Analysis of in-vivo skin anisotropy using elastic wave measurements and Bayesian modelling

TL;DR

This study uses elastic wave measurements and Bayesian analysis to characterize in vivo skin anisotropy, revealing how it varies with age, gender, and tension, with implications for medical and cosmetic applications.

Contribution

It introduces a new anisotropy measurement based on eccentricity, providing a more robust method for in vivo skin analysis compared to traditional ratios.

Findings

Skin anisotropy increases logarithmically with age.

Skin stiffness increases linearly along Langer Lines.

Gender influences skin stiffness but not anisotropy.

Abstract

In vivo skin exhibits viscoelastic, hyper-elastic and non-linear characteristics. It is under a constant non-equibiaxial tension in its natural configuration and is reinforced with oriented collagen fibers, giving rise to anisotropic behaviour. Understanding the complex mechanical behaviour of skin has relevance across many sectors including pharmaceuticals, cosmetics and surgery. However, there is a dearth of quality data characterizing human skin anisotropy in vivo. The available data is usually confined to limited population groups and/or limited angular resolution. Here, we use elastic waves travelling through the skin to obtain measurements from 78 volunteers from 3 to 93 years old. Using a Bayesian framework, we analyse the effect that age, gender and level of skin tension have on the skin anisotropy and stiffness. First, we propose a new measurement of anisotropy based on the eccentricity of angular data and conclude that it is a more robust measurement compared to the classic ``anisotropic ratio". We then find that in vivo skin anisotropy increases logarithmically with age, while the skin stiffness increases linearly along the direction of Langer Lines. We also conclude that gender does not significantly affect the skin anisotropy level, but does affect the overall stiffness, with males having stiffer skin on average. Finally, we find that skin tension significantly affects both the anisotropy and stiffness measurements, indicating that elastic wave measurements have promising applications in determining in vivo skin tension. In contrast to earlier studies, these results represent a comprehensive assessment of the variation of skin anisotropy with age and gender using a sizeable dataset and robust modern statistical analysis. This data has implications for the planning of surgical procedures and the adoption of universal cosmetic surgery practices for young or elderly patients.