Calculating the 2D motion of lumbar vertebrae using splines.

In this study we investigate the use of splines and the ICP method [Besl, P., McKay, N., 1992. A method for registration of 3d shapes. IEEE Transactions on Pattern Analysis and Machine Intelligence 14, 239-256.] for calculating the transformation parameters for a rigid body undergoing planar motion parallel to the image plane. We demonstrate the efficacy of the method by estimating the finite centre of rotation and angle of rotation from lateral flexion/extension radiographs of the lumbar spine. In an in vitro error study, the method displayed an average error of rotation of 0.44 +/- 0.45 degrees, and an average error in FCR calculation of 7.6 +/- 8.5 mm. The method was shown to be superior to that of Crisco et al. [Two-dimensional rigid-body kinematics using image contour registration. Journal of Biomechanics 28(1), 119-124.] and Brinckmann et al. [Quantification of overload injuries of the thoracolumbar spine in persons exposed to heavy physical exertions or vibration at the workplace: Part i - the shape of vertebrae and intervertebral discs - study of a yound, healthy population and a middle-aged control group. Clinical Biomechanics Supplement 1, S5-S83.] for the tests performed here. In general, we believe the use of splines to represent planar shapes to be superior to using digitised curves or landmarks for several reasons. First, with appropriate software, splines require less effort to define and are a compact representation, with most vertebra outlines using less than 30 control points. Second, splines are inherently sub-pixel representations of curves, even if the control points are limited to pixel resolutions. Third, there is a well-defined method (the ICP algorithm) for registering shapes represented as splines. Finally, like digitised curves, splines are able to represent a large class of shapes with little effort, but reduce potential segmentation errors from two dimensions (parallel and perpendicular to the image gradient) to just one (parallel to the image gradient). We have developed an application for performing all the necessary computations which can be downloaded from http://www.claritysmart.com.

[1]  J M Muggleton,et al.  Insights into the measurement of vertebral translation in the sagittal plane. , 1998, Medical engineering & physics.

[2]  Vijay K. Goel,et al.  The Consistency and Accuracy of Roentgenograms for Measuring Sagittal Translation in the Lumbar Vertebral Motion Segment: An Experimental Model , 1990 .

[3]  H. Stockdale,et al.  Flexion and extension radiography of the lumbar spine: a comparison with lumbar discography. , 1983, Clinical radiology.

[4]  J. Atha,et al.  Quantification of overload injuries to thoracolumbar vertebrae and discs in persons exposed to heavy physical exertions or vibration at the work-place The shape of vertebrae and intervertebral discs - study of a young, healthy population and a middle-aged control group. , 1994, Clinical biomechanics.

[5]  D. Hukins,et al.  Measurement of lumbar spinal flexion-extension kinematics from lateral radiographs: simulation of the effects of out-of-plane movement and errors in reference point placement. , 1998, Medical engineering & physics.

[6]  J H Challis,et al.  Estimation of the finite center of rotation in planar movements. , 2001, Medical engineering & physics.

[7]  M. Pfeiffer,et al.  Analysis of a computer-assisted technique for measuring the lumbar spine on radiographs: correlation of two methods. , 2003, Academic radiology.

[8]  F. Veldpaus,et al.  Finite centroid and helical axis estimation from noisy landmark measurements in the study of human joint kinematics. , 1985, Journal of biomechanics.

[9]  Yvan Petit,et al.  Spinal shape changes resulting from scoliotic spine surgical instrumentation expressed as intervertebral rotations and centers of rotation. , 2004, Journal of biomechanics.

[10]  P Brinckmann,et al.  Precision measurement of segmental motion from flexion-extension radiographs of the lumbar spine. , 1996, Clinical biomechanics.

[11]  V. Goel,et al.  1990 Volvo Award in Clinical Sciences: The Consistency and Accuracy of Roentgenograms for Measuring Sagittal Translation in the Lumbar Vertebral Motion Segment: An Experimental Model , 1990, Spine.

[12]  F. Veldpaus,et al.  A least-squares algorithm for the equiform transformation from spatial marker co-ordinates. , 1988, Journal of biomechanics.

[13]  S. Woo,et al.  A rigid-body method for finding centers of rotation and angular displacements of planar joint motion. , 1987, Journal of biomechanics.

[14]  O'Brien Jp,et al.  Experimentally induced hypermobility in the lumbar spine. A pathologic and radiologic study of the posterior ligament and annulus fibrosus. , 1979 .

[15]  P Brinckmann,et al.  Sagittal plane segmental motion of the cervical spine. A new precision measurement protocol and normal motion data of healthy adults. , 2002, Clinical biomechanics.

[16]  Paul J. Besl,et al.  A Method for Registration of 3-D Shapes , 1992, IEEE Trans. Pattern Anal. Mach. Intell..

[17]  B. McCane,et al.  On calculating the finite centre of rotation for rigid planar motion. , 2005, Medical engineering & physics.

[18]  W. Frobin,et al.  Precision measurement of disc height, vertebral height and sagittal plane displacement from lateral radiographic views of the lumbar spine. , 1997, Clinical biomechanics.

[19]  Nikolai Bogduk,et al.  Abnormal Instantaneous Axes of Rotation in Patients with Neck Pain , 1992, Spine.

[20]  C. Spoor,et al.  Rigid body motion calculated from spatial co-ordinates of markers. , 1980, Journal of biomechanics.

[21]  P Brinckmann,et al.  Assessment of Sagittal Plane Segmental Motion in the Lumbar Spine: A Comparison Between Distortion‐Compensated and Stereophotogrammetric Roentgen Analysis , 1998, Spine.

[22]  K. Sairyo,et al.  Normal and Spondylolytic Pediatric Spine Movements With Reference to Instantaneous Axis of Rotation , 2002, Spine.

[23]  M M Panjabi,et al.  Optimal marker placement for calculating the instantaneous center of rotation. , 1994, Journal of biomechanics.

[24]  J W Frymoyer,et al.  Segmental Motion and Instability , 1987, Spine.

[25]  N. Bogduk,et al.  A Biological Basis for Instantaneous Centres of Rotation of the Vertebral Column , 1995, Proceedings of the Institution of Mechanical Engineers. Part H, Journal of engineering in medicine.

[26]  J. Duncan,et al.  Two-dimensional rigid-body kinematics using image contour registration. , 1995, Journal of biomechanics.