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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

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

Abstract

Keywords

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