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

Diosa, Johnatan; Moreno, Ricardo; Chica, Edwin; Villarraga, Junes; Tepole, Adrián Buganza

doi:10.1371/journal.pone.0241533

Cited by 13 publications

(13 citation statements)

References 112 publications

(213 reference statements)

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“…It should be noted that to account for the effect of humidity, we only consider a change the Youngʼs modulus of the SC in this study. Though, this is consistent with the previously conducted mechanical modeling of human skin in [4,[29][30][31], in practice, a change in the humidity can also affect the chemical bonds at molecular level [66] and physiological properties of skin like lipid barriers [67]. Therefore, while our results point to the importance of humidity as a factor affecting skin friction, the question of humidity needs to be investigated further.…”

Section: Role Of Hydrationsupporting

confidence: 91%

“…Limbert and Kuhl [46] use this material model to understand the effect of compression induced wrinkling using a three-dimensional model. Recently Diosa et al [31] use this approach for three-dimensional modeling of human skin contact with a spherical indenter.…”

Section: Constitutive Modelingmentioning

confidence: 99%

“…They find that skin roughness and its layered structure indeed influence its contact behavior. Diosa et al [31] show the importance of roughness in how aging impacts the mechanical and tribological behavior of human skin using an image-based computational model. Given the randomness of roughness over skin and the complexities involved in obtaining actual skin surfaces in large numbers, representative models of rough surfaces come as a convenient tool.…”

Section: Introductionmentioning

confidence: 99%

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Fractal surface-based three-dimensional modeling to study the role of morphology and physiology in human skin friction

Roy,

Vemaganti

2024

Surf. Topogr.: Metrol. Prop.

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Human skin plays an important role in our perception of contact made throughout the day. In this work, we study the interplay of various morphological and physiological factors that dictate its contact mechanics. A hybrid computational-empirical approach is developed to model skin friction and to understand the role of roughness in contact mechanics of human skin variations in structural properties. A fractal rough surface is considered to model the skin surface. A layered three-dimensional finite element model is generated with stratum corneum, viable epidermis, and dermis which is further used to determine its mechanical response under normal loading. An empirical relationship is then used to predict the coefficient of friction. The effects of varying the Young’s modulus, roughness parameters, thickness of stratum corneum and domain size are studied. Simulations are performed for multiple realizations to quantify statistical variations. Our results show that the proposed approach can replicate several experimental findings from the literature such as the decrease in skin friction with humidity and increasing roughness. The study provides qualitative and quantitative insight into the role of roughness in the contact mechanics of human skin while accounting for the effects of micro-level interfacial phenomena.

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Section: Role Of Hydrationsupporting

confidence: 91%

Section: Constitutive Modelingmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Fractal surface-based three-dimensional modeling to study the role of morphology and physiology in human skin friction

Roy,

Vemaganti

2024

Surf. Topogr.: Metrol. Prop.

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“…The stratum corneum (SC), being the topmost layer of skin, has a major role in the contact mechanics between skin and object. Though it has the least thickness (≈20 μ m ) (Diosa, Moreno, Chica, Villarraga, & Tepole, 2021), it has a considerably higher elastic modulus compared to other layers of skin (Van Kuilenburg, Masen, & Van Der Heide, 2013; Diosa, Moreno, Chica, Villarraga, & Tepole, 2021). Further, its mechanical properties vary over a large range and humidity or water content plays a big role in determining its behavior (Kim & Yun, 2019; Dzidek, Bochereau, Johnson, Hayward, & Adams, 2017; Mojumdar, Pham, Topgaard, & Sparr, 2017; Bernard, et al, 2001; Derler, Rossi, & Rotaru, 2015; Tomlinson, Lewis, Liu, Texier, & Carré, 2011).…”

Section: Introductionmentioning

confidence: 99%

“…Among the various in-silico modelling approaches, finite element models have been extensively used over the past decade to study the biomechanics of skin (Flynn & McCormack, Simulating the wrinkling and aging of skin with a multi-layer finite element model, 2010; Leyva-Mendivil, Page, Bressloff, & Limbert, 2015; Leyva-Mendivil, Lengiewicz, Page, Bressloff, & Limbert, 2017; Santoprete & Querleux, 2014; Nandamuri, 2016; Diosa, Moreno, Chica, Villarraga, & Tepole, 2021) for a variety of applications including wrinkling, subcutaneous drug delivery, wound healing and robotics assisted surgery. Recent advancements in the development of commercial and open-source FEM packages have allowed researchers to develop robust in-silico models of skin that can a) include property variation across different skin layers b) model contact mechanics between skin and indenter for large deformations and include microscopic details of skin structure into the modelling framework.…”

Section: Introductionmentioning

confidence: 99%

RVE based Finite Element Modelling of the Contact Mechanics Between Skin and Indenter

Pardeshi,

Dingari,

Rai

2023

Preprint

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The nature of contact between human skin and external object (such as medical device, personal care device, fabric and so on) significantly influences the tactile perception and/or the functionality of the object. The contact mechanics depends strongly on the indenter properties and the mechanical properties of skin. Further, the topmost layer i.e., stratum corneum plays the most important role in tactile perception. In this study we use a representative volume element (RVE) based FEM model including the four layers of skin - stratum corneum, epidermis, dermis, and hypodermis - to simulate the contact mechanics between skin and a spherical indenter. The RVE model captures the mechanical properties of the microscopic constituents of the stratum corneum, which is the topmost layer of skin. We found that the RVE model can be used to simulate a variety of stratum corneum conditions (for example, dry and wet stratum corneum) and compositions. Using the RVE model in conjunction with an FEM model, we compute the frictional stress between skin and an indenter, as a function of stratum corneum microstructure, indentation depth, and local coefficient of friction. Both, the RVE model and the contact mechanics model predictions show good qualitative agreement with experimental findings in literature. Such studies will be very useful in in-silico design and optimization of devices that interact with skin. The current framework gives control over several parameters like skin microstructure, indenter or skin geometry and hence can be used to augment/substitute experimental testing.

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Multiscale Computational and Artificial Intelligence Models of Linear and Nonlinear Composites: A Review

Agarwal,

Pasupathy,

et al. 2024

Small Science

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Herein, state‐of‐the‐art multiscale modeling methods have been described. This research includes notable molecular, micro‐, meso‐, and macroscale models for hard (polymer, metal, yarn, fiber, fiber‐reinforced polymer, and polymer matrix composites) and soft (biological tissues such as brain white matter [BWM]) composite materials. These numerical models vary from molecular dynamics simulations to finite‐element (FE) analyses and machine learning/deep learning surrogate models. Constitutive material models are summarized, such as viscoelastic hyperelastic, and emerging models like fractional viscoelastic. Key challenges such as meshing, data variability and material nonlinearity‐driven uncertainty, limitations in terms of computational resources availability, model fidelity, and repeatability are outlined with state‐of‐the‐art models. Latest advancements in FE modeling involving meshless methods, hybrid ML and FE models, and nonlinear constitutive material (linear and nonlinear) models aim to provide readers with a clear outlook on futuristic trends in composite multiscale modeling research and development. The data‐driven models presented here are of varying length and time scales, developed using advanced mathematical, numerical, and huge volumes of experimental results as data for digital models. An in‐depth discussion on data‐driven models would provide researchers with the necessary tools to build real‐time composite structure monitoring and lifecycle prediction models.

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

Cited by 13 publications

References 112 publications

Fractal surface-based three-dimensional modeling to study the role of morphology and physiology in human skin friction

Fractal surface-based three-dimensional modeling to study the role of morphology and physiology in human skin friction

RVE based Finite Element Modelling of the Contact Mechanics Between Skin and Indenter

Multiscale Computational and Artificial Intelligence Models of Linear and Nonlinear Composites: A Review

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