Multibody Modeling of the Cervical Spine in the Simulation of Flexion-Extension after Disc Arthroplasty

Abstract

This paper presents a three-dimensional (3D) multibody model of the cervical spine implanted with an artificial disc. The model was used to predict prosthesis placement influence on the resulting cervical kinematics in a series of patients. The vertebral tract modeled was the C2–C7, and the vertebral geometries were reconstructed from computed tomography (CT) images. The model was used to simulate the flexion-extension motion of the cervical spine in 10 patients implanted with the Prestige commercial disc prosthesis at a single level. For each patient, a geometrical model of the prosthesis was scaled and included in the multibody model to match the size and positioning of the actual prosthesis, as assessed on post-operative radiographs. Simulations of complete flexion-extension were carried out for each patient, and the main parameters relevant to the motion of the vertebral bodies were calculated and compared to data measured from dynamic post-operative radiographs. At the implanted level, the simulated ranges of motion generally agreed with the measured ones, with an average deviation <2 degrees. In addition, the simulated relative angles between vertebral bodies agreed with the measured ones, with minor average differences of 1.2, 1.8 and 2.1 degrees in full flexion, neutral alignment and full extension, respectively. The cervical kinematics after prosthesis placement was influenced both by the design of the artificial joint and by surgical positioning. Therefore, the model presented can be used both to support pre-operative planning for disc arthroplasty and in the optimization of new prostheses design.

Keywords

Cervical spine Intervertebral disc Artificial disc Prosthesis Multibody model

References

Eck

J.C.

, Humphreys

S.C.

, Lim

T.H.

. Biomechanical study on the effect of cervical spine fusion on adjacent-level intradiscal pressure and segmental motion. Spine 2002; 27: 2431–4.

Cummins

B.H.

, Robertson

J.T.

, Gill

S.S.

Surgical experience with an implanted artificial cervical joint. J Neurosurg 1998; 88: 943–8.

Sekhon

L.H.

Two-level artificial disc placement for spondylotic cervical myelopathy. J Clin Neurosci 1994; 11: 412–5.

Dimnet

, Pasquet

Cervical spine motion in the sagittal plane: Kinematic and geometric parameters. J Biomech 1982; 15: 959–69.

Penning

Differences in anatomy, motion, development and aging of the upper and lower cervical disk segments. Clin Biomech (Bristol, Avon) 1998; 3: 37–47.

Takeshima

, Omokawa

, Takaoka

, Araki

, Ueda

, Takakura

Sagittal alignment of cervical flexion and extension. Spine 2002; 27: 348–55.

Wigfield

C.C.

, Gill

, Nelson

, Langdon

, Metcalf

, Robertson

Influence of an artificial cervical joint compared with fusion on adjacent-level motion in the treatment of degenerative cervical disc disease. J Neurosurg 2002; 96(suppl): S17–21.

Kettler

, Schmitt

, Simon

. A new acceleration apparatus for the study of whiplash with human cadaveric cervical spine specimens. J Biomech 2004; 37: 1607–13.

Panjabi

M.M.

, Cholewicki

, Nibu

, Grauer

, Vahldiek

Capsular ligament stretches during in vitro whiplash simulations. J Spinal Disord 1998; 11: 227–32.

10.

Panjabi

M.M.

, Pearson

A.M.

, Ito

, Ivancic

P.C.

, Wang

J.L.

Cervical spine curvature during simulated whiplash. Clin Biomech (Bristol, Avon) 2004; 19: 1–9.

11.

Shea

, Edwards

W.T.

, White

A.A.

, Hayes

W.C.

Variations of stiffness and strength along the human cervical spine. J Biomech 1991; 24: 95–107.

12.

DiAngelo

D.J.

, Roberston

J.T.

, Metcalf

N.H.

, McWay

B.J.

, Champ Davis

Biomechanical testing of an artificial cervical joint and an anterior cervical plate. J Spinal Disord Tech 2003; 16: 314–23.

13.

McAfee

P.C.

, Cunningham

, Dmitriev

. Cervical disc replacement-porous coated motion prosthesis: a comparative biomechanical analysis showing the key role of the posterior longitudinal ligament. Spine 2003; 28: 176–85.

14.

