Narzędzia help

Preferencje help
Widoczny [Schowaj] Abstrakt
Liczba wyników
cannonical link button

http://yadda.icm.edu.pl:80/baztech/element/bwmeta1.element.baztech-bff8b696-0990-45b5-9a6d-e4bbd4b9b789

Czasopismo

Acta of Bioengineering and Biomechanics

Tytuł artykułu

Modeling and stress analyses of a normal foot-ankle and a prosthetic foot-ankle complex

Autorzy Ozen, M.  Sayman, O.  Havitcioglu, H. 
Treść / Zawartość
Warianty tytułu
Języki publikacji EN
Abstrakty
EN Total ankle replacement (TAR) is a relatively new concept and is becoming more popular for treatment of ankle arthritis and fractures. Because of the high costs and difficulties of experimental studies, the developments of TAR prostheses are progressing very slowly. For this reason, the medical imaging techniques such as CT, and MR have become more and more useful. The finite element method (FEM) is a widely used technique to estimate the mechanical behaviors of materials and structures in engineering applications. FEM has also been increasingly applied to biomechanical analyses of human bones, tissues and organs, thanks to the development of both the computing capabilities and the medical imaging techniques. 3-D finite element models of the human foot and ankle from reconstruction of MR and CT images have been investigated by some authors. In this study, data of geometries (used in modeling) of a normal and a prosthetic foot and ankle were obtained from a 3D reconstruction of CT images. The segmentation software, MIMICS was used to generate the 3D images of the bony structures, soft tissues and components of prosthesis of normal and prosthetic ankle-foot complex. Except the spaces between the adjacent surface of the phalanges fused, metatarsals, cuneiforms, cuboid, navicular, talus and calcaneus bones, soft tissues and components of prosthesis were independently developed to form foot and ankle complex. SOLIDWORKS program was used to form the boundary surfaces of all model components and then the solid models were obtained from these boundary surfaces. Finite element analyses software, ABAQUS was used to perform the numerical stress analyses of these models for balanced standing position. Plantar pressure and von Mises stress distributions of the normal and prosthetic ankles were compared with each other. There was a peak pressure increase at the 4th metatarsal, first metatarsal and talus bones and a decrease at the intermediate cuneiform and calcaneus bones, in prosthetic ankle-foot complex compared to normal one. The predicted plantar pressures and von Misses stress distributions for a normal foot were consistent with other FE models given in the literature. The present study is aimed to open new approaches for the development of ankle prosthesis.
Słowa kluczowe
PL modelowanie 3D   proteza   analiza elementów skończonych  
EN 3D modeling   finite element analysis   prosthetic foot-ankle complex  
Wydawca Oficyna Wydawnicza Politechniki Wrocławskiej
Czasopismo Acta of Bioengineering and Biomechanics
Rocznik 2013
Tom Vol. 15, nr 3
Strony 19--27
Opis fizyczny Bibliogr. 36 poz., rys., tab.
Twórcy
autor Ozen, M.
autor Sayman, O.
  • Faculty of Engineering, Dokuz Eylul University, Izmir, Turkey
autor Havitcioglu, H.
  • Faculty of Medicine, Dokuz Eylul University, Izmir, Turkey
Bibliografia
[1] ANDERSON T., MONTGOMERY F., CARLSSON A., UncementedSTAR total ankle prostheses. Three to eight-year follow-up of fifty-one consecutive ankles, The Journal of Bone and Joint Surgery AM, 2003, Vol. 85, 1321–1329.
