Simulation of a Bead Placement Protocol for Follow-up of Thoracic Spinal Fusion Using Radio stereometric Analysis

Study Design Computer simulation to detect intervertebral motion enabling future follow-up of spinal fusions performed on patients with multilevel thoracic scoliosis. Objectives To propose a method using computer simulation to evaluate a radiostereometric analysis (RSA) marker placement protocol for...

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Bibliographic Details
Published in:Spine deformity 2015, Vol.3 (3), p.219-227
Main Authors: Bou-Francis, Antony, Lee, J. Michael, Dunbar, Michael, El-Hawary, Ron
Format: Article
Language:English
Subjects:
Computer Modeling
Medicine & Public Health
Orthopedics
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Summary:Study Design Computer simulation to detect intervertebral motion enabling future follow-up of spinal fusions performed on patients with multilevel thoracic scoliosis. Objectives To propose a method using computer simulation to evaluate a radiostereometric analysis (RSA) marker placement protocol for visibility and redundancy and validate the performance of the developed RSA system in detecting intervertebral motion. Summary of Background Data Radiostereometric analysis is a stereo x-ray technique in which clusters of tantalum markers are implanted to label well-defined landmarks and measure the relative motion between rigid bodies. Methods A model of the spine with the instrumentation and the RSA markers was developed. The vertebrae were aligned to mimic multilevel thoracic scoliosis after correction. The researchers performed virtual segment motion to validate the performance of the developed system. X-ray images were simulated and RSA was used to evaluate the proposed marker placement protocol and detect virtual motion. The authors performed a physical phantom study to evaluate marker visibility. Results All markers were located and matched between simulations and the condition numbers were well below the recommended value of 100. Based on computer simulation, average translational accuracy was 0.14, 0.01, and 0.24 mm along the x , y, and z axes, respectively, and average rotational accuracy was 0.23°, 0.12°, and 0.11° about the x,y , and z axes, respectively. The translational and rotational precision of the simulated RSA system was generally high. The physical phantom study agreed with the computer simulation and validated marker visibility. Conclusions Computer simulation is a powerful tool that can be used to facilitate the development and refinement of an RSA system before its application in patients, particularly when the anatomy involved is complex. The proposed marker placement protocol yielded translational and rotational accuracy below the limits of clinical significance, which enables future follow-up of multilevel thoracic scoliosis with Lenke classification IAN.
ISSN:2212-134X
2212-1358
DOI:10.1016/j.jspd.2014.09.056