Effect of Screw Diameter in Femoral Fracture Fixation Modeled by Finite Element Method
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D. T. Reilly and A. H. Burstein, “The Elastic and Ultimate Properties of Compact Bone Tissue,” J Biomech 8, pp 384-405, 1975.
B. D. Ratner, A. S. Hoffman, F. J. Schoen, and J. E. Lemons, “Biomaterials Science: An Introduction to Materials in Medicine,” Vol. 2, New York Academic Press, 1996.
A. Koistinen, “Improvement of The Orthopaedic Bone Screws by DLC Coatings,” Publications of The University of Eastern Finland, Dissertation in Forestry and Natural Science, No 89, Nov. 2012.
B. K. Kwon, D. J. Goertzen, P. J. O’Brien, H. M. Broekhuyse, and T. R. Oxland, “Biomechanical Evaluation of Proximal Humeral Fracture Fixation Supplemented with Calcium Phosphate Cement,” Journal of Bone and Joint Surgery America 84, pp 951–961, 2002.
C. Cuny, M. M. Scarlat, M. Irrazi, P. Beau, V. Wenger, N. Ionescu, and A. Berrichi, “The Telegraph Nail for Proximal Humeral Fractures: A Prospective Four Year Study,” Journal of Shoulder and Elbow Surgery 17, pp 539–545, 2008.
R. W. Gaines Jr, “The Use of Pedicle–Screw Internal Fixation For The Operative Treatment of Spinal Disorders,” The Journal of Bone and Joint Surgery (American) 82, pp 1458-1476, 2000.
F. A. Barber, M. A. Herbert, R. C. Beavis, and F. Barrera Oro, “Suture Anchor Materials, Eyelets, and Designs: Update 2008.” Arthroscopy: The Journal of Arthroscopic and Related Surgery 24, pp 859–867, 2008
K. C. Owsley and J. T. Gorczyca, ”Displacement/Screw Cutout after Open Reduction and Locked Plate Fixation of Humeral Fractures,” Journal of Bone and Joint Surgery America 90, pp 233–240, 2008.
P. S. D. Nasr, et al., “Effect of Screw Position on Bone Tissue Differentiation Within a Fixed Femoral Fracture,” Journal of Biomedical Science and Engineering, pp 71–83, 2013.
M. O. Kaman, N. Celik, and S. Karakuzu, “Numerical Stress Analysis of The Plates Used to Treat The Tibia Bone Fracture,” Journal of Applied Mathematics and Physics, pp 304-309, May 2014.
C. H. Lee, et al., “Simulation-based Particle Swarm Optimization and Mechanical Validation of Screw Position and Number for The Fixation Stability of A Femoral Locking Compression Plate,” Journal Medical Engineering and Physics, pp 57-64, 2014.
B. Sepheri, E. Taheri, and R. Ganji, “Biomechanical Analysis of Diversified Screw Arrangement on 11 Holes Locking Compression Plate Considering Time-Varying Properties of Callus”, Elsevier Ltd, 2013.
P. S. D. Patel, D. E. T. Shepherd, and D. W. L. Hukins, “The Effect of Screw Insertition Angle and Thread Type on The Pullout Strength of Bone Screw in Normal and Osteoporotic Cancellous Bone Models,” Journal of Medical Engineering and Physics, Elsevier, 2010.
H. K. Uhthoff, P. Poitras, and D. S. Backman, “Internal Plate Fixation of Fractures: Short History and Recent Developments,” Journal of Orthopedic Science 11, pp 118–26, 2006.
M. S. Ali, T.A. French, G. W. Hastings, T. Rae, N. Rushton, E. R. Ross, et al., “Carbon Fibre Composite Bone Plate. Development, Evaluation and Early Clinical Experience,” Journal of Bone and Joint Surgery 72B, pp 586–91, 1990.
N. Setiawan, “Peningkatan Kebutuhan Protein Hewani di Jawa Barat : Dampak dari Perubahan Struktur Penduduk”, Jurnal Ilmu Ternak Vol 8 No.1, pp 65-71, 2008.
A. N. Hughes and B. A. Jordan, “The Mechanical Properties of Surgical Bone Screws and Some Aspects of Insertion Practice,” Journal of Injury, pp 25-38, 1972.
A. Dubov, et al., “The Biomechanics of Plate Repair of Periprosthetic Femur Fractures Near The Tip of a Total Hip Implant: The Effect of Cable-Screw Position." in Proceedings of the Institution of Mechanical Engineers, pp. 857-865, 2011.
S. E. Asnis, et al., “Cancellous Bone Screw Thread Design and Holding Power,” Journal of Orthopaedic Trauma, pp 391-398, 1996.
J. R. Chapman, et al., “Factors Affecting The Pullout Strength of Cancellous Bone Screws,” Journal of Biomedical Engineering-Transaction of Asme, pp 391-398, 1996.
T. A. Decoster, et al., “Cancellous Bone Screw Thread Design and Holding Power,” Clinical Research, pp A213-A213, 1990.
J. D. Thompson, J. B. Benjamin, and J. A. Szivek, “Pullout Strengths of Cannulated and Noncannulated Cancallous Bone Screwa,” Clinical Orthopaedics and Related Research, pp 241-249, 1997.
R. E. Tooms, “Amputations of Lower Extremity, in Campbell’s Operative Orthopaedics,” A. H. Crenshaw, Editor, pp 740-760, 1992.
A. Gefen, “Optimizing The Biomechanical Compatibility of Orthopedic Screws for Bone Fracture Fixation,” Journal of Medical Engineering and Physics, pp 337-347, 2002.
R.M. Pilliar, et al., “Bone Ingrowth and Stress Shielding with A Porous Surface Coated Fracture Fxation Plate,” J. Biomed. Mater. Res 13, pp 799, 1979.
G. Rouhi, “Biomechanics of Osteoporosis: The Importance of Bone Resorption and Remodeling Processes,” InTech, pp 59, 2012.
K. Haase, “Prediction of Stress Shielding Around An Orthopedic Screw: Using Stress and Strain Energy Density as Mechanical Stimuli,” Computers in Biology and Medicine 43, pp 1748–1757, 2013.
S. Benli, S. Aksoy, H. Havitcioglu, and M. Kucuk, “Evaluation of Bone Plate with Low-stiffness Material in terms of Stress Distribution,” Journal of Biomkechanics 41, pp 3229–3235, 2008.
DOI: http://dx.doi.org/10.12962/j23546026.y2017i2.2336
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