[2] WOOD P.L., DEAKIN S., Total ankle replacement. The result in 200 ankles, The Journal of Bone and Joint Surgery BR, 2003, Vol. 85, 334–341.
[3] AJAI S., A review of the STAR prosthetic system and the biomechanical considerations in total ankle replacements, Foot and Ankle Surgery, 2011, Vol. 17, 64–67.
[4] DYRBY C., CHOU L.B., ANDRIACCHI T.P., MANN R.A., Functional evaluation of the Scandinavian Total Ankle Replacement, Foot & Ankle International, 2004, Vol. 25, 377–381.
[5] HOUDIJK H., DOETS H.C., van MIDDELKOOP M., VEEGER H.E.J., Joint stiffness of the ankle during walking after successful mobile-bearing total ankle replacement, Gait & Posture, 2008, Vol. 27, 115–119.
[6] PRENDERGAST P.J., Finite element models in tissue mechanics and orthopaedic implant design, Clinical Biomechanics, 1997, Vol. 12, 343–366.
[7] ZHNAG M., MAK A., ROBERTS V.C., Finite element modeling of a residual lower-limb in a prosthetic socket: a survey of the development in the first decade, Medical Engineering & Physics, 1998, Vol. 20, 360–373.
[8] SCHULLER-GÖTZBURG P., KRENKEL C., 2D-finite element analyses and histomorphology of lag screws with and without a biconcave washer, Journal of Biomechanics, 1999, Vol. 32, 511–520.
[9] REGGIANI B., LEARDINI A., CORAZZA F., TAYLOR M., Finite element analysis of a total ankle replacement during the stance phase of gait, Journal of Biomechanics, 2006, Vol. 39, 1435–1443.
[10] VICECONTI M., BELLINGERI L., CRISTOFOLINI L., TONI A., A comparative study on different methods of automatic mesh generation of human femurs, Medical Engineering & Physics, 1998, Vol. 20, 1–10.
[11] NIEBUR G.L., FELDSTEIN M.J., YUEN J.C., CHEN T.J., KEAVENY T.M., High-resolution finite element models with tissue strength asymmetry accurately predict failure of trabecular bone, Journal of Biomechanics, 2000, Vol. 33, 1575–1583.
[12] SCIFERT C.F., BROWN T.D., LIPMAN J.D., Finite element analysis of a novel design approach to resisting total hip dislocation, Clinical Biomechanics, 1999, Vol. 14, 697–703.
[13] TADEPALLI S.C., ERDEMIR A., CAVANGH P.R., Comparison of hexahedral and tetrahedral elements in finite element analysis of the foot and footwear, Journal of Biomechanics, 2011, Vol. 44, 2337–2343.
[14] TADEPALLI S.C., SHIVANNA K.H., MAGNOTTA V.A., KALLEMEYN N.A., GROSLAND N.M., Toward the development of virtual surgical tools to aid orthopaedic FE analyses, Journal on Advances in Signal Processing, 2010, 1902931–1902937.
[15] DEVRIES N.A., SHIVANNA K.H., TADEPALLI S.C., MAGNOTTA V.A., GROSLAND N.M., Ia-FEMesh: anatomic FE models – a check of mesh accuracy and validity, The Iowa Orthopaedic Journal, 2009, Vol. 29, 48–54.
[16] CHENG C.K., CHEN H.H., KUO H.H., LEE C.L., CHEN W.J., LIU C.L., A three-dimensional mathematical model for predicting spinal joint force distribution during manual liftings, Clinical Biomechanics, 1998, Vol. 13, 59–64.
[17] BANDAK F.A., TANNOUS R.E., TORIDIS T., On the development of an osseo-ligamentous finite element model of human ankle joint, International Journal of Solids and Structures, 2001, Vol. 38, 1681–1697.
[18] BARTOS M., KESTRANEK Z., NEDOMA J., STEHLIK J., On the 2D and 3D finite element simulation in orthopaedy using MRI, Mathematics and Computers in Simulation, 1999, Vol. 50, 115–121.
[19] GEFEN A., MEGIDO-RAVID M., ITZCHAK Y., ARCAN M., Biomechanical Analysis of the Three-Dimensional Foot Structure during Gait: A Basic Tool for Clinical Applications, Journal of Biomechanical Engineering, 2000, Vol. 12, 631–639.
