of human fingertip only by deterministic models based on either statistical data analysis or fingertip structure/viscoelasticity analysis. To take the force uncertainty into consideration, this paper proposes a novel probability-based haptics model, which includes two parts: a force prediction model to obtain the most possible contact force according to the indentation depth, and a probabilistic model based on Gaussian distribution to describe the force uncertainty. Experiments were conducted by pressing subjects' index fingertips against a cone-shape probe with the measurement of the contact force and the indentation depth under a wide range of 0~5 mm. Four types of non-linear regression models and the Gaussian distribution model are applied for model training and validation. Experiment results reveal that the contact force varying with the indentation depth presents the characteristics of non-linearity, dispersion, and individual difference. Model testing results confirm the effectiveness of the haptics model on force prediction and force uncertainty description. An example of its application on a virtual hand of a rehabilitation system is demonstrated.

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Section: Related Workmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Haptics model for human fingertips based on gaussian distribution

Fang

Zhou

et al. 2019

IFS

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show abstract

“…Since it is impossible to capture the full mechanical response of human skin in one single experiment, different types of experiments have been performed to partially capture this response. Most studies involved experiments on in vivo human skin, comprising uniaxial tensile (Mahmud et al, 2012;Delalleau et al, 2008b;Gambarotta et al, 2005), multiaxial tensile (Flynn et al, 2011(Flynn et al, , 2011(Flynn et al, , 2013Khatyr et al, 2004;Kvistedal and Nielsen, 2009), suction (Khatyr et al, 2006;Delalleau et al, 2008aDelalleau et al, , 2011Delalleau et al, , 2012Hendriks et al, 2003) and indentation (Groves et al, 2012;Delalleau et al, 2006;Kumar et al, 2015) experiments. Although it is preferable to measure skin in its natural environment, in vivo measurements have limitations for several reasons.…”

Section: Introductionmentioning

confidence: 99%

“…Other constitutive models described the mechanical behavior as linear elastic (Delalleau et al, 2006), nonlinear (hyper)elastic using Ogden (Groves et al, 2012(Groves et al, , 2013Jor et al, 2011;Li and Xiaoyu, 2016;Evans, 2009;Flynn et al, 2011Flynn et al, , 2011Karimi et al, 2015;Mahmud et al, 2012;Lapeer et al, 2010;Limbert, 2011), Mooney-Rivlin (Flynn et al, 2013;Hendriks et al, 2003), (extended) Neo-Hookean (Delalleau et al, 2008a(Delalleau et al, , 2011(Delalleau et al, , 2012, Kalman filters (Delalleau et al, 2008b), Tong-Fung (Kvistedal and Nielsen, 2009;Gambarotta et al, 2005) or viscoelastic (Lokshin and Lanir, 2009a;Khatyr et al, 2004;Holt et al, 2008;Bischoff, 2006;Karimi et al, 2016;Kumar et al, 2015). The necessity to capture a certain level of mechanical complexity with a constitutive model is dependent on the application.…”

Section: Introductionmentioning

confidence: 99%

A model of human skin under large amplitude oscillatory shear

Soetens

Vijven

Bader

et al. 2018

Journal of the Mechanical Behavior of Biomedical Materials

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A B S T R A C TSkin mechanics is of importance in various fields of research when accurate predictions of the mechanical response of skin is essential. This study aims to develop a new constitutive model for human skin that is capable of describing the heterogeneous, nonlinear viscoelastic mechanical response of human skin under shear deformation. This complex mechanical response was determined by performing large amplitude oscillatory shear (LAOS) experiments on ex vivo human skin samples. It was combined with digital image correlation (DIC) on the cross-sectional area to assess heterogeneity. The skin is modeled as a one-dimensional layered structure, with every sublayer behaving as a nonlinear viscoelastic material. Heterogeneity is implemented by varying the stiffness with skin depth. Using an iterative parameter estimation method all model parameters were optimized simultaneously. The model accurately captures strain stiffening, shear thinning, softening effect and nonlinear viscous dissipation, as experimentally observed in the mechanical response to LAOS. The heterogeneous properties described by the model were in good agreement with the experimental DIC results. The presented mathematical description forms the basis for a future constitutive model definition that, by implementation in a finite element method, has the capability of describing the full 3D mechanical behavior of human skin.

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“…One might think to control force and then divide by the area of the tip to get "nominal pressure" and indeed this surface quantity, which Ge and Khalsa referred to as compressive stress, better correlates with firing rate than displacement or force [75]. [9][10][11]27,[77][78][79]. However, maximum compressive stress is invariant to rotations, unlike others such as maximum horizontal or vertical stress, which were excluded from analysis following past studies [27].…”

Section: Discussionmentioning

confidence: 99%

Computationally Modeling the Impact of Measured Variance in Skin Mechanics on Neural Responses to Touch Stimuli

Wang¹

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We rely on our sense of touch to obtain information from the external environment with which we interact. Upon touching an object, the distal mechanical stimulus propagates through the skin's layers toward the end organs of cutaneous afferents that initiate neural responses. While the encoding of various stimuli has been thoroughly investigated in prior studies, the impact of the skin's mechanics remains vastly understudied. In particular, while we know that the skin undergoes natural cycles of remodeling, we do not know how remodeling impacts the skin's thickness and elasticity and what impacts those might have on the neural response and neural sensitivity between afferents. In the first aim, we performed uniaxial compression tests to measure the viscoelastic properties of 139 mouse skin specimens while also varying stretch level and rate. This is the first effort to do such a detailed characterization at different stages of the hair cycle. Over the population measured, we observed the skin's thickness and viscoelasticity to be highly variable, yet found systematic correlations between the viscoelastic parameters and skin thickness and applied stretch. Specifically, residual stress ratio positively correlates with skin thickness and stretch, and relaxation time constants negative correlates with strain rates. In the second aim, we used the population of measurements to build finite element models to closely examine the effect of thickness-dependent viscoelasticity on the propagation of internal deformation toward the end orangs of slowly adapting type I (SAI) afferents. In simulating the observed changes to the skin's mechanics, we find that there can be large variance in stresses and strains near the locations of end organs, which might lead to large variance in firing sensitivity. However, variance in internal deformation is significantly reduced when the stimulus tip is controlled by surface pressure and compressive stress is measured near the end organs. The combined results of the two aims indicate that the skin can reliably convey surface stimulus information to locations of tactile receptors even amidst changes in skin's structure. During such 2 changes, stimulus control by surface pressure may be more naturalistic and optimal and underlie how animals actively explore the tactile environment.

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Viscoelastic Characterization of the Primate Finger Pad In Vivo by Microstep Indentation and Three-Dimensional Finite Element Models for Tactile Sensation Studies

Cited by 18 publications

References 19 publications

Haptics model for human fingertips based on gaussian distribution

Haptics model for human fingertips based on gaussian distribution

A model of human skin under large amplitude oscillatory shear

Computationally Modeling the Impact of Measured Variance in Skin Mechanics on Neural Responses to Touch Stimuli

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