Biomechanical effect of pedicle screw distribution in AIS instrumentation using a segmental translation technique: computer modeling and simulation

Xiaoyu Wang; A Noelle Larson; Dennis G Crandall; Stefan Parent; Hubert Labelle; Charles G T Ledonio; Carl-Eric Aubin

doi:10.1186/s13013-017-0120-4

Biomechanical effect of pedicle screw distribution in AIS instrumentation using a segmental translation technique: computer modeling and simulation

Scoliosis Spinal Disord. 2017 Apr 17:12:13. doi: 10.1186/s13013-017-0120-4. eCollection 2017.

Authors

Xiaoyu Wang^{1

2}, A Noelle Larson³, Dennis G Crandall⁴, Stefan Parent², Hubert Labelle², Charles G T Ledonio⁵, Carl-Eric Aubin^{1

2}

Affiliations

¹ Department of Mechanical Engineering, Polytechnique Montréal, P.O. Box 6079, Downtown Station, Montreal, Quebec H3C 3A7 Canada.
² Sainte-Justine University Hospital Center, 3175, Cote Sainte-Catherine Road, Montreal, Quebec H3T 1C5 Canada.
³ Department of Orthopedic Surgery, Mayo Clinic, 200 1st Street SW, Rochester, MN 55905 USA.
⁴ Sonoran Spine Center and Research Foundation, 1255 W Rio Salado Pkwy, Suite 107, Tempe, AZ 85281 USA.
⁵ Department of Orthopaedic Surgery, University of Minnesota, 2450 Riverside Avenue South, Suite R200, Minneapolis, MN 55454 USA.

Abstract

Background: Efforts to select the appropriate number of implants in adolescent idiopathic scoliosis (AIS) instrumentation are hampered by a lack of biomechanical studies. The objective was to biomechanically evaluate screw density at different regions in the curve for AIS correction to test the hypothesis that alternative screw patterns do not compromise anticipated correction in AIS when using a segmental translation technique.

Methods: Instrumentation simulations were computationally performed for 10 AIS cases. We simulated simultaneous concave and convex segmental translation for a reference screw pattern (bilateral polyaxial pedicle screws with dorsal height adjustability at every level fused) and four alternative patterns; screws were dropped respectively on convex or concave side at alternate levels or at the periapical levels (21 to 25% fewer screws). Predicted deformity correction and screw forces were compared.

Results: Final simulated Cobb angle differences with the alternative screw patterns varied between 1° to 5° (39 simulations) and 8° (1 simulation) compared to the reference maximal density screw pattern. Thoracic kyphosis and apical vertebral rotation were within 2° of the reference screw pattern. Screw forces were 76 ± 43 N, 96 ± 58 N, 90 ± 54 N, 82 ± 33 N, and 79 ± 42 N, respectively, for the reference screw pattern and screw dropouts at convex alternate levels, concave alternate levels, convex periapical levels, and concave periapical levels. Bone-screw forces for the alternative patterns were higher than the reference pattern (p < 0.0003). There was no statistical bone-screw force difference between convex and concave alternate dropouts and between convex and concave periapical dropouts (p > 0.28). Alternate dropout screw forces were higher than periapical dropouts (p < 0.05).

Conclusions: Using a simultaneous segmental translation technique, deformity correction can be achieved with 23% fewer screws than maximal density screw pattern, but resulted in 25% higher bone-screw forces. Screw dropouts could be either on the convex side or on the concave side at alternate levels or at periapical levels. Periapical screw dropouts may more likely result in lower bone-screw force increase than alternate level screw dropouts.

Keywords: Adolescent idiopathic scoliosis; Biomechanical modeling; Instrumentation; Pedicle screw; Screw density; Screw distribution; Screw pattern; Simulation.