Abstract
The skin is the largest organ in the human body and serves various functions, including mechanical protection and mechanosensation. Yet, even though skin’s biomechanics are attributed to two main layers—epidermis and dermis—computational models have often treated this tissue as a thin homogeneous material or, when considering multiple layers, have ignored the most prominent heterogeneities of skin seen at the mesoscale. Here, we create finite element models of representative volume elements (RVEs) of skin, including the three-dimensional variation of the interface between the epidermis and dermis as well as considering the presence of hair follicles. The sinusoidal interface, which approximates the anatomical features known as Rete ridges, does not affect the homogenized mechanical response of the RVE but contributes to stress concentration, particularly at the valleys of the Rete ridges. The stress profile is three-dimensional due to the skin’s anisotropy, leading to high-stress bands connecting the valleys of the Rete ridges through one type of saddle point. The peaks of the Rete ridges and the other class of saddle points of the sinusoidal surface form a second set of low-stress bands under equi-biaxial loading. Another prominent feature of the heterogeneous stress pattern is a switch in the stress jump across the interface, which becomes lower with respect to the flat interface at increasing deformations. These features are seen in both tension and shear loading. The RVE with the hair follicle showed strains concentrating at the epidermis adjacent to the hair follicle, the epithelial tissue surrounding the hair right below the epidermis, and the bulb or base region of the hair follicle. The regions of strain concentration near the hair follicle in equi-biaxial and shear loading align with the presence of distinct mechanoreceptors in the skin, except for the bulb or base region. This study highlights the importance of skin heterogeneities, particularly its potential mechanophysiological role in the sense of touch and the prevention of skin delamination.
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References
Amaied E, Vargiolu R, Bergheau JM, Zahouani H (2015) Aging effect on tactile perception: experimental and modelling studies. Wear 332:715–724
Annaidh AN, Bruyère K, Destrade M, Gilchrist MD, Otténio M (2012) Characterization of the anisotropic mechanical properties of excised human skin. J Mech Behav Biomed Mater 5(1):139–148
Bai L, Lehnert BP, Liu J, Neubarth NL, Dickendesher TL, Nwe PH, Cassidy C, Woodbury CJ, Ginty DD (2015) Genetic identification of an expansive mechanoreceptor sensitive to skin stroking. Cell 163(7):1783–1795
Balbi V, Ciarletta P (2013) Morpho-elasticity of intestinal villi. J R Soc Interface 10(82):20130109
Berkey CA, Elsafty O, Riggs MM, Dauskardt RH (2022) Characterization and modeling of partial-thickness cutaneous injury from debris-simulating kinetic projectiles. Commun Eng 1(1):33
Bouten CV, Oomens CW, Baaijens FP, Bader DL (2003) The etiology of pressure ulcers: skin deep or muscle bound? Arch Phys Med Rehabil 84(4):616–619
Boyle CJ, Plotczyk M, Villalta SF, Patel S, Hettiaratchy S, Masouros SD, Masen MA, Higgins CA (2019) Morphology and composition play distinct and complementary roles in the tolerance of plantar skin to mechanical load. Sci Adv 5(10):eaay0244
Buffoli B, Rinaldi F, Labanca M, Sorbellini E, Trink A, Guanziroli E, Rezzani R, Rodella LF (2014) The human hair: from anatomy to physiology. Int J Dermatol 53(3):331–341
Chen S, Ní Annaidh A, Roccabianca S (2020) A microstructurally inspired constitutive model for skin mechanics. Biomech Model Mechanobiol 19:275–289
Ciarletta P, Amar MB (2012) Papillary networks in the dermal-epidermal junction of skin: a biomechanical model. Mech Res Commun 42:68–76
Cotterell B, Rice J (1980) Slightly curved or kinked cracks. Int J Fract 16:155–169
Diosa JG, Moreno R, Chica EL, Villarraga JA, Tepole AB (2021) Changes in the three-dimensional microscale topography of human skin with aging impact its mechanical and tribological behavior. Plos one 16(7):e0241533
Flynn C, McCormack BA (2010) Simulating the wrinkling and aging of skin with a multi-layer finite element model. J Biomech 43(3):442–448
Geerligs M, Van Breemen L, Peters G, Ackermans P, Baaijens F, Oomens C (2011) In vitro indentation to determine the mechanical properties of epidermis. J Biomech 44(6):1176–1181
