sa ›› 2018, Vol. 23 ›› Issue (1): 132-137.doi: 10.1007/s12204-018-1918-9
OU Haihuaa (欧海华), QAISER Zeeshana, KANG Lipinga (康利平), JOHNSON Shanea,b*
出版日期:
2018-02-01
发布日期:
2018-02-01
通讯作者:
JOHNSON Shane
E-mail:shane.johnson@sjtu.edu.cn
OU Haihuaa (欧海华), QAISER Zeeshana, KANG Lipinga (康利平), JOHNSON Shanea,b*
Online:
2018-02-01
Published:
2018-02-01
Contact:
JOHNSON Shane
E-mail:shane.johnson@sjtu.edu.cn
摘要: Experimental measurements of stresses and strains for lower extremity injuries (LEI) are invasive, and therefore, predictions require physiologically accurate 3D finite element (FE) models of the foot and ankle. In previous models, skin is typically neglected. However, experimental studies have shown that skin is much stiffer than soft tissue. In this study, the material sensitivity of skin on foot arch deformation is investigated. A finite element model of the foot is developed, incorporating bones, soft tissue, ligament, articulating surfaces, plantar aponeurosis, skin and plantar plate. Balanced standing is simulated without skin or with three different skin mechanical properties. By including different skin models, the foot static vertical stiffness, navicular displacement and plantar aponeurosis strain change significantly, when compared with the model without skin. The study shows that skin, showing a much stiffer behaviour than soft tissue, should not be neglected in the foot modelling. Further, the plantar plate considered in this model can give merit to modelling injuries such as plantar plate tearing.
中图分类号:
OU Haihuaa (欧海华), QAISER Zeeshana, KANG Lipinga (康利平), JOHNSON Shanea,b*. Effect of Skin on Finite Element Modeling of Foot and Ankle During Balanced Standing[J]. sa, 2018, 23(1): 132-137.
OU Haihuaa (欧海华), QAISER Zeeshana, KANG Lipinga (康利平), JOHNSON Shanea,b*. Effect of Skin on Finite Element Modeling of Foot and Ankle During Balanced Standing[J]. Journal of Shanghai Jiao Tong University (Science), 2018, 23(1): 132-137.
[1] BANDAK F A, TANNOUS R E, TORIDIS T. Onthe development of an osseo-ligamentous finite elementmodel of the human ankle joint [J]. International Journalof Solids and Structures, 2001, 38(10-13): 1681-1697. [2] CHEN W P, TANG F T, JU C W. Stress distributionof the foot during mid-stance to push-off in barefootgait: a 3-D finite element analysis [J]. Clinical Biomechanics,2001, 16(7): 614-620. [3] GEFEN A. Stress analysis of the standing foot followingsurgical plantar fascia release [J]. Journal ofBiomechanics, 2002, 35(5): 629-637. [4] CHEUNG J T M, ZHANG M, AN K N. Effect ofAchilles tendon loading on plantar fascia tension in thestanding foot [J]. Clinical Biomechanics, 2006, 21(2):194-203. [5] TAO K, WANG D M, WANG C T, et al. An In VivoExperimental Validation of a Computational Model ofHuman Foot [J]. Journal of Bionic Engineering, 2009,6(4): 387-397. [6] SARRAFIAN S K. Functional characteristics of thefoot and plantar aponeurosis under tibiotalar loading[J]. Foot Ankle, 1987, 8(1): 4-18. [7] LEMMON D, SHIANG T Y, HASHMI A, et al. Theeffect of insoles in therapeutic footwear - A finite elementapproach [J]. Journal of Biomechanics, 1997,30(6): 615-620. [8] HSU C C, TSAI W C, CHEN C P C, et al. Effects ofaging on the plantar soft tissue properties under themetatarsal heads at different impact velocities [J]. Ultrasoundin Medicine and Biology, 2005, 31(10): 1423-1429. [9] WRIGHT D G, RENNELS D C. A STUDY OF THEELASTIC PROPERTIES OF PLANTAR FASCIA [J].Journal of Bone and Joint Surgery-American Volume,1964, 46(3): 482-492. [10] PAVAN P G, STECCO C, DARWISH S, et al. Investigationof the mechanical properties of the plantaraponeurosis [J]. Surgical and Radiologic Anatomy,2011, 33(10): 905-911. [11] JANSEN L H, ROTTIER P B. Some mechanical propertiesof human abdominal skin measured on excisedstrips: a study of their dependence on age and howthey are influenced by the presence of striae [J]. Dermatologica,1958, 117(2): 65-83. [12] VOGEL H G. Age dependence of mechanical and biochemicalproperties of human skin [J]. Bioengineeringand the Skin, 1987, (3): 67-91. [13] JACQUEMOUD C, BRUYERE-GARNIER K,CORET M. Methodology to determine failure characteristicsof planar soft tissues using a dynamictensile test [J]. Journal of biomechanics, 2007, 40(2):468-475. [14] CHEUNG J T, ZHANG M, LEUNG A K, et al. Threedimensionalfinite element analysis of the foot duringstanding - A material sensitivity study. [J]. Journal ofBiomechanics, 2005, 38: 1045-1054. [15] FONTANELLA C G, FAVARETTO E, CARNIEL EL, et al. Constitutive formulation and numerical analysisof the biomechanical behaviour of forefoot plantarsoft tissue [J]. Proceedings of the Institution of MechanicalEngineers Part H-Journal of Engineering inMedicine, 2014, 228(9): 942-951. [16] WEARING S C, SMEATHERS J E, URRY S R. The effect of plantar fasciitis on vertical foot-ground reactionforce [J]. Clinical Orthopaedics and Related Research,2003, (409): 175-185. [17] SHEPHERD D E T, SEEDHOM B B. The ’instantaneous’compressive modulus of human articular cartilagein joints of the lower limb [J]. Rheumatology (Oxford),1999, 38(2): 124-132. [18] SIEGLER S, BLOCK J, SCHNECK C D. The mechanicalcharacteristics of the collateral ligaments ofthe human ankle joint [J]. Foot & ankle, 1988, 8(5):234-42. [19] KOGLER G F, SOLOMONIDIS S E, PAUL J P.Biomechanics of longitudinal arch support mechanismsin foot orthoses and their effect on plantar aponeurosisstrain [J]. Clinical Biomechanics, 1996, 11(5): 243-252. [20] LEDOUX W R, BLEVINS J J. The compressive materialproperties of the plantar soft tissue [J]. Journalof Biomechanics, 2007, 40(13): 2975-2981. [21] CAMACHO D L A, LEDOUX W R, ROHR E S, et al.A three-dimensional, anatomically detailed foot model:A foundation for a finite element simulation and meansof quantifying foot-bone position [J]. Journal of RehabilitationResearch and Development, 2002, 39(3):401-410. [22] ANDERSON D D, GOLDSWORTHY J K, LIW, et al.Physical validation of a patient-specific contact finiteelement model of the ankle [J]. Journal of Biomechanics,2007, 40(8): 1662-1669. [23] GEFEN A. The in vivo elastic properties of the plantarfascia during the contact phase of walking [J]. FootAnkle Int, 2003, 24(3): 238-44. [24] DUAN X, LI L, WEI D Q, et al. Role of magneticresonance imaging versus ultrasound for detection ofplantar plate tear [J]. Journal of Orthopaedic Surgeryand Research, 2017, 12: 14. |
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