Damon E Mar1, Steven J Clary2, Douglas C Burton2, Terence E McIff2. 1. Department of Orthopedic Surgery, University of Kansas Medical Center, Kansas City, KS, USA. Electronic address: dmar@kumc.edu. 2. Department of Orthopedic Surgery, University of Kansas Medical Center, Kansas City, KS, USA.
Abstract
STUDY DESIGN: Biomechanical evaluation of cadaver functional spinal units (FSUs). OBJECTIVES: Demonstrate the effect of increasing spinous process (SP) tether pretension on FSU flexion range of motion (ROM), intervertebral disc (IVD) pressure, and SP force. Quantify SP tether pull-out forces and relate them to SP forces generated at maximum flexion. SUMMARY OF BACKGROUND DATA: There has been recent interest in the use of SP tethering for prophylactic treatment of proximal junctional kyphosis (PJK). There is currently no consensus on standard tethering technique and no biomechanical data on the effect of tether pretension. METHODS: Nine T11-T12 FSUs were tested to 5 Nm of flexion-extension bending. A strain gauge was applied at the base of the T11 SP to measure force. Two custom pressure sensors were inserted into the anterior and posterior thirds of the IVD. Motion kinematics were measured by a motion capture system. An untethered test was done to describe baseline behavior. A 5-mm polyester tether was looped through holes drilled at the base of each SP and pretensioned to five different pretensions ranging from 0 to 88 N. Following ROM testing, specimens were dissected into individual vertebra and then SP pull-out testing was done at each level. RESULTS: Increasing pretension significantly reduced flexion ROM, reduced IVD pressures, and increased SP force. All pretensions, including the minimum, significantly reduced flexion ROM. SP pull-out forces were significantly greater than SP forces generated at maximum flexion. CONCLUSIONS: Tether pretension significantly affects segmental FSU biomechanics. Pretension should be considered an integral factor in the overall success of a tethering strategy. Efforts should be made to control and record pretension intraoperatively. LEVEL OF EVIDENCE: Level V, biomechanical study.
STUDY DESIGN: Biomechanical evaluation of cadaver functional spinal units (FSUs). OBJECTIVES: Demonstrate the effect of increasing spinous process (SP) tether pretension on FSU flexion range of motion (ROM), intervertebral disc (IVD) pressure, and SP force. Quantify SP tether pull-out forces and relate them to SP forces generated at maximum flexion. SUMMARY OF BACKGROUND DATA: There has been recent interest in the use of SP tethering for prophylactic treatment of proximal junctional kyphosis (PJK). There is currently no consensus on standard tethering technique and no biomechanical data on the effect of tether pretension. METHODS: Nine T11-T12 FSUs were tested to 5 Nm of flexion-extension bending. A strain gauge was applied at the base of the T11 SP to measure force. Two custom pressure sensors were inserted into the anterior and posterior thirds of the IVD. Motion kinematics were measured by a motion capture system. An untethered test was done to describe baseline behavior. A 5-mm polyester tether was looped through holes drilled at the base of each SP and pretensioned to five different pretensions ranging from 0 to 88 N. Following ROM testing, specimens were dissected into individual vertebra and then SP pull-out testing was done at each level. RESULTS: Increasing pretension significantly reduced flexion ROM, reduced IVD pressures, and increased SP force. All pretensions, including the minimum, significantly reduced flexion ROM. SP pull-out forces were significantly greater than SP forces generated at maximum flexion. CONCLUSIONS: Tether pretension significantly affects segmental FSU biomechanics. Pretension should be considered an integral factor in the overall success of a tethering strategy. Efforts should be made to control and record pretension intraoperatively. LEVEL OF EVIDENCE: Level V, biomechanical study.
Authors: Bernardo de Andrada Pereira; Jennifer N Lehrman; Anna G U Sawa; Piyanat Wangsawatwong; Jakub Godzik; David S Xu; Jay D Turner; Brian P Kelly; Juan S Uribe Journal: Neurospine Date: 2022-09-30
Authors: Audrey A Pitaru; Jean-Gabriel Lacombe; Megan E Cooke; Lorne Beckman; Thomas Steffen; Michael H Weber; Paul A Martineau; Derek H Rosenzweig Journal: Micromachines (Basel) Date: 2020-09-11 Impact factor: 2.891