Study on nonlinear constitutive model of skin under compression load over a wide range of strain rates

Zhang, Xiaoping; Wen, Cun; Tang, Chengli; Liu, Susu; Wen, Yaoke; Wang, Yaping; Bao, Zhenyu; Luo, Shaomin

doi:10.37190/abb-01947-2021-04

Abstract

Purpose: In wound ballistics, skin has obvious blocking effect in the biological target penetration of projectiles. An analytical description of skin mechanical properties under compression can set the basis for the numerical simulation and the evaluation of blocking effect.

Methods: In this study, an improved three-parameter solid visco-elastic model was proposed to describe the skin creep phenomenon. And then combined with Maxwell and Ogden model, a new nonlinear skin constitutive model, consisting of hyper-elastic unit, creep unit and relaxation unit in parallel, was established. Here, we examine the material properties of freshly harvested porcine skin in compression at strain rates from 0.01/s to 4000/s.

Results: The model is verified by comparison with the experimental results by our test and that in the literature at different strain rates.

Conclusions: It shows that calculated results of the constitutive model agree well with the experiment data at extremely low to high strain rates, which is useful for the description of the heterogeneous, nonlinear viscoelastic, relaxation and creep mechanical response of skin under compression.

References

Annaidh A.N., Bruyère K., Destrade M., Gilchrist M.D., Otténio M., Characterization of the anisotropic mechanical properties of excised human skin, J. Mech. Behav. Biomed. Mater., 2012, 5 (1), 139–148.
Search in Google Scholar Back to article
Bao Z.Y., Study on dynamic mechanical properties of biological soft tissue, Dissertation, Nanjing University of Science and Technology, 2019.
Search in Google Scholar Back to article
Belfiore L.A., Physical properties of macromolecules, John Wiley & Sons, 2010.
Search in Google Scholar Back to article
Butler B.J., Boddy R.L., Bo C., Arora H., Williams A., Proud W.G., Brown K.A., Composite nature of fresh skin revealed during compression, Bioinsp. Biomim. Nanobiomater., 2015, 4 (2), 133–139.
Search in Google Scholar Back to article
Chen W., Lu F., Frew D.J., Forrestal M.J., Dynamic Compression Testing of Soft Material, ASME J. Appl. Mech., 2002, 69 (3), 214–223.
Search in Google Scholar Back to article
De Mey J.G., Claeys M., Vanhoutte P.M., Endotheliumdependent inhibitory effects of acetylcholine, adenosine triphosphate, thrombin and arachidonic acid in the canine femoral artery, J. Pharmacol. Exp. Ther., 1982, 222 (1), 166–173.
Search in Google Scholar Back to article
DiMaio V.J., Copeland A.R., Besant-Matthews P.E., Fletcher L.A., Jones A., Minimal velocities necessary for perforation of skin by air gun pellets and bullets, J. Forensic. Sci., 1982, 27 (4), 894–899.
Search in Google Scholar Back to article
Dougherty P.J., Najibi S., Silverton C., Vaidya R., Gunshot wounds: epidemiology, wound ballistics, and soft-tissue treatment, Instr. Course. Lect., 2009, 58, 131–139.
Search in Google Scholar Back to article
Fackler M.L., Wound ballistics and the scientific background: book review, Wound. Ballistics. Rev., 1994, 2, 46–48.
Search in Google Scholar Back to article
Finlay B., Dynamic mechanical testing of human skin “in vivo”, J. Biomech., 1970, 3 (6), 559–568.
Search in Google Scholar Back to article
Ghorbel-Feki H., Masood A., Caliez M., Gratton M., Pittet J. C., Lints M., Dos Santos S., Acousto-mechanical behaviour of ex vivo skin: Nonlinear and viscoelastic properties, Comptes. Rendus. Mécanique., 2019, 347 (3), 218–227.
Search in Google Scholar Back to article
Groves R.B., Coulman S.A., Birchall J.C., Evans S.L., An anisotropic, hyperelastic model for skin: experimental measurements, finite element modelling and identification of parameters for human and murine skin, J. Mech. Behav. Biomed. Mater., 2013, 18, 167–180.
Search in Google Scholar Back to article
Haut R.C., The effects of orientation and location on the strength of dorsal rat skin in high and low speed tensile failure experiments, J. Biomech. Eng., 1989, 111, 136–140.
Search in Google Scholar Back to article
Holt B., Tripathi A., Morgan J., Viscoelastic response of human skin to low magnitude physiologically relevant shear, J. Biomech., 2008, 41 (12), 2689–2695.
Search in Google Scholar Back to article
