MYWEBSPINE Customized expert system for presurgical planning and evaluation of spine. ORTHOSIM The European Simulation Service Provider for Orthopaedic Surgery

References

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Below a list of references that are relevant for the use of simulation in the clinical praxis or in the implant design office.

Specific Orthosim references

  1. Lafage V, Mitulescu A, Mosnier T. Devaspim: a European project for the design of an internet based tool for preoperative planning of lumbar spinal surgery. ARGOS Spinenews. 2005 April; 42-45. .PDF
  2. Mosnier T, Lafage V, Rillardon L, Irujo M, Pratt J, Skalli W, Finite Element Simulation for the prediction of mechanical failure in the lumbar spine surgery, CMBBE 2006 (7th International Symposium on Computer Methods in Biomechanics and Biomedical engineering), Antibes (France), 24th March 2006. .PDF
  3. Mosnier T, Lafage V, Rillardon L, Irujo M, Pratt J, Skalli W, Finite Element Simulation for the prediction of mechanical failure in the lumbar spine surgery, ISSLS 2006 (The International Society for the Study of the Lumbar Spine), Bergen, Norway, 14th June 2006. .PDF
  4. Mosnier T, Lafage V, Rillardon L, Irujo M, Pratt J, Skalli W, Finite Element Simulation for the prediction of mechanical failure in the lumbar spine surgery, CMBBE 2006 (7th International Symposium on Computer Methods in Biomechanics and Biomedical engineering), Antibes (France), 24th March 2006. .PDF
  5. Skalli W, Mosnier T. Mécanique et sciences du vivant au service de la chirurgie. Arts et Métiers Magazine. 2005 Sept; 10-11. .PDF