Gerhardt LC, Strässle V, Lenz A, Spencer ND, Derler S (2008) Influence of epidermal hydration on the friction of human skin against textiles. J R Soc Interface 5(28):1317–1328
Groves RB, Coulman S, Birchall JC, Evans SL (2012) Quantifying the mechanical properties of human skin to optimise future microneedle device design. Comput Methods Biomech Biomed Engin 15(1):73–82
Hirsch F, Kästner M (2017) Microscale simulation of adhesive and cohesive failure in rough interfaces. Eng Fract Mech 178:416–432
Horch K, Tuckett R, Burgess P (1977) A key to the classification of cutaneous mechanoreceptors. J Investig Dermatol 69(1):75–82
Hu Z, Li G, Xie H, Hua T, Chen P, Huang F (2010) Measurement of young’s modulus and Poisson’s ratio of human hair using optical techniques. In: Fourth International Conference on Experimental Mechanics, vol. 7522, pp. 773–781. SPIE
Iriyama S, Yasuda M, Nishikawa S, Takai E, Hosoi J, Amano S (2020) Decrease of laminin-511 in the basement membrane due to photoaging reduces epidermal stem/progenitor cells. Sci Rep 10(1):1–10
Janes LE, Ledwon JK, Vaca EE, Turin SY, Lee T, Tepole AB, Bae H, Gosain AK (2020) Modeling tissue expansion with isogeometric analysis: skin growth and tissue level changes in the porcine model. Plast Reconstr Surg 146(4):792–798
Jenkins BA, Lumpkin EA (2017) Developing a sense of touch. Development 144(22):4078–4090
Jensen KB, Watt FM (2006) Single-cell expression profiling of human epidermal stem and transit-amplifying cells: Lrig1 is a regulator of stem cell quiescence. Proc Natl Acad Sci 103(32):11958–11963
Jor JW, Parker MD, Taberner AJ, Nash MP, Nielsen PM (2013) Computational and experimental characterization of skin mechanics: identifying current challenges and future directions. Wiley Interdiscip Rev Syst Biol Med 5(5):539–556
Kaurin D, Bal PK, Arroyo M (2022) Peeling dynamics of fluid membranes bridged by molecular bonds: moving or breaking. J R Soci Interface 19(191):20220183
Kendall MA, Chong YF, Cock A (2007) The mechanical properties of the skin epidermis in relation to targeted gene and drug delivery. Biomaterials 28(33):4968–4977
Kuehn ED, Meltzer S, Abraira VE, Ho CY, Ginty DD (2019) Tiling and somatotopic alignment of mammalian low-threshold mechanoreceptors. Proc Natl Acad Sci 116(19):9168–9177
Langton AK, Graham HK, Griffiths CE, Watson RE (2019) Ageing significantly impacts the biomechanical function and structural composition of skin. Exp Dermatol 28(8):981–984
Lanir Y (1983) Constitutive equations for fibrous connective tissues. J Biomech 16(1):1–12
Larose AE, Dakiw-Piaceski A, Barbier MA, Larouche D, Gauvin R, Caruso M, Pope E, Germain L (2020) Peel test to assess the adhesion strength of the dermal-epidermal junction in tissue-engineered skin. Tissue Eng Part C Methods 26(3):180–189
Ledwon JK, Applebaum SA, Progri B, Vignesh O, Gutowski KS, Chang AB, Tepole AB, Gosain AK (2022) Biological cover mitigates disruption of the dermal structure in mechanically expanded skin in a porcine model. Int J Mol Sci 23(21):13091
Li L, Ginty DD (2014) The structure and organization of lanceolate mechanosensory complexes at mouse hair follicles. Elife 3:e01901
Limbert G (2017) Mathematical and computational modelling of skin biophysics: a review. Proc R Soc A Math Phys Eng Sci 473(2203):20170257
Limbert G, Kuhl E (2018) On skin microrelief and the emergence of expression micro-wrinkles. Soft Matter 14(8):1292–1300
Logozzo S, Valigi MC, Malvezzi M (2022) Modelling the human touch: a basic study for haptic technology. Tribol Int 166:107352
Lynch B, Bonod-Bidaud C, Ducourthial G, Affagard JS, Bancelin S, Psilodimitrakopoulos S, Ruggiero F, Allain JM, Schanne-Klein MC (2017) How aging impacts skin biomechanics: a multiscale study in mice. Sci Rep 7(1):13750
McGrath J, Eady R, Pope F (2004) Anatomy and organization of human skin. Rook’s Textb Dermatol 1:3
Meador WD, Sugerman GP, Story HM, Seifert AW, Bersi MR, Tepole AB, Rausch MK (2020) The regional-dependent biaxial behavior of young and aged mouse skin: a detailed histomechanical characterization, residual strain analysis, and constitutive model. Acta Biomater 101:403–413
Müller B, Elrod J, Pensalfini M, Hopf R, Distler O, Schiestl C, Mazza E (2018) A novel ultra-light suction device for mechanical characterization of skin. PloS one 13(8):e0201440
