Abstract
Skin 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.
Highlights
Skin is the largest organ of the human body and functions as a barrier against the external environment
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
Summary
Skin is the largest organ of the human body and functions as a barrier against the external environment. The stratum corneum is composed of terminally differentiated non-viable keratinocytes, called corneocytes It has a thickness varying from 10 to 20 μm depending on body site and is the most important protection barrier. Via the dermo-epidermal junction, a basal membrane, the epidermis is connected to the underlying dermis This connective tissue is mainly composed of collagen and elastin fibers embedded in an extrafibrillar matrix. The papillary dermis is the uppermost layer, composed of loose areolar connective tissue forming fingerlike projections called papillae, which extend towards the epidermis It contains terminal networks of blood capillaries and nerve endings. The underlying reticular dermis is a thicker layer, composed of densely packed collagen and elastin fibers The presence of these fibers are important factors in the mechanical properties of human skin, providing both strength and elasticity. Underneath the dermis lies the subcutaneous tissue layer, mainly composed of adipose cells used for fat storage, and is generally not regarded as part of the skin
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