Changes in the three-dimensional microscale topography of human skin with aging impact its mechanical and tribological behavior.

Human skin enables interaction with diverse materials every day and at all times. The ability to grasp objects, feel textures, and perceive the environment depends on the mechanical behavior, complex structure, and microscale topography of human skin. At the same time, abrasive interactions, such as...

Full description

Bibliographic Details
Main Authors: Juan G Diosa, Ricardo Moreno, Edwin L Chica, Junes A Villarraga, Adrian B Tepole
Format: Article
Language:English
Published: Public Library of Science (PLoS) 2021-01-01
Series:PLoS ONE
Online Access:https://doi.org/10.1371/journal.pone.0241533
id doaj-2ab135a3ef4d448a814c289c4e450526
record_format Article
spelling doaj-2ab135a3ef4d448a814c289c4e4505262021-07-24T04:32:56ZengPublic Library of Science (PLoS)PLoS ONE1932-62032021-01-01167e024153310.1371/journal.pone.0241533Changes in the three-dimensional microscale topography of human skin with aging impact its mechanical and tribological behavior.Juan G DiosaRicardo MorenoEdwin L ChicaJunes A VillarragaAdrian B TepoleHuman skin enables interaction with diverse materials every day and at all times. The ability to grasp objects, feel textures, and perceive the environment depends on the mechanical behavior, complex structure, and microscale topography of human skin. At the same time, abrasive interactions, such as sometimes occur with prostheses or textiles, can damage the skin and impair its function. Previous theoretical and computational efforts have shown that skin's surface topography or microrelief is crucial for its tribological behavior. However, current understanding is limited to adult surface profiles and simplified two-dimensional simulations. Yet, the skin has a rich set of features in three dimensions, and the geometry of skin is known to change with aging. Here we create a numerical model of a dynamic indentation test to elucidate the effect of changes in microscale topography with aging on the skin's response under indentation and sliding contact with a spherical indenter. We create three different microrelief geometries representative of different ages based on experimental reports from the literature. We perform the indentation and sliding steps, and calculate the normal and tangential forces on the indenter as it moves in three distinct directions based on the characteristic skin lines. The model also evaluates the effect of varying the material parameters. Our results show that the microscale topography of the skin in three dimensions, together with the mechanical behavior of the skin layers, lead to distinctive trends on the stress and strain distribution. The major finding is the increasing role of anisotropy which emerges from the geometric changes seen with aging.https://doi.org/10.1371/journal.pone.0241533
collection DOAJ
language English
format Article
sources DOAJ
author Juan G Diosa
Ricardo Moreno
Edwin L Chica
Junes A Villarraga
Adrian B Tepole
spellingShingle Juan G Diosa
Ricardo Moreno
Edwin L Chica
Junes A Villarraga
Adrian B Tepole
Changes in the three-dimensional microscale topography of human skin with aging impact its mechanical and tribological behavior.
PLoS ONE
author_facet Juan G Diosa
Ricardo Moreno
Edwin L Chica
Junes A Villarraga
Adrian B Tepole
author_sort Juan G Diosa
title Changes in the three-dimensional microscale topography of human skin with aging impact its mechanical and tribological behavior.
title_short Changes in the three-dimensional microscale topography of human skin with aging impact its mechanical and tribological behavior.
title_full Changes in the three-dimensional microscale topography of human skin with aging impact its mechanical and tribological behavior.
title_fullStr Changes in the three-dimensional microscale topography of human skin with aging impact its mechanical and tribological behavior.
title_full_unstemmed Changes in the three-dimensional microscale topography of human skin with aging impact its mechanical and tribological behavior.
title_sort changes in the three-dimensional microscale topography of human skin with aging impact its mechanical and tribological behavior.
publisher Public Library of Science (PLoS)
series PLoS ONE
issn 1932-6203
publishDate 2021-01-01
description Human skin enables interaction with diverse materials every day and at all times. The ability to grasp objects, feel textures, and perceive the environment depends on the mechanical behavior, complex structure, and microscale topography of human skin. At the same time, abrasive interactions, such as sometimes occur with prostheses or textiles, can damage the skin and impair its function. Previous theoretical and computational efforts have shown that skin's surface topography or microrelief is crucial for its tribological behavior. However, current understanding is limited to adult surface profiles and simplified two-dimensional simulations. Yet, the skin has a rich set of features in three dimensions, and the geometry of skin is known to change with aging. Here we create a numerical model of a dynamic indentation test to elucidate the effect of changes in microscale topography with aging on the skin's response under indentation and sliding contact with a spherical indenter. We create three different microrelief geometries representative of different ages based on experimental reports from the literature. We perform the indentation and sliding steps, and calculate the normal and tangential forces on the indenter as it moves in three distinct directions based on the characteristic skin lines. The model also evaluates the effect of varying the material parameters. Our results show that the microscale topography of the skin in three dimensions, together with the mechanical behavior of the skin layers, lead to distinctive trends on the stress and strain distribution. The major finding is the increasing role of anisotropy which emerges from the geometric changes seen with aging.
url https://doi.org/10.1371/journal.pone.0241533
work_keys_str_mv AT juangdiosa changesinthethreedimensionalmicroscaletopographyofhumanskinwithagingimpactitsmechanicalandtribologicalbehavior
AT ricardomoreno changesinthethreedimensionalmicroscaletopographyofhumanskinwithagingimpactitsmechanicalandtribologicalbehavior
AT edwinlchica changesinthethreedimensionalmicroscaletopographyofhumanskinwithagingimpactitsmechanicalandtribologicalbehavior
AT junesavillarraga changesinthethreedimensionalmicroscaletopographyofhumanskinwithagingimpactitsmechanicalandtribologicalbehavior
AT adrianbtepole changesinthethreedimensionalmicroscaletopographyofhumanskinwithagingimpactitsmechanicalandtribologicalbehavior
_version_ 1721284213460697088