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Research Article | Open Access

Static Study and Finite Element Analysis of a New Method of Fixation of a Medial Humerus Fracture by an Intramedullary Nailing System Analyzed by the ANSYS Workbench 16.2 Calculus Code

Brahim Keddar1,4Benaoumer Aour1,4Samir Zahaf2( )Chetti Boualem2Fouzia Bouchakour2Zahra Najafi Vafa4
Department of Mechanical Engineering, National Polytechnic School of Oran-MA, BP 1523 El Mnaour, Oran, Algeria
Department of Technology, University of Djilali Bounaama-Khamis Meliana, Ain Defla-Algeria
Department of Agronomy and Plant Breeding, Faculty of Agriculture, University of Kurdistan Sananda-Iran
Laboratory of Applied Biomechanics and Biomaterials (LABAB)
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Abstract

Comminuted fractures of the humerus are generally treated with the intramedullary rod fixed by screws or locking plate system, and clinical results are satisfactory. We also know very well that the success of this agriculture depends on the stability and adaptability and integration of the bone tissue of the humerus with this nail in the long term, with less and optimal distribution of stress in the surrounding bone. For this reason, we began to think and look for rational solutions to reduce and minimize this stress which has become an important issue in this area. In this regard, we have proposed a new model of hollow nail made of titanium proposed by some scientific specialists in this field of biomechanics, and we inserted from the proximal humeral head, and to ensure the stability of the nail inside the bone and prevent slippage, we attached small screws. To know the extent of the realization of these nails under the influence of the forces applied to them, finite elements in three dimensions as well as the program ANSYS Workbench 16.2 were used. Two intramedullary rods were instrumented in the finite element model of a medial humeral fracture. Axial, shear, and rotational loads were applied to the models under normal and osteoporotic bone conditions. The whole simulation was repeated 5 times for each fixator. To evaluate the biomechanical characteristics, the distribution of von Mises stresses and strains, total displacement in the nail, cortical and cancellous bone were compared. The numerical results showed that the intramedullary rod system with 4 screws and 6 screws played a very important role in the absorption and thus minimization of stresses. On the other hand, the nailing system fixed with screws was too great a role in reducing the stress compared to intact model. In general, the new model nailing system secured with screws gave a lower level of von Mises stress and strain at the cortical and cancellous bone of the humerus compared to the intact model. The results provided a theoretical basis for the selection of an appropriate surgical model.

References

[1]

F. Chen, X. Huang, Y. Ya, et al., Finite element analysis of intramedullary nailing and double locking plate for treating extra-articular proximal tibial fractures. Journal of Orthopaedic Surgery and Research, 2018: 1-8.

[2]

T. Tolunay, M.O. Akkurt, and A. Solak, The effectiveness of intramedullary nailing on the fixation of tibia diaphyseal fractures: Biomechanical point of view. Turkish Journal of Clinics and Laboratory, 2018, 9(3): 221-226.

[3]

Y.S. Salphale, W.M. Gadegone, R.M. Chandak, et al., screw intramedullary nailing for fractures of the humeral shaft. Surgical Science, 2015, 6: 395-401.

[4]

Y.P. Acklin, I. Zderic, J.A. inzana, et al., Biomechanical evaluation of a new gliding screw concept for the fixation of proximal humeral fractures. Bone Joint Res, 2018, 7: 422-429.

[5]

E. Arbit, S. Pannullo, Lumbar stenosis: A clinical review. Clin Orthop, 2001, 384: 137-143.

[6]

Y. Fan, Y.W. Li, H.B. Zhang, et al., Management of humeral shaft fractures with intramedullary interlocking nail versus locking compression plate. Orthopedics, 2015, 38(9): e825-e829.

[7]

M.A. Verdano, A. Pellegrini, P. Schiavi, et al., Humeral shaft fractures treated with antegrade intramedullary nailing: what are the consequences for the rotator cuff? IntOrthop, 2013, 37(10): 2001-2007.

[8]

M. Walker, B. Palumbo, B. Badman, et al., Humeralshaft fractures: a review. J Shoulder Elbow Surg, 2011, 20(5): 833-844.

[9]

P.M. Rommens, J. Blum, and M. Runkel, Retrograde nailing of humeral shaft fractures. Clin Orthop Relat Res, 1998, (350): 26-39.

[10]

A. Baltov, R. Mihail, and E. Dian, Complications after interlocking intramedullary nailing of humeral shaft fractures. Injury, 2014, 45(suppl 1): S9-S15.

[11]

F. Pogliacomi, A. Devecchi, C. Costantino, et al., Functional long-term outcome of the shoulder after antegrade intramedullary nailing in humeraldiaphyseal fractures. Chir Organi Mov, 2008, 92(1): 11-16.

[12]

C. Voigt, A. Geisler, and H. Lill, Arthroscopic locking plate removal after proximal humeral fractures. Arch Orthop Trauma Surg, 2010, 130(3): 391-395.

[13]
S. Adewusi, M. Thomas, V.H. Vu, et al., Modal parameters of the human hand-arm using finite element and operational modal analysis. Proceedings of 3 ième Congrès International sur l'Ingénierie des Risques Industriels. 2013.
[14]

T.B. Khalil, D.C. Viano, and L. Taber, Vibrational characteristics of the embalmed human femur. Journal of Sound and Vibration, 1981, 75: 417-436.

