Characterization of the mechanical properties of a dermal equivalent compared with human skin in vivo by indentation and static friction tests

Characterization of the mechanical properties of a dermal equivalent compared with human skin in vivo by indentation and static friction tests

The study of changes in skin structure with age is becoming all the more important with the increase in life. The atrophy that occurs during aging is accompanied by more profound changes, with a loss of organization within the elastic collagen network and alterations in the basal elements. The aim o...

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Bibliographic Details
Published in:Skin research and technology Vol. 15; no. 1; p. 68
Main Authors: Zahouani, H, Pailler-Mattei, C, Sohm, B, Vargiolu, R, Cenizo, V, Debret, R
Format: Journal Article
Language:English
Published: England 01-02-2009
Subjects:
Aged
Animals
Artificial Organs
Biomimetics - instrumentation
Cattle
Collagen - chemistry
Computer Simulation
Dermis - physiology
Elastic Modulus - physiology
Equipment Design
Equipment Failure Analysis
Female
Friction
Hardness
Hardness Tests - instrumentation
Hardness Tests - methods
Humans
Materials Testing
Middle Aged
Models, Biological
Skin Physiological Phenomena
Skin Tests - instrumentation
Skin Tests - methods
Stress, Mechanical
Viscosity
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Summary:The study of changes in skin structure with age is becoming all the more important with the increase in life. The atrophy that occurs during aging is accompanied by more profound changes, with a loss of organization within the elastic collagen network and alterations in the basal elements. The aim of this study is to present a method to determine the mechanical properties of total human skin in vivo compared with dermal equivalents (DEs) using indentation and static friction tests. A new bio-tribometer working at a low contact pressure for the characterization the mechanical properties of the skin has been developed. This device, based on indentation and static friction tests, also allows to characterize the skin in vivo and reconstructed DEs in a wide range of light contact forces, stress and strain. This original bio-tribometer shows the ability to assess the skin elasticity and friction force in a wide range of light normal load (0.5-2 g) and low contact pressure (0.5-2 kPa). The results obtained by this approach show identical values of the Young's modulus E(*) and the shear modulus G(*) of six DEs obtained from a 62-year-old subject (E(*)=8.5+/-1.74 kPa and G(*)=3.3+/-0.46 kPa) and in vivo total skin of 20 subjects aged 55 to 70 years (E(*)=8.3+/-2.1 kPa, G(*)=2.8+/-0.8 kpa).
ISSN:1600-0846
DOI:10.1111/j.1600-0846.2008.00329.x