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Computer Methods in Biomechanics and Biomedical Engineering Volume 16, 2013 - Issue 8
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Articles

Development and validation of a subject-specific finite element model of a human clavicle

Zuoping LiCenter for Applied Biomechanics, University of Virginia, 4040 Lewis and Clark Drive, Charlottesville, VA22902, USACorrespondence[email protected]
,
Matthew W. KindigCenter for Applied Biomechanics, University of Virginia, 4040 Lewis and Clark Drive, Charlottesville, VA22902, USA
,
Jason R. KerriganCenter for Applied Biomechanics, University of Virginia, 4040 Lewis and Clark Drive, Charlottesville, VA22902, USA
,
Richard W. KentCenter for Applied Biomechanics, University of Virginia, 4040 Lewis and Clark Drive, Charlottesville, VA22902, USA
&
Jeff R. CrandallCenter for Applied Biomechanics, University of Virginia, 4040 Lewis and Clark Drive, Charlottesville, VA22902, USA
Pages 819-829 | Received 13 May 2010, Accepted 12 Nov 2011, Published online: 06 Jan 2012

REFERENCES

  • AamodtA, KevistadK, AndersonE, Lund-LarsenJ, EineJ, BenumP, HusbyOS. 1999. Determination of the hounsfield value for CT-based design of custom femoral stems. J Bone Joint Surg (Br). 81-B:143–147.
  • AndermahrJ, RingDC, JupiterJB. 2006. Fracture of the clavicle. In: IannottiJP, WilliamsGR, editors. Disorders of the shoulder: diagnosis and management. Vol. 2. Philadelphia, PA: Lippincott Williams & Wilkins. p. 943–974.
  • AndermahrJ, JubelA, ElsnerA, JohannJ, ProkopA, RehmK, KoebkeJ. 2007. Anatomy of the clavicle and the intermedullary nailing of midclavicular fractures. Clin Anat. 20:48–56.
  • AndersonAE, PetersCL, TuttleBD, WeissJA. 2005. Subject-specific finite element model of the pelvis: development, validation and sensitivity studies. J Biomech Eng. 127(3):364–373.
  • Arregui-DalmasesC, PozoED, DupreyS, Lopez-ValdesFJ, LauA, SubitD, KentRW. 2010. A parametric study of hard tissue injury prediction using finite elements: consideration of geometric complexity, sub-failure material properties, CT-thresholding, and element characteristics. Traffic Inj Prev. 11(3):286–293.
  • AstierV, ThollonL, ArnouxPJ, MourF, BrunetPC. 2008. Development of a finite element model of the shoulder: application during a side impact. Int J Crashworthiness. 13(3):301–312.
  • BolteJHIV, HinesMH, McFaddenJD, SaulRA. 2000. Shoulder response characteristics and injury due to lateral glenohumeral joint impacts. Stapp Car Crash J. 44:261–280.
  • ChecchiaSL, DoneuxPS, MiyazakiAN, FregonezeM, SilvaLA. 2008. Treatment of distal clavicle fractures using an arthroscopic technique. J Shoulder Elbow Surg. 17(3):395–398.
  • CompigneS, CaireY, QuesnelT, VerriestJ-P. 2004. Non-injurious and injurious impact response of the human shoulder – three dimensional analysis of kinematics and determination of injury threshold. Stapp Car Crash J. 48:89–125.
  • DupreyS, BruyèreK, VerriestJ-P. 2008. Influence of geometrical personalization on the simulation of clavicle fractures. J Biomech. 41(1):200–207.
  • DupreyS, BruyereK, VerriestJ-P. 2010. Clavicle fracture prediction: simulation of shoulder lateral impacts with geometrically personalized finite elements models. J Trauma. 68(1):177–182.
  • FressmannD, MünzT, GrafO, SchweizerhofK. 2007. FE modeling in crash-aspects of the numerical modeling and current applications in automotive industry. Frankenthal: LS-DYNA Anwenderforum F-I-23-34.
  • GroslandNM, ShivannaKH, MagnottaVA. 2009. IA-FEMesh: an open source, interactive, multi-block approach to anatomic finite element model development. Comput Methods Prog Biomed. 94:96–107.
  • HamerAJ, StrachenJR, BlackMM, IbbotsonCJ, StockleyI, ElsonRA. 1996. Biomechanical properties of cortical allograft bone using a new method of bone strength measurement. A comparison of fresh, fresh-frozen and irradiated bone. J Bone Joint Surg. 78B:363–368.
  • HaugE, ChoiHY, RobinS, BeaugoninM. 2004. Human models for crash and impact simulation. In: AyacheN, editor. Handbook of numerical analysis. Vol. 12. Elsevier B.V. p. 231–452.
