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. 2023 Nov;11(6):1309-1316.
doi: 10.1007/s43390-023-00707-9. Epub 2023 Jun 1.

Biomechanical analysis of rod contouring in posterior spinal instrumentation and fusion for 3D correction of adolescent idiopathic scoliosis

Marine Gay  1   2 Xiaoyu Wang  1   2 Todd Ritzman  3 Lorena Floccari  3 Richard M Schwend  4 Carl-Eric Aubin  5   6
Affiliations

Biomechanical analysis of rod contouring in posterior spinal instrumentation and fusion for 3D correction of adolescent idiopathic scoliosis

Marine Gay et al. Spine Deform. 2023 Nov.

Abstract

Purpose: To biomechanically evaluate 3D corrective forces and deformity correction attributable to key parameters of rod contouring in posterior spinal fusion (PSF) for