An investigation of range of motion preservation in fusionless anterior double screw and cord constructs for scoliosis correction.

Abstract

To evaluate the motion-preserving properties of vertebral body tethering with varying cord/screw constructs and cord thicknesses in cadaveric thoracolumbar spines. In vitro flexibility tests were performed on six fresh-frozen human cadaveric spines (T1-L5) (2M, 4F) with a median age of 63 (59-to-80). An ± 8 Nm load was applied to determine range of motion (ROM) in flexion-extension (FE), lateral bending (LB), and axial rotation (AR) in the thoracic and lumbar spine. Specimens were tested with screws (T5-L4) and without cords. Single (4.0mm and 5.0mm) and double (4.0mm) cord constructs were sequentially tensioned to 100 N and tested: (1) Single 4.0mm and (2) 5.0mm cords (T5-T12); (3) Double 4.0mm cords (T5-12); (4) Single 4.0mm and (5) 5.0mm cord (T12-L4); (6) Double 4.0mm cords (T12-L4). In the thoracic spine (T5-T12), 4.0-5.0mm single-cord constructs showed slight reductions in FE and 27-33% reductions in LB compared to intact, while double-cord constructs showed reductions of 24% and 40%, respectively. In the lumbar spine (T12-L4), double-cord constructs had greater reductions in FE (24%), LB (74%), and AR (25%) compared to intact, while single-cord constructs exhibited reductions of 2-4%, 68-69%, and 19-20%, respectively. The present biomechanical study found similar motion for 4.0-5.0mm single-cord constructs and the least motion for double-cord constructs in the thoracic and lumbar spine suggesting that larger diameter 5.0mm cords may be a more promising motion-preserving option, due totheir increased durability compared to smaller cords. Future clinical studies are necessary to determine the impact of these findings on patient outcomes.