Validation of a finite element model of a unilateral external fixator in a rabbit tibia defect model.

[en] In case of large segmental defects in load-bearing bones, an external fixator is used to provide mechanical stability to the defect site. The overall stiffness of the bone-fixator system is determined not only by the fixator design but also by the way the fixator is mounted to the bone. This stiffness is an important factor as it will influence the biomechanical environment to which tissue engineering scaffolds and regenerating tissues are exposed. A finite element (FE) model can be used to predict the system stiffness. The goal of this study is to develop and validate a 3D anatomical FE model of a bone-fixator system which includes a previously developed unilateral external fixator for a large segmental defect model in the rabbit tibia. It was hypothesized that the contact interfaces between bone and fixator screws play a major role for the prediction of the stiffness. In vitro mechanical testing was performed in order to measure the axial stiffness of cortical bone from mid-shaft rabbit tibiae and of the tibia-fixator system, as well as the bending stiffness of individual fixator screws, inserted in bone. muCT-based case-specific FE models of cortical bone and SCREW-BONE specimens were created to simulate the corresponding mechanical test set-ups. The Young's modulus of rabbit cortical bone as well as appropriate screw-bone contact settings were derived from those FE models. We then used the derived settings in an FE model of the tibia-fixator system. The difference between the FE predicted and measured axial stiffness of the tibia-fixator system was reduced from 117.93% to 7.85% by applying appropriate screw-bone contact settings. In conclusion, this study shows the importance of screw-bone contact settings for an accurate fixator stiffness prediction. The validated FE model can further be used as a tool for virtual mechanical testing in the design phase of new tissue engineering scaffolds and/or novel patient-specific external fixation devices.

Disciplines :

Engineering, computing & technology: Multidisciplinary, general & others

Author, co-author :

Karunratanakul, Kavin

Kerckhofs, Greet ; Université de Liège - ULiège > Département d'aérospatiale et mécanique > Génie biomécanique

Lammens, Johan

Vanlauwe, Johan

Schrooten, Jan

Van Oosterwyck, Hans

Language :

English

Title :

Validation of a finite element model of a unilateral external fixator in a rabbit tibia defect model.

Publication date :

2013

Journal title :

Medical Engineering and Physics

ISSN :

1350-4533

eISSN :

1873-4030

Publisher :

Elsevier, Oxford, United Kingdom

Volume :

Issue :

Pages :

1037-43

Peer reviewed :

Peer Reviewed verified by ORBi

Commentary :

Available on ORBi :

since 14 November 2013

Statistics

Number of views

51 (2 by ULiège)

Number of downloads

2 (2 by ULiège)

