Digital tracking algorithm reveals the influence of structural irregularities on joint movements in the human cervical spine
Disc height loss and osteophytes change the local mechanical environment in the spine; while previous research has examined kinematic dysfunction under degenerative change, none has looked at the influence of disc height loss and osteophytes throughout movement. Twenty patients with pain related to...
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Veröffentlicht in: | Clinical biomechanics (Bristol) 2018-07, Vol.56, p.11-17 |
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Zusammenfassung: | Disc height loss and osteophytes change the local mechanical environment in the spine; while previous research has examined kinematic dysfunction under degenerative change, none has looked at the influence of disc height loss and osteophytes throughout movement.
Twenty patients with pain related to the head, neck or shoulders were imaged via videofluoroscopy as they underwent sagittal-plane flexion and extension. A clinician graded disc height loss and osteophytes as “severe/moderate”, “mild”, or “none”. A novel tracking algorithm quantified motions of each vertebra. This information was used to calculate intervertebral angular and shear displacements. The digital algorithm made it practical to track individual vertebrae in multiple patients through hundreds of images without bias.
Cases without height loss/osteophytes had a consistent increase in intervertebral angular displacement from C2/C3 to C5/C6, like that of healthy individuals, and mild height losses did not produce aberrations that were systematic or necessarily discernable. However, joints with moderate to severe disc height loss and osteophytes exhibited reduced range of motion compared to adjacent unaffected joints in that patient and corresponding joints in patients without structural irregularities.
Digitally-obtained motion histories of individual joints allowed anatomical joint changes to be linked with changes in joint movement patterns. Specifically, disc height loss and osteophytes were found to influence cervical spine movement in the sagittal plane, reducing angular motions at affected joints by approximately 10% between those with and without height loss and osteophytes. Further, these joint changes were associated with perturbed intervertebral angular and shear movements.
•Structural irregularities could influence cervical spine kinematics.•Patients were imaged by videofluoroscopy during flexion and extension movements.•A novel digital tracking algorithm quantified the full range of vertebrae movement.•Moderate and severe disc height loss and osteophytes reduced joint motion.•Disc height loss and osteophytes appear to produce aberrant cervical spine movements. |
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ISSN: | 0268-0033 1879-1271 |
DOI: | 10.1016/j.clinbiomech.2018.04.015 |