Karimi A., Faturechi R., Navidbakhsh M., Hashemi S.A., A non-linear hyperelastic behavior to identify the mechanical properties of rat skin under uniaxial loading, J. Mech. Med. Biol., 2014, 14 (5), 1–14.
Search in Google Scholar Back to article
Koene L., Papy A., Towards a better, science-based, evaluation of kinetic non-lethal weapons, Int. J. Intelligent. Defence. Support. Systems., 2011, 4 (2), 169–186.
Search in Google Scholar Back to article
Łagan S.D., Liber-Kneć A., Experimental testing and constitutive modeling of the mechanical properties of the swine skin tissue. Act. Bioeng. Biomech., 2017, 19 (2), 93–102.
Search in Google Scholar Back to article
Lamers E., van Kempen T.H.S., Baaijens F.P.T., Peters G.W.M., Oomens C.W.J., Large amplitude oscillatory shear properties of human skin, J. Mech. Behav. Biomed. Mater., 2013, 28, 462–470.
Search in Google Scholar Back to article
Lanir Y., Fung Y.C., Two-dimensional mechanical properties of rabbit skin – I. Experimental system, J. Biomech., 1974, 7, 29–34.
Search in Google Scholar Back to article
Lapeer R.J., Gasson P.D., Karri V., Simulating plastic surgery: From human skin tensile tests, through hyperelastic finite element models to real-time haptics, Prog. Biophys. Mol. Bio., 2010, 103 (2–3), 208–216.
Search in Google Scholar Back to article
Li W., Luo X.Y., An Invariant-Based Damage Model for Human and Animal Skins, Ann. Biomed. Eng., 2016, 44, 3109–3122.
Search in Google Scholar Back to article
Lim J., Hong J., Chen W.W., Weerasooriya T., Mechanical response of pig skin under dynamic tensile loading, Int. J. Impact. Eng., 2011, 38 (2), 130–135.
Search in Google Scholar Back to article
Liu K., Wu Z.L., Ren H.L., Li Z.X., Ning J.G., Strain rate sensitive compressive response of gelatine: Experimental and constitutive analysis, Polym. Testing., 2017, 6, 254–266.
Search in Google Scholar Back to article
Missliwetz J., Critical velocity in skin (an experimental ballistic study with firearms of 4 mm and 4.5 mm calibers), Beitr. Gerichtl. Med., 1987, 45, 411–432.
Search in Google Scholar Back to article
Nicolle S., Decorps J., Fromy B., Palierne J.-F., New regime in the mechanical behavior of skin: strain-softening occurring before strain-hardening, J. Mech. Behav. Biomed. Mater., 2017, 69, 98–106.
Search in Google Scholar Back to article
Pissarenko A., Meyers M.A., The materials science of skin: Analysis, characterization, and modeling, Prog. Mater. Sci., 2020, 110, 100634.
Search in Google Scholar Back to article
Reihsner R., Menzel E.J., Two-dimensional stress–relaxation behavior of human skin as influenced by non-enzymatic glycation and the inhibitory agent aminoguanidine, J. Biomech., 1998, 31 (11), 985–993.
Search in Google Scholar Back to article
Ridge M.D., Wright V., The directional effects of skin, J. Invest. Dermatol., 1965, 46, 341–6.
Search in Google Scholar Back to article
Rubin M.B., Bodner S.R., Binur N.S., An elastic-viscoplastic model for excised facial tissues, J. Biomech. Eng., 1998, 120 (5), 686–689.
Search in Google Scholar Back to article
Schneider D.C., Davidson T.M., Nahum A.M., In vitro biaxial stress–strain response of human skin, Arch. Otolaryngol., 1984, 110 (5), 329–333.
Search in Google Scholar Back to article
Shergold O.A., Fleck N.A., Radford D., The uniaxial stress versus strain response of pig skin and silicone rubber at low and high strain rates, Int. J. Impact. Eng., 2006, 32 (9), 1384–1402.
Search in Google Scholar Back to article
Soetens J.F.J., van Vijven M., Bader D.L., Peters G.W.M., Oomens C.W.J., A model of human skin under large amplitude oscillatory shear, J. Mech. Behav. Biomed. Mater., 2018, 86, 423–432.
Search in Google Scholar Back to article
Tausch D., Sattler W., Wehrfritz K., Wehrfritz G., Wagner H.J., Experiments on the penetration power of various bullets into skin and muscle tissue, Z. Rechtsmed., 1978, 81 (4), 309–328.
Search in Google Scholar Back to article
Weiss J.A., Maker B.N., Govindjee S., Finite element implementation of incompressible, transversely isotropic hyperelasticity, Comput. Meth. Appl. Mech. Eng., 1996, 135, 107–128.
Search in Google Scholar Back to article
Wu J.Z., Dong R.G., Smutz P., Schopper A.W., Nonlinear and Viscoelastic Characteristics of Skin Under Compression: Experiment and Analysis, Biomed. Mater. Eng., 2003, 13 (4), 373–385.
Search in Google Scholar Back to article

Study on nonlinear constitutive model of skin under compression load over a wide range of strain rates

Abstract

Paradigm

My account