General scientific references

  1. Abumi K, Panjabi MM, Duranceau. J. Biomechanical evaluation of spinal fixation devices. Part. III. Stability provided by six spinal fixation devices and interbody bone graft. Spine 1989;14(11):1249-1256.
  2. Skalli W, Mosnier T. Mécanique et sciences du vivant au service de la chirurgie. ARGOS Spinenews. 2005 April; 42-45.
  3. Atienza, C.M. (2000). Definición de un modelo para la evaluación y el diseño de sistemas de fijación de raquis en base a métodos analíticos. Thesis Doctoral. UPV, Valencia.
  4. Atienza, C.M. y Corell, A. (2000) Instituto de Biomecánica de Valencia NetSpine/IBV?: Sistema de apoyo al diseño y planificación preoperatoria de implantes de raquis lumbar. 28: 5-8.
  5. Atienza, C.M., Prat, J.M., Peris, J.L., Comín, M., Gómez, A., Mollá, F., Sierra, A. y Cebrián, J.L. (1999). Validación de un modelo de elementos finitos tridimensional del raquis lumbar mediante ensayos in vitro. Rev. Ortop. Traumatol. S1, 41-48.
  6. Belytschko T, Kulak RF, Schultz AB, Galante JO. Finite element stress analysis of an intervertebral disc. J Biomech 1974;7(3):277-285.
  7. Carson WL, Duffield RC, Arendt M, et al. Internal forces and moments in transpedicular spine instrumentation. The 4R-4Bar Linkage Concept. Spine 1990;15(9):893-901.
  8. Cunningham BW, Sefter JC, Shono Y, McAfee PC. Static and Cyclical biomechanical analysis of pedicle screw spinal constructs. Spine 1993;18:1677-1688.
  9. Diop A, Skalli W, Lavaste F. Tests et épreuves biomécaniques incontournables pour le développement d'une nouvelle instrumentation rachidienne. Cahiers d'enseignement de la SOFCOT 1995 53:20-27.
  10. Duffield RC, Carson WL, Chen L, Voth B. Longitudinal element size effect on load sharing, internal loads, and fatigue life on tri-level spinal implant constructs. Spine 1993;18(12):1695-1703.
  11. Farfan, H.F., Cossette, J.W, Robertson GH, Wells RV, Kraus H. (1970) The effects of torsion on the lumbar intervertebral joints: the role of torsion in the production of disc degeneration. J Bone Joint Surg Am Apr;52(3):468-97
  12. Goel VK, Kim YE, Lim TH, Weinstein JN. An analytical investigation of the mechanics of spinal instrumentation. Spine 1988;13(9):1003-1011.
  13. Goel VK, Lim TH, Gwon J, et al. Effects of rigidity of an internal fixation device. A comprehensive biomechanical investigation. Spine 1991;16(S3):S155-161.
  14. Guigui, P., Lambert, P., Lassale, B. and Deburge, A. Long-term outcome at adjacent levels of lumbar arthrodesis. Rev. Chir. Orthop. Reparatrice Appar. Mot. 1997;83(8):685-96.
  15. Kulak, RF, Belytschko TB, Scultz AB, Galante JO. Nonlinear behaviour of the human intervertebral disc under axial load. J Biomech 1976;9(6):377-386.
  16. Lavaste F, Skalli W, Robin S, Roy-Camille R, Mazel C. Three-dimensional geometrical and mechanical modelling of the lumbar spine. J. Biomech. 1992; 25(10):1153-1164.
  17. Lavaste F, Diop A, Skalli W. Fiabilité de l'évaluation expérimentale des implants rachidiens. Rachis, 1993 5(6):273-278.
  18. Lim TH, Eck JC, An HS, et al. Biomechanics of transfixation in pedicle screw instrumentation. Spine 1996;21(19):2224-9.
  19. MediSTAT REPORTS© MDIS Publications Limited. The World Medical Market Fact File 1997.
  20. Ministries of Health and Science and technology (Spain). White Book. I+D+I in the sector of sanitary products.
  21. Nachemson, A. and Morris, J.M. (1964) In vivo measurements of intradiscal pressure. J. Bone Joint Surg. 43, 1077.
  22. Lin MS, Liu YK, Ray G, Nikravesh P. Systems identification for materials properties of the intervertebral joint. J Biomech 1978;11(1-2):1-14.
  23. Panjabi, M.M., Abumi, K. Duranceau, J. y Crisco, J.J. (1988) Biomechanical evaluation of spinal fixations devices II. Stability provided by eight internal fixations devices. Spine 13(10), 1135-1139.
  24. Rohlmann A, Calisse J, Bergmann G, Ulrich W. Internal Spinal Fixator Stifness, stiffness has only a minor influence on stress in the adjacent disc. Spine 1999;24(11):1192-1196.
  25. Sharma M, Langrana N, Rodríguez J. Role of ligaments and facets in lumbar spinal stability. Spine 1995;20(3):887-900.
  26. Shirazi-Adl A, Shrivasta SC, Ahmed AM. Stress analysis of the lumbar disc-body unit in compression: A three-dimensional nonlinear finite element study. Spine 1984;9(2):120-134.
  27. Skalli W, Robin S, Lavaste F, Dubousset JA. Biomechanical Analysis of short Segment Spinal Fixation Using a Three-Dimensional Geometric and Mechanical Model. Spine 1993;18(5):536-545.
  28. Spilker RL. Mechanical behaviour of a simple model of an intervertebral disk under compressive loading. J Biomech 1980;13:895.
  29. Templier A, Skalli W, Demminger L, Manzel C, Lavaste F. Lumbar spinal fixation: The influence of flexural stiffness on anchor loadding. 11th Conference of the ESB 1999, July 8-11 98, Toulouse, France.
  30. Totoribe K, Tajima N, Chosa E. A biomechanical study of posterolateral lumbar fusion using a three-dimensional nonlinear finite element method. J Orthop Sci 1999;4:115-126.
  31. Walker et al 1993, Older people in Europe: social and economic policies. The 1993 report of the European Observatory, Commission of the European Communities, Directorate General V, Employment, Social Affairs, Industrial Relations.
  32. Zucherman J, Hsu K, Picetti G 3d, White A, Wynne G, Taylor L. Clinical efficacy of spinal instrumentation in lumbar degenerative disc disease. Spine 1992 Jul;17(7):834-7.

Related standards

  • ISO/CD 12189-2:2000. Implants for surgery. Mechanical testing of implantable spinal devices. Part 2: Static and fatigue test methods for spinal implants assemblies using corporectomy models.
  • ISO/CD 12189-3: 2000. Implants for surgery. Mechanical testing of implantable spinal devices. Part 3: Evaluation of static and fatigue properties of interconnection mechanisms and subassemblies used in spinal mechanical implants.
  • ISO/CD 12189-5:1998. Spinal implants. Spinal implant testing. Part 5: Static and dynamic test methods for interbody fuSÍon devices.
  • ASTM F1717-96. Standard test Methods for Static and Fatigue for Spinal Implant Constructs in a Corpectomy Model.
  • ASTM F1798-97. Guide for evaluation the static and fatigue properties of interconnection mechanisms and subassemblies used in spinal arthrodesis implants.
  • ASTM F1582-95. Standard terminology relating to spinal implants.
  • ASTM. F2077-01. Test methods for body fusion devices.

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