Abstract
To validate the accuracy of Cone beam computed tomography (CBCT) cervical spine modeling with three dimensional (3D)-3D registration for in vivo measurements of cervical spine kinematics. CBCT model accuracy was validated by superimposition with computed tomography (CT) models in 10 healthy young adults, and then cervical vertebrae were registered in six end positions of functional movements, versus a neutral position, in 5 healthy young adults. Registration errors and six degrees of freedom (6-DOF) kinematics were calculated and reported. Relative to CT models, mean deviations of the CBCT models were < 0.6 mm. Mean registration errors between end positions and the reference neutral position were < 0.7 mm. During flexion–extension (F–E), the translation in the three directions was small, mostly < 1 mm, with coupled LB and AR both < 1°. During lateral bending (LB), the bending was distributed roughly evenly, with coupled axial rotation (AR) opposite to the LB at C1–C2, and minimal coupled F–E. During AR, most of the rotation occurred in the C1–C2 segment (29.93 ± 7.19° in left twist and 31.38 ± 8.49° in right twist) and coupled LB was observed in the direction opposite to that of the AR. Model matching demonstrated submillimeter accuracy in cervical spine kinematics data. The presently evaluated low-radiation-dose CBCT technique can be used to measure 3D spine kinematics in vivo across functional F–E, AR, and LB positions, which has been especially challenging for the upper cervical spine.
Highlights
To validate the accuracy of Cone beam computed tomography (CBCT) cervical spine modeling with three dimensional (3D)-3D registration for in vivo measurements of cervical spine kinematics
Computed tomography (CT) and magnetic resonance imaging (MRI) techniques can be used to obtain 3D in vivo m easurements[16,17], they are performed in subjects that are lying down and without physiological loading
The mean deviation ranges of the six end positions of functional movements from the neutral position for the CBCT model were 0.14–0.67 mm during head F–E (Table 2), 0.15–0.66 mm during lateral bending (LB) (Table 3), and 0.14–0.65 mm during head axial rotation (AR) (Table 4)
Summary
To validate the accuracy of Cone beam computed tomography (CBCT) cervical spine modeling with three dimensional (3D)-3D registration for in vivo measurements of cervical spine kinematics. CBCT model accuracy was validated by superimposition with computed tomography (CT) models in 10 healthy young adults, and cervical vertebrae were registered in six end positions of functional movements, versus a neutral position, in 5 healthy young adults. The presently evaluated low-radiation-dose CBCT technique can be used to measure 3D spine kinematics in vivo across functional F–E, AR, and LB positions, which has been especially challenging for the upper cervical spine. The purpose of the present study was to validate the accuracy of CBCT modeling and a 3D–3D registration technique for the measurement of in vivo cervical spine kinematics. We hypothesize that the technique can be used for segmental kinematic analysis of the cervical spines, especially at the end positions of functional movements
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