1887
Volume 2014, Issue 1
  • E-ISSN: 2223-506X

ملخص

The human knee joint has a three-dimensional geometry with multiple body articulations that produce complex mechanical responses under loads that occur in everyday life and sports activities. Knowledge of the complex mechanical interactions of these load-bearing structures is of use when treatments of relevant diseases are evaluated and assisting devices are designed. Numerical tools, such as the finite element analysis, are suitable for such modeling and can be used with success by students as well as experienced researchers alike. These tools have been used to develop an accurate human knee joint model to study its mechanical behavior.

This model has been used to study the kinematics of a PCL deficient human knee joint. Both linear and non-linear material models were developed for comparison purposes.

The main objective of this study is to verify developed knee joint models. Displacement results for static load cases presented in previous modeling work were used. Results were in agreement with those of the study employed for validation.

Results were compared with work from previous authors' studies, for the intact and the ACL deficient human knee joint. This aimed to understand the behavior of the knee joint and to verify that the model produced results in agreement with real life knee joint behavior with these types of injuries, as described in literature.

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References

  1. Lo JH, Muller O, Wunschel M, Bauer S, Wulker N. Forces in anterior cruciate ligament during simulated weight-bearing flexion with anterior and internal rotational tibial load. J Biomech. 2008; 41:9:18551861.
    [Google الباحث العلمي]
  2. Adler GG. All-Inside posterior cruciate ligament reconstruction with a GraftLink. Arthrosc Tech. 2013; 2:2:15.
    [Google الباحث العلمي]
  3. Chandrasekaran S, Ma D, Scarvell JM, Woods KR, Smith PN. A review of the anatomical, biomechanical and kinematic findings of posterior cruciate ligament injury with respect to non-operative management. Knee. 2012; 19:6:738745.
    [Google الباحث العلمي]
  4. Rosenthal MD, Rainey CE, Tognoni A, Worms R. Evaluation and management of posterior cruciate ligament injuries. Phys Ther Sport. 2012; 13:4:196208.
    [Google الباحث العلمي]
  5. Slullitel D, Galan H, Ojeda V, Seri M. Double-bundle “all-inside” posterior cruciate ligament reconstruction. Arthrosc Tech. 2012; 1:2:e141e148.
    [Google الباحث العلمي]
  6. Harner CD, Hoher J. Evaluation and treatment of posterior cruciate ligament injuries. Am J Sports Med. 1998; 26:3:471482.
    [Google الباحث العلمي]
  7. Kennedy JC, Grainger RW. The posterior cruciate ligament. J Trauma. 1967; 7:3:367377.
    [Google الباحث العلمي]
  8. White EA, Patel DB, Matcuk GR, Forrester DM, Lundquist RB, Rick Hatch GF III, Vangsness CT, Gottsegen CJ. Cruciate ligament avulsion fractures: Anatomy, biomechanics, injury patterns, and approach to management. Emerg Radiol. 2013; 20:5:429440.
    [Google الباحث العلمي]
  9. Baldwin MA, Clary CW, Fitzpatrick CK, Deacy JS, Maletsky LP, Rullkoetter PJ. Dynamic finite element knee simulation for evaluation of knee replacement mechanics. J Biomech. 2012; 45:3:474483.
    [Google الباحث العلمي]
  10. Abdullah AH, Rashid H, Mahmud J, Othman MF, Ibrahim MWA-J. Effects of screw materials in anterior cruciate ligament reconstruction using finite element analysis. Procedia Eng. 2012; 41::16141619.
    [Google الباحث العلمي]
  11. Park HS, Ahn C, Fung DT, Ren Y, Zhang LQ. A knee-specific finite element analysis of the human anterior cruciate ligament impingement against the femoral intercondylar notch. J Biomech. 2010; 43:10:20392042.
    [Google الباحث العلمي]
