Biomedical Engineering Reference
In-Depth Information
5. The percentage variation in total deformation for different angles for different
age group of male patients is found to be more in 32 years than in 17 years, and
the least variation is found in 40 years.
6. For same body weight, maximum deformation is found to be at the age of
40 years, then 17 years, and least deformation at 32 years in male right femur
for both the inclination angles.
Acknowledgments The authors would like to thank Dr. (Mrs.) Shobha Katheria, Principal
Medical Officer, Ordnance Factory Hospital, Itarsi, M.P. India, Dr Rakesh Tirkey, Assistant
Professor of Medical College, Jabalpur, M.P, India, and Dr. Pushpraj Bhatele, for providing
medical imaging data and supporting our work.
Conflict of Interest Statement
None of the authors have any conflict of interest to declare that
could bias the presented work.
References
1. Gdoutos EE, Raftopoulos DD, Baril JD (1982) A critical review of the biomechanical stress
analysis of the human femur. J Biomater 3:2-8
2. Nather A, Ong HJC, Aziz Z (2005) Bone grafts and bone substitutes: basic science and
clinical applications, structure of bone. World Scientific Publishing Co. Pte. Ltd 5, Singapore
3. Rohlmann A, Mossner U, Bergmann G, Kolbel R (1982) Finite element analysis and
experimental investigation of stresses in a femur. J Biomed Eng 4:242-246
4. Wille H, Rank E, Yosibash Z (2012) Prediction of the mechanical response of the femur with
uncertain elastic properties. J Biomech. Accepted in Feb 2012
5. Grassi L, Schoileo E, Taddei F, Zani L, Juszczyk M, Cristofolini L, Viceconti M (2012)
Accuracy of finite element predictions in sideways load configurations for the proximal
human femur. J Biomech 45:394-399
6. Trabelsi N, Yosibash Z, Milgrom C (2009) Validation of subject-specific automated p-FE
analysis of the proximal femur. J Biomech 42:234-241
7. Yosibash Z, Trabelsi N, Milgrom C (2007) Reliable simulations of the human proximal
femur
by
high-order
finite
element
analysis
validated
by
experimental
observations.
J Biomech 40(16):3688-3699
8. Yosibash Z, Padan R, Joscowicz L, Milgrom C (2007) A CT-based high-order finite element
analysis of the human proximal femur compared to in vitro experiments. ASME J Biomech
Eng 129(3):297-309
9. Taylor ME, Tanner KE, Freeman MA, Yettram AL (1996) Stress and strain distribution
within the intact femur: compression or bending? Med Eng Phys, Elsevier Science Ltd
18(2):122-131
10. Jun-hai Z, Shu-fang MA, Wue-ying WEI (2009) Finite element analysis of femur stress under
bending moment and compression load. IEEE
11. Bitsakos C, Kerner J, Fisher I, Amis AA (2005) The effect of muscle loading on the
simulation of bone remodelling in the proximal femur. J Biomech 38:133-139
12. Duda GN, Schneider E, Chao EYS (1997) Internal forces and moments in the femur during
walking. J Biomech 30(9):933-941
13. Simoes JA, Vaz MA, Blatcher S, Taylor M (2000) Influence of head constraint and muscle
forces on the strain distribution within the intact femur. Med Eng Phys 22:453-459
14. Brand RA, Crowninshield RD, Wittstock CE, Pederson DR, Clark CR, Van Krieken FM
(1982) A model of lower extremity muscular anatomy. J Biomech 104:304-310
Search WWH ::




Custom Search