More statistics

Scopus citations^®

Scopus citations^®
without self-citations

OpenCitations

Bibliography

Cancedda R, Giannoni P, Mastrogiacomo M. A tissue engineering approach to bone repair in large animal models and in clinical practice. Biomaterials 2007;28:4240-50.
Marcacci M, Kon E, Moukhachev V, Lavroukov A, Kutepov S, Quarto R, et al. Stem cells associated with macroporous bioceramics for long bone repair: 6- to 7-year outcome of a pilot clinical study. Tissue Eng 2007;13:947-55.
Vacanti CA, Bonassar LJ, Vacanti MP, Shufflebarger J. Replacement of an avulsed phalanx with tissue-engineered bone. N Engl J Med 2001;344:1511-4.
Boerckel JD, Dupont KM, Kolambkar YM, Lin ASP, Guldberg RE. In vivo model for evaluating the effects of mechanical stimulation on tissue-engineered bone repair. J Biomech Eng 2009;131:084502.
Drosse I, Volkmer E, Seitz S, Seitz H, Penzkofer R, Zahn K, et al. Validation of a femoral critical size defect model for orthotopic evaluation of bone healing: a biomechanical, veterinary and trauma surgical perspective. Tissue Eng Part C: Methods 2008;14:79-88.
Augat P, Simon U, Liedert A, Claes L. Mechanics and mechano-biology of fracture healing in normal and osteoporotic bone. Osteoporos Int 2005;16(Suppl.2):S36-43.
Claes LE, Heigele CA. Magnitudes of local stress and strain along bony surfaces predict the course and type of fracture healing. J Biomech 1999;32:255-66.
Kenwright J, Gardner T. Mechanical influences on tibial fracture healing. Clin Orthop 1998:S179-90.
Prendergast PJ, Huiskes R, Søballe K. ESB research award 1996. Biophysical stimuli on cells during tissue differentiation at implant interfaces. J Biomech 1997;30:539-48.
Byrne DP, Lacroix D, Planell JA, Kelly DJ, Prendergast PJ. Simulation of tissue differentiation in a scaffold as a function of porosity Young's modulus and dissolution rate: application of mechanobiological models in tissue engineering. Biomaterials 2007;28:5544-54.
Milan J-L, Planell JA, Lacroix D. Simulation of bone tissue formation within a porous scaffold under dynamic compression. Biomech Model Mechanobiol 2010;9:583-96.
Sanz-Herrera JA, Garcia-Aznar JM, Doblare M. A mathematical model for bone tissue regeneration inside a specific type of scaffold. Biomech Model Mechanobiol 2008;7:355-66.
Duda GN, Kirchner H, Wilke HJ, Claes L. A method to determine the 3-D stiffness of fracture fixation devices and its application to predict inter-fragmentary movement. J Biomech 1998;31:247-52.
Meleddu A, Barrault S, Zysset PK. A rigorous method for evaluation of the 6d compliance of external fixators. Biomech Model Mechanobiol 2007;6: 253-64.
Drijber FL, Finlay JB, Dempsey AJ. Evaluation of linear finite-element analysis models' assumptions for external fixation devices. J Biomech 1992;25: 849-55.
Koo TK, Chao EY, Mak AF. Fixation stiffness of dynafix unilateral external fixator in neutral and non-neutral configurations. Biomed Mater Eng 2005;15:433-44.
Watson MA, Mathias KJ, Maffulli N, Hukins DWL, Shepherd DET. Finite element modelling of the Ilizarov external fixation system. Proc Inst Mech Eng Part H: J Eng Med 2007;221:863-71.
Karunratanakul K, Schrooten J, Van Oosterwyck H. Finite element modelling of a unilateral fixator for bone reconstruction: importance of contact settings. Med Eng Phys 2010;32:461-7.
Bakker AD, Schrooten J, van Cleynenbreugel T, Vanlauwe J, Luyten J, Schepers E, et al. Quantitative screening of engineered implants in a long bone defect model in rabbits. Tissue Eng Part C: Methods 2008;14:251-60.
Kerckhofs G, Schrooten J, Van Cleynenbreugel T, Lomov SV, Wevers M. Validation of X-ray microfocus computed tomography as an imaging tool for porous structures. Rev Sci Instrum 2008;79:013711.
Feldkamp L, Davis L, Kress J. Practical cone-beam algorithm. J Opt Soc Am A- Opt Image Sci Vision 1984;1:612-9.
Pérez MA, Moreo P, García-Aznar JM, Doblaré M. Computational simulation of dental implant osseointegration through resonance frequency analysis. J Biomech 2008;41:316-25.
Van Oosterwyck H, Vander Sloten J, Puers R, Naert I. Finite element studies on the role of mechanical loading in bone response around oral implants. Mecanica 2002;37:441-51.
Bartold PM, Kuliwaba JS, Lee V, Shah S, Marino V, Fazzalari NL. Influence of surface roughness and shape on microdamage of the osseous surface adjacent to titanium dental implants. Clin Oral Implants Res 2011;22:613-8.
Clary EM, Roe SC. In vitro biomechanical and histological assessment of pilot hole diameter for positive-profile external skeletal fixation pins in canine tibiae. Vet Surg 1996;25:453-62.
Lee N-K, Baek S-H. Effects of the diameter and shape of orthodontic miniimplants on microdamage to the cortical bone. Am J Orthod Dentofacial Orthop 2010;138, 8.e1-8; discussion 8-9.
Wawrzinek C, Sommer T, Fischer-Brandies H. Microdamage in cortical bone due to the overtightening of orthodontic microscrews. J Orofacial Orthop 2008;69:121-34.
Hayes WC, Perren SM. Plate-bone friction in the compression fixation of fractures. Clin Orthop 1972;89:236-40.
Orr TE, Villars PA, Mitchell SL, Hsu HP, Spector M. Compressive properties of cancellous bone defects in a rabbit model treated with particles of natural bone mineral and synthetic hydroxyapatite. Biomaterials 2001;22:1953-9.
Qu J, Blau PJ, Watkins TR, Cavin OB, Kulkarni NS. friction and wear of titanium alloys sliding against metal, polymer, and ceramic counterfaces. Wear 2005;258:1348-56.
Chang MC, Ko CC, Liu CC, Douglas WH, DeLong R, Seong W-J, et al. Elasticity of alveolar bone near dental implant-bone interfaces after one month's healing. J Biomech 2003;36:1209-14.
Huja SS, Katona TR, Burr DB, Garetto LP, Roberts WE. Microdamage adjacent to endosseous implants. Bone 1999;25:217-22.
Torcasio A, Zhang X, Van Oosterwyck H, Duyck J, van Lenthe GH. Use of micro-CT-based finite element analysis to accurately quantify periimplant bone strains: a validation in rat tibiae. Biomech Model Mechanobiol 2011;11:743-50.
Brånemark R, Ohrnell LO, Nilsson P, Thomsen P. Biomechanical characterization of osseointegration during healing: an experimental in vivo study in the rat. Biomaterials 1997;18:969-78.
van Lenthe GH, Voide R, Boyd SK, Müller R. Tissue modulus calculated from beam theory is biased by bone size and geometry: implications for the use of three-point bending tests to determine bone tissue modulus. Bone 2008;43:717-23.
Hirano T, Burr DB, Turner CH, Sato M, Cain RL, Hock JM. Anabolic effects of human biosynthetic parathyroid hormone fragment (1-34), LY333334, on remodeling and mechanical properties of cortical bone in rabbits. J Bone Miner Res 1999;14:536-45.
Isaksson H, Harjula T, Koistinen A, Iivarinen J, Seppänen K, Arokoski J PA, et al. Collagen and mineral deposition in rabbit cortical bone during maturation and growth: effects on tissue properties. J Orthop Res 2010;28:1626-33.