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Scientific Session VI
             Closed cervical traction using a motorized robot: a biomechanical proof
             of concept
             Marcus D Mazur,MD University of Utah, Salt Lake City, Utah

             Introduction: Closed cervical traction is commonly used to reduce subaxial
             cervical spine dislocation injuries and to distract the intervertebral space dur-
             ing cervical spine surgery. However, the standard weight-and-pulley cervical
             traction with cranial tongs relies on cumbersome and imprecise technology
             without any safeguard to prevent over- traction or weights being pulled/
             released inadvertently.
             Objective: To overcome the limitations of current traction methods, our goal
             is to demonstrate that robotic cervical traction can apply closed cervical trac-
             tion more safely and efficiently than manual weight-and-pulley traction in ex-
             tension spring and cadaveric models.

             Methods: A prototype robotic traction device was designed and manufactured
             with the following objectives: real-time tensile force measurement, ± 1lb (5 N)
             force application accuracy, locking/non back -driveable linear actuators with
             actuator position sensing, maximum force capability of 200 lbs (900 N), up to
             20 degrees of flexion/extension manipulation, device weight < 25 lbs (111
             N), and compatibility with Gardner-Wells tongs or Mayfield head clamp. The
             device was tested using both an extension spring model and an intact fresh
             cadaver specimen to assess applied force and desired force over time as well
             as radiographic changes in the cervical spine as traction force increased. The
             cadaver was tested in manual traction and then robotic traction in 10 lbs (50
             N) increments up to 80 lbs (400 N) to compare methods.
             Results: The prototype device met or exceeded all objectives. In extension
             spring testing, the device was able to reach prescribed forces of 111 N and
             355 lbs accurately and maintain a desired weight. In cadaveric testing, radio-
             graphic outcomes were equivalent between the prototype and manual weight-
             and-pulley traction at 80 lbs (355 N) (disc space measurements within ±10%
             for all levels), and the device was able to reach the desired weight amount
             within ±1 lb (5 N) of accuracy at each weight interval.
             Conclusion: This preliminary work demonstrates that motorized robotic cervi-
             cal traction can safely and effectively apply controlled traction forces that are
             more precise than weight-and-pulley traction. Further cadaveric studies on
             efficacy of reducing facet dislocation injuries are warranted.



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