  12. Peña E, Calvo B, Martínez MA, Doblaré M. A three-dimensional finite element analysis of the combined behavior of ligaments and menisci in the healthy human knee joint. J Biomech. 2006; 39:9:16861701.
    [Google الباحث العلمي]
  13. Weiss JA, Gardiner JC, Ellis BJ, Lujan TJ, Phatak NS. Three-dimensional finite element modeling of ligaments: Technical aspects. Med Eng Phys. 2005; 27:10:845861.
    [Google الباحث العلمي]
  14. Zelle J, Van der Zanden AC, De Waal Malefijt M, Verdonschot N. Biomechanical analysis of posterior cruciate ligament retaining high-flexion total knee arthroplasty. Clin Biomech. 2009; 24:10:842849.
    [Google الباحث العلمي]
  15. Yoon KH, Kim YH, Ha JH, Kim K, Park WM. Biomechanical evaluation of double bundle augmentation of posterior cruciate ligament using finite element analysis. Clin Biomech. 2010; 25:10:10421046.
    [Google الباحث العلمي]
  16. Ramaniraka NA, Terrier A, Theumann N, Siegrist O. Effects of the posterior cruciate ligament reconstruction on the biomechanics of the knee joint: A finite element analysis. Clin Biomech. 2005; 20:4:434442.
    [Google الباحث العلمي]
  17. Zelle J, Heesterbeek PJC, De Waal Malefijt M, Verdonschot N. Numerical analysis of variations in posterior cruciate ligament properties and balancing techniques on total knee arthroplasty loading. Med Eng Phys. 2010; 32:7:700707.
    [Google الباحث العلمي]
  18. Moglo KE, Shirazi-Adl A. Biomechanics of passive knee joint in drawer: Load transmission in intact and ACL-deficient joints. Knee. 2003; 10:3:265276.
    [Google الباحث العلمي]
  19. Moglo KE, Shirazi-Adl A. On the coupling between anterior and posterior cruciate ligaments, and knee joint response under anterior femoral drawer in flexion: A finite element study. Clin Biomech. 2003; 18:8:751759.
    [Google الباحث العلمي]
  20. Cowin SC. Bone mechanics. Boca Raton: CRC Press 1989.
    [Google الباحث العلمي]
  21. Kingsmill VJ, Boyde A. Variation in the apparent density of human mandibular bone with age and dental status. J Anatomy. 1998; 192::233244.
    [Google الباحث العلمي]
  22. Woo SLY, Almarza AJ, Liang R, Fisher MB. Functional tissue engineering of ligament and tendon injuries. In: Mao JMikos AGVunjak-Novakovic GAntala A, eds. Translational approaches in tissue engineering and regenerative medicine. London: Artech House 2007:p.163.
    [Google الباحث العلمي]
  23. Chandrashekar N, Slauterbeck J, Hashemi J. Sex-based differences in the anthropometric characteristics of the anterior cruciate ligament and its relation to intercondylar notch geometry: A cadaveric study. Am J Sports Med. 2005; 33::14921498.
    [Google الباحث العلمي]
  24. McDermott ID, Masouros SD, Amis AA. Biomechanics of the menisci of the knee. Curr Orthopaed. 2008; 22:3:193201.
    [Google الباحث العلمي]
  25. Haut Donahue TL, Hull ML, Rashid MM, Jacobs CR. A finite element model of the human knee joint for the study of tibio-femoral contact. J Biomech Eng. 2002; 124:3:273280.
    [Google الباحث العلمي]
  26. Fithian DC, Kelly MA, Mow VC. Material properties and structure-function relationships in the menisci. Clin Orthopaed Relat Res. 1990; 252::1931.
    [Google الباحث العلمي]
  27. Bendjaballah MZ, Shirazi-Adl A, Zukor DJ. Biomechanical response of the passive human knee joint under anterior-posterior forces. Clin Biomech. 1998; 13:8:625633.
    [Google الباحث العلمي]
  28. Bendjaballah MZ, Shirazi-Adl A, Zukor DJ. Biomechanics of the human knee joint in compression: Reconstruction, mesh generation and finite element analysis. Knee. 1995; 2:2:6979.
    [Google الباحث العلمي]
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  • نوع المستند: Research Article
الموضوعات الرئيسية biomechanicsfinite element modellingknee ligament repair and posterior cruciate ligament
هذه الخانة مطلوبة
يُرجى إدخال عنوان بريد إلكتروني صالح
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