[20] CHEN W.M., LEE T., LEE P.V.S., LEE J.W., LEE S.J., Effects of internal stress concentrations in plantar soft-tissue – A preliminary three-dimensional finite element analysis, Medical Engineering & Physics, 2010, Vol. 32, 324–331.
[21] CHEN W.P., TANG F.T., JU C.W., Stress Distribution of the Foot During Mid-stance to Push-off in Barefoot Gait: a 3-D Finite Element Analysis, Clinical Biomechanics, 2001, Vol. 16, 614–620.
[22] CHEUNG J.T.M., ZHANG M., LEUNG A.K.L., FAN Y.B., Threedimensional finite element analysis of the foot during standing – a material sensitivity study, Journal of Biomechanics, 2005, Vol. 38, 1045–1054.
[23] CHEUNG J.T.M., ZHANG M., AN K.N., Effects of plantar fascia stiffness on the biomechanical responses of the ankle-foot complex, Clinical Biomechanics, 2004, Vol. 19, 839–846.
[24] CHEUNG J.T.M., ZHANG M., Finite element modeling of the human foot and footwear, ABAQUS Users Conference, May 23, 2006, Cambridge, MA USA.
[25] CHEUNG J.T.M., ZHANG M., AN K.N., Effect of Achilles tendon loading on plantar fascia tension in the standing foot, Clinical Biomechanics, 2006, Vol. 21, 194–203.
[26] CHEUNG J.T.M., ZHANG M., Parametric design of pressurerelieving foot orthosis using statistical-based finite element method, Medical Engineering & Physics, 2008, Vol. 30, 269–277.
[27] YU J., CHEUNG J.T.M., FAN Y., ZHANG Y., LEUNG A.K.L., ZHANG M., Development of a finite element model of female foot for high-heeled shoe design, Clinical Biomechanics, 2008, Vol. 23, 31–38.
[28] ANTUNES P.J., DIAS G.R., COELHO A.T., REBELO F., PEREIRA T., Non-linear finite element modeling of anatomically detailed 3D foot model, Materialise, http://materialise.com/materialise/ view/ en/394365-Non-Linear + Finite + Element + Modeling + of + Anatomically + Detailed + 3D + Foot + Model.html, Retrieved 2012.
[29] TAO K., WANG D., WANG C., WANG X., LIU A., NESTER C.J., HOWARD D., An in vivo experimental validation of a computational model of human foot, Journal of Bionic Engineering, 2009, Vol. 6, 387–397.
[30] QIU T.X., TEO E.C., YAN Y.B., LEI W., Finite element modeling of a 3D coupled foot–boot model, Medical Engineering & Physics, 2011, Vol. 33, 1228–1233.
[31] JACOB S., PATIL M.K., Three-dimensional foot modeling and analysis of stress in normal and early stage Hansen’s disease with muscle paralysis, Journal of Rehabilitation Research & Development, 1999, Vol. 36, 252–263.
[32] JACOB S., PATIL M.K., Stress analysis in three-dimensional foot of normal and diabetic neuropathy, Frontiers of Medical and Biological Engineering, 1999, Vol. 9, 211–227.
[33] ATHANASIOU K.A., LIU G.T., LAVERY L.A., LANCTOT D.R., SCHENCK R.C., Biomechanical topography of human articular cartilage in the first metatarsophalangeal joint, Clinical Orthopaedics and Related Research, 1998, Vol. 348, 269–381.
[34] SIEGLER S., BLOCK J., SCHNECK C.D., The mechanical characteristics of the collateral ligaments of the human ankle joint, Foot & Ankle, 1988, Vol. 8, 234–242.
[35] WRIGHT D., RENNELS D., A study of the elastic properties of plantar fascia, The Journal of Bone and Joint Surgery AM, 1964, Vol. 46, 482–492.
[36] ZHANG M., MAK A.F.T., In vivo skin frictional properties, Prosthetics and Orthotics International, 1999, Vol. 23, 135–141.
Kolekcja BazTech
Identyfikator YADDA bwmeta1.element.baztech-bff8b696-0990-45b5-9a6d-e4bbd4b9b789
Identyfikatory