Characterising the Anisotropic Mechanical Properties of Excised Human Skin

TL;DR

This study characterizes the anisotropic mechanical properties of excised human skin, revealing how location and collagen fiber orientation influence tensile strength, elasticity, and energy absorption, with implications for modeling skin behavior.

Contribution

It provides detailed quantitative data on skin's anisotropic mechanical properties and links these to collagen fiber orientation and anatomical location.

Findings

Mechanical properties depend on Langer line orientation.

Location on the back affects tensile strength and elasticity.

Collagen fiber orientation correlates with Langer lines.

Abstract

The mechanical properties of skin are important for a number of applications including surgery, dermatology, impact biomechanics and forensic science. In this study we have investigated the influence of location and orientation on the deformation characteristics of 56 samples of excised human skin. Uniaxial tensile tests were carried out at a strain rate of 0.012s$^{-1}$ on skin from the back. Digital Image Correlation was used for 2D strain measurement and a histological examination of the dermis was also performed. The mean ultimate tensile strength (UTS) was 21.6$\pm$8.4MPa, the mean failure strain 54$\pm$17%, the mean initial slope 1.18$\pm$0.88MPa, the mean elastic modulus 83.3$\pm$34.9MPa and the mean strain energy was 3.6$\pm$1.6MJ/m$^3$. A multivariate analysis of variance has shown that these mechanical properties of skin are dependent upon the orientation of Langer lines (P$<$0.0001-P=0.046). The location of specimens on the back was also found to have a significant effect on the UTS (P =0.0002), the elastic modulus (P=0.001) and the strain energy (P=0.0052). The histological investigation concluded that there is a definite correlation between the orientation of Langer Lines and the preferred orientation of collagen fibres in the dermis (P$<$0.001). The data obtained in this study will provide essential information for those wishing to model the skin using a structural constitutive model.