[15]

A.A. Zadpoor, Finite element method analysis of human hand arm vibrations. Int. J. Sci. Res. , 2006, 16: 391-395.

[16]

A. Kumar, H. Jaiswal, T. Garg, et al., Free vibration modes analysis of femur bone fracture using varying boundary conditions based on FEA. Procedia Materials Science, 2014, 6: 1593-1599.

[17]

A. Kumar, D.P. Mamgain, H. Jaiswal, et al., Modal analysis of hand-arm vibration (humerus bone) for biodynamic response using varying boundary conditions based on FEA. Intelligent Computing, Communication and Devices. Advances in Intelligent Systems and Computing, 2015, 308: 169-176.

[18]

A. Gupta, K.M. Tse, Vibration analysis of femur bone using Elmer. Journal of Engineering Science and Technology Special Issue on ICMTEA 2013 Conference, 2014: 12-19.

[19]
N. Sharma, B. Yadav, Free vibration analysis of humerus bone fracture with varying boundary condition based on FEA. Proceedings of International Journal of Advanced Technology & Engineering Research (IJATER) 1st International Conference on Research in Science, Engineering & Management IOCRSEM. 2014.
[20]

G. Campoli, N. Baka, B.L. Kaptein, et al., Relationship between the shape and density distribution of the femur and its natural frequencies of vibration. Journal of Biomechanics, 2014, 47: 3334-3343.

[21]

Y. He, Y. Zhang, Y. Wang, et al., Biomechanical evaluation of a novel dualplate fixation method for proximal humeral fractures without medial support. Journal of Orthopaedic Surgery and Research, 2017: 1-10.

[22]

S. Sabalic, J. Kodvanj, and A. Pavic, Comparative study of three models of extra-articular distal humerus fracture osteosynthesis using the finite element method on an osteoporotic computational model. Injury, 2013, 44(Suppl 3): S1-S6.

[23]

P. Buchler, N.A. Ramaniraka, L.R. Rakotomanana, et al., A finite element model of the shoulder: application to the comparison of normal and osteoarthritic joints. Clinical Biomechanics, 2002, 17: 630-639.

[24]
K.N. Nur, İnsan kolu humerus kemiği için sonlu elemanlar University, Graduate School of Natural and Applied Sciences. 2003.
[25]

E. Tan, D. Lie, M.K. Wong, et al., Early outcomes of proximal humerus fracture fixation with locking plate and intramedullary fibular strut graft. Orthopedics, 2014, 37: e822-e827.

[26]

S. Choi, H. Kang, H. Bang, et al., Technical tips: Dualplate fixation technique for comminuted proximal humerus fractures. Injury, 2014, 45: 1280-1282.

[27]

Y. He, J. He, F. Wang, D. Zhou, et al., Application of additional medial plate in treatment of proximal humeral fractures with unstable medial column: A finite element study and clinical practice. Medicine, 2015, 94(41): e1775-e1785.

[28]

G. Osterhoff, D. Baumgartner, P. Favre, et al., Medial support by fibula bone graft in angular stable plate fixation of proximal humeral fractures: an in vitro study with synthetic bone. J Shoulder Elbow Surg, 2011, 20: 740-746.

[29]

H.S. Sohn, S.J. Shin, Minimally invasive plate osteosynthesis for proximal humeral fractures: clinical and radiologic outcomes according to fracture type. J Shoulder Elbow Surg, 2014, 23: 1334-1340.

[30]

H. Sano, I. Wakabayashi, E. Itoi, et al., Stress distribution in the supraspinatus tendon with partial-thickness tears: an analysis using two-dimensional finite element model. J Shoulder Elbow Surg, 2006, 15: 100-105.

[31]

M. Eduard, V. Daniel, B. Titi, et al., A novel implant regarding transcondylar humeral fractures stabilization. A comparative study of two approaches. Procedia Eng, 2014, 69: 1201-1208.

[32]

J. Wolff, N. Narra, A.K. Antalainen, et al., Finite element analysis of bone loss around failing implants. Mater Des, 2014, 61: 177-184.

[33]

M. Eduard, V. Daniel, B. Titi, et al., A novel implant regarding transcondylar humeral fractures stabilization. A comparative study of two approaches. Procedia Eng, 2014, 69: 1201-1208.

Nano Biomedicine and Engineering
Pages 272-289
Cite this article:
Keddar B, Aour B, Zahaf S, et al. Static Study and Finite Element Analysis of a New Method of Fixation of a Medial Humerus Fracture by an Intramedullary Nailing System Analyzed by the ANSYS Workbench 16.2 Calculus Code. Nano Biomedicine and Engineering, 2019, 11(3): 272-289. https://doi.org/10.5101/nbe.v11i3.p272-289

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Received: 29 April 2019
Accepted: 11 August 2019
Published: 16 August 2019
© Brahim Keddar, Benaoumer Aour, Samir Zahaf, Chetti Boualem, Fouzia Bouchakour, and Zahra Najafi Vafa.

This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

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