  • HillJM, McGuireMH, CrosbyLA. 1997. Closed treatment of displaced middle-third fractures of the clavicles gives poor results. J Bone Joint Surg (British volume). 79b:537–539.
  • HousnerJ, KuhnJ. 2003. Clavicle fractures. Physician Sports Med. 31(12):30–36.
  • HyndD, CarrollJ, CuerdenR. 2007. Upper extremity injury study: recommendations for injury prevention priorities. In: Proceeding of the 20th International Technical Conference of the Enhanced Safety of Vehicles (ESV), Paper 07-0317.
  • ItoO, DokkoY, OhashiK. 2009. Development of adult and elderly FE thorax skeletal models. Society of Automotive Engineers (SAE). Paper number 2009-01-0381.
  • IwamotoM, MikiK, MohammadM, NayefA, YangKH, BegemanPC, KingAI. 2000. Development of a finite element model of the human shoulder. Stapp Car Crash J. 44:281–297.
  • Kallieris D. 1998. Experimental activity for HUMOS project: mechanical tests on bone and cartilage. Final report of the European project HUMOS. Reference 3HEI/98110/T1/DA.
  • KellerTS. 1994. Predicting the compressive mechanical behavior of bone. J Biomech. 27(9):509–522.
  • KemperA, StitzelJ, GablerC, DumaSM, MatsuokaF. 2006. Biomechanical response of the human clavicle subjected to dynamic bending. Biomed Sci Instrum. 42:231–236.
  • KemperAR, StitzelJD, McNallyC, GablerHC, DumaSM. 2009. Biomechanical response of the human clavicle: the effects of loading direction on bending properties. J Appl Biomech. 25(2):165–174.
  • LiZ, KindigM, KerriganJW, UntaroiuCD, DameinS, CrandallJR, KentRW. 2010. Rib fractures under anterior-posterior dynamic loads: experimental and finite element study. J Biomech. 43(2):228–234.
  • LindeF, SorensonHCF. 1993. The effect of different storage methods on the mechanical properties of trabecular bone. J Biomech. 26:1249–1252.
  • LittleEG, KneafseyAG, LynchP, KennedyM. 1985. The design of a model for a three dimensional stress analysis of the cement layer beneath the medial plateau of a knee prosthesis. J Biomech. 18(2):157–160.
  • NordqvistA, PeterssonCJ, Redlund-JohnellI. 1993. The natural course of lateral clavicle fracture: 15 year follow-up of 110 cases. Acta Orthop Scand. 64(1):87–91.
  • ProubastaIR, ItarteJP, CáceresEP, LlusáMP, GilJM, PlanellJA, GinebraMP. 2002. Biomechanical evaluation of fixation of clavicle fractures. J South Orthop Assoc. 11(3):148–152.
  • RobinS. 2001. Humos: human model for safety – a joint effort towards the development of the refined human-like car occupant models. In: Proceedings of the 17th International Conference on Enhanced Safety of Vehicle. 2001 June 4–7. Amsterdam, The Netherlands. Paper number 297.
  • SchileoE, Dall'AraE, TaddeiF, MalandrinoA, SchotampT, BaleleaniM, VicecontiM. 2008. An accurate estimation of bone density improves the accuracy of the subject-specific finite element models. J Biomech. 41:2483–2491.
  • ShahCS, YangKH, HardyWN, YangKH, KingAI. 2001. Development of a computer model to predict aortic rupture due to impact loading. Stapp Car Crash J. 45:161–182.
  • ShahJ, GibsonA, PriceM. 2002. An investigation of the effects of experimental errors on the correlations between FEA and test results for a welded fuselage panel. In: Proceeding of the 23rd International Congress of Aeronautical Sciences. 2002 Sep 8–13; Toronto, Canada.
  • StanleyD, TrowbridgeEA, NorrisSH. 1988. The mechanism of clavicular fracture. A clinical and biomechanical analysis. J Bone Joint Surg (British volume). 70:461–464.
  • ThollonL, BehrM, CavalleroC, BrunetPC. 2001. Finite element modeling and simulation of upper limb with radios. Int J Crashworthiness. 7:269–284.
  • UntaroiuCD, DupreyS, KerriganJR, LiZ, BoseD, CrandallJR. 2009. Experimental and computational investigation of human clavicle response in anterior-posterior bending loading. Biomed Sci Instrum. 45:6–11.
  • ZhaoJ, NarwaniG. 2005. Development of a human body finite element model for restraint system R&D applications. In: Proceedings of The 19th International Technical Conference on the Enhanced Safety of Vehicles (ESV). 2005 June 6–9; Washington DC, Paper number 05-0399.

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