Kumaresan

, Yoganandan

, Pintar

F.A.

Finite element modeling approaches of human cervical spine facet joint capsule. J Biomech 1998; 31: 371–6.

15.

Kumaresan

, Yoganandan

, Pintar

F.A.

Finite element analysis of the cervical spine: A material property sensitivity study. Clin Biomech (Bristol, Avon) 1999; 14: 41–53.

16.

Yoganandan

, Kumaresan

, Voo

, Pintar

F.A.

, Larson

S.J.

Finite element modeling of the C4–C6 cervical spine unit. Med Eng Phys 1996; 18: 569–74.

17.

Yoganandan

, Kumaresan

, Pintar

F.A.

Biomechanics of the cervical spine Part 2. Cervical spine soft tissue responses and biomechanical modelling. Clin Biomech (Bristol, Avon) 2001; 16: 1–27.

18.

Brolin

, Halldin

Development of a finite element model of the upper cervical spine and a parameter study of ligament characteristics. Spine 2004; 29: 376–85.

19.

Garcia

, Ravani

A biomechanical evaluation of whiplash using a multi-body dynamic model. J Biomech Eng 2003; 125: 254–65.

20.

Huang

S.C.

Numerical simulations of human headneck dynamics. Biomed Mater Eng 1999; 9: 61–71.

21.

Linder

A new mathematical neck model for a low-velocity rear-end impact dummy: Evaluation of components influencing head kinematics. Accid Anal Prev 2000; 32: 261–9.

22.

Kecskeméthy

, Lange

, Grabner

Simulating cervical vertebrae motion using elementary contact pairs (1999). Available online at: http://www.mechanik.uni-duisburg.de/downloads/Publikationen/Multibodygraz99.pdf (Accessed June 28, 2005).

23.

Ouyang

, Yang

G.T.

, Wu

W.Z.

, Zhu

Q.A.

, Zhong

S.Z.

Biomechanical characteristics of human trabecular bone. Clin Biomech (Bristol, Avon) 1997; 12: 522–4.

24.

Amevo

, Worth

, Bogduk

Instantaneous axes of rotation of the typical cervical motion segments: a study in normal volunteers. Clin Biomech (Bristol, Avon) 1991; 6: 111–7.

25.

Bogduk

, Mercer

Biomechanics of the cervical spine. I: Normal kinematics. Clin Biomech (Bristol, Avon) 2000; 15: 633–48.

26.

Aho

, Vartianen

, Salo

Segmentary antero-posterior mobility of the cervical spine. Ann Med Intern Fenn 1955; 44: 287–99.

27.

Bhalla

S.K.

, Simmons

E.H.

Normal ranges of intervertebral joint motion of the cervical spine. Can J Surg 1969; 12: 181–7.

28.

Lind

, Sihlbom

, Nordwall

, Malchau

Normal ranges of motion of the cervical spine. Arch Phys Med Rehabil 1989; 70: 692–5.

29.

Dvorak

, Froehlich

, Penning

, Baumgartner

, Panjabi

M.M.

Functional radiographic diagnosis of the cervical spine: Flexion/extension. Spine 1988; 13: 748–55.

30.

Malmstrom

E.M.

, Karlberg

, Fransson

P.A.

, Melander

, Magnusson

Primary and coupled cervical movements: the effects of age, gender, and body mass index. A 3-dimensional movement analysis of a population without symptoms of neck disorders. Spine 2006; 15; 31: 44–50.

31.

Buckwalter

J.A.

Aging and degeneration of the human intervertebral disc. Spine 1995; 20: 1307–14.

32.

Kumaresan

, Yoganandan

, Pintar

F.A.

, Maiman

D.J.

, Goel

V.K.

Contribution of disc degeneration to osteophyte formation in the cervical spine: A biomechanical investigation. J Orthop Res 2001; 19: 977–84.

33.

van Mameren

, Sanches

, Beurgsgens

, Drukker

Cervical spine motion in the sagittal plane II. Position of segmental averaged instantaneous centers of rotation - a cineradiographic study. Spine 1992; 17: 467–74.

34.

White

A.A.

, Panjabi

M.M.

Kinematics of the spine. In: Clinical biomechanics of the spine. Philadelphia: JB Lippincott Company, 1978.