Nemat-Nasser S, Hori M (2013) Micromechanics: overall properties of heterogeneous materials. Elsevier, Amsterdam
Ní Annaidh A, Bruyère K, Destrade M, Gilchrist MD, Maurini C, Otténio M, Saccomandi G (2012) Automated estimation of collagen fibre dispersion in the dermis and its contribution to the anisotropic behaviour of skin. Ann Biomed Eng 40(8):1666–1678
Ovadia J, Nie Q (2013) Stem cell niche structure as an inherent cause of undulating epithelial morphologies. Biophys J 104(1):237–246
Pissarenko A, Meyers MA (2020) The materials science of skin: analysis, characterization, and modeling. Progress Mater Sci 110:100634
Rahimi E, Gomez H, Ardekani AM (2022) Transport and distribution of biotherapeutics in different tissue layers after subcutaneous injection. Int J Pharm 626:122125
Sachs D, Wahlsten A, Kozerke S, Restivo G, Mazza E (2021) A biphasic multilayer computational model of human skin. Biomech Model Mechanobiol 20:969–982
Saeb S, Steinmann P, Javili A (2016) Aspects of computational homogenization at finite deformations: a unifying review from reuss’ to Voigt’s bound. Appl Mech Rev 68(5):050801
Schlüter H, Stark HJ, Sinha D, Boukamp P, Kaur P (2013) Wif1 is expressed by stem cells of the human interfollicular epidermis and acts to suppress keratinocyte proliferation. J Invest Dermatol 133(6):1669
Shen Z, Sun L, Liu Z, Li M, Cao Y, Han L, Wang J, Wu X, Sang S (2022) Rete ridges: morphogenesis, function, regulation, and reconstruction. Acta Biomater 155:19
Sree V, Zhong X, Bilionis I, Ardekani A, Tepole AB (2023) Optimizing autoinjector devices using physics-based simulations and gaussian processes. J Mech Behav Biomed Mater 140:105695
Sree VD, Toaquiza-Tubon JD, Payne J, Solorio L, Tepole AB (2023) Damage and fracture mechanics of porcine subcutaneous tissue under tensile loading. Ann Biomed Eng 51:2056
Tonge TK, Atlan LS, Voo LM, Nguyen TD (2013) Full-field bulge test for planar anisotropic tissues: Part i-experimental methods applied to human skin tissue. Acta Biomater 9(4):5913–5925
Vogt A, Hadam S, Heiderhoff M, Audring H, Lademann J, Sterry W, Blume-Peytavi U (2007) Morphometry of human terminal and vellus hair follicles. Exp Dermatol 16(11):946–950
Wahlsten A, Pensalfini M, Stracuzzi A, Restivo G, Hopf R, Mazza E (2019) On the compressibility and poroelasticity of human and murine skin. Biomech Model Mechanobiol 18:1079–1093
Wang S, Demirci N, Holland MA (2021) Numerical investigation of biomechanically coupled growth in cortical folding. Biomech Model Mechanobiol 20:555–567
Webb A, Li A, Kaur P (2004) Location and phenotype of human adult keratinocyte stem cells of the skin. Differentiation 72(8):387–395
Whitting DA, Blume-Peytavi U, Tosti A, Trüeb RM (2008) Hair growth and disorders. Springer, Berlin
Willsteed E, Bhogal B, Das A, Bekir S, Wojnarowska F, Black M, Mckee P (1991) An ultrastructural comparison of dermo-epidermal separation techniques. J Cutan Pathol 18(1):8–12
Woo SH, Lumpkin EA, Patapoutian A (2015) Merkel cells and neurons keep in touch. Trends Cell Biol 25(2):74–81
Yazdi SJM, Baqersad J (2022) Mechanical modeling and characterization of human skin: a review. J Biomech 130:110864
Zavattieri PD, Hector LG Jr, Bower AF (2007) Determination of the effective mode-i toughness of a sinusoidal interface between two elastic solids. Int J Fract 145(3):167–180
Zhao Y, Feng B, Lee J, Lu N, Pierce D (2020) A multi-layered computational model for wrinkling of human skin predicts aging effects. J Mech Behav Biomed Mater 103:103552
Zhao Y, Feng B, Lee J, Lu N, Pierce D (2020) A multi-layered model of human skin elucidates mechanisms of wrinkling in the forehead. J Mech Behav Biomed Mater 105:103694
Zimmerman A, Bai L, Ginty DD (2014) The gentle touch receptors of mammalian skin. Science 346(6212):950–954
Zou Y, Maibach HI (2018) Dermal-epidermal separation methods: research implications. Arch Dermatol Res 310:1–9
Acknowledgements
This work was supported by NIAMS, USA, award R01AR074525, NSF CMMI, USA, award 1916668.
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Moreno-Flores, O., Rausch, M.K. & Tepole, A.B. The role of interface geometry and appendages on the mesoscale mechanics of the skin. Biomech Model Mechanobiol 23, 553–568 (2024). https://doi.org/10.1007/s10237-023-01791-6
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DOI: https://doi.org/10.1007/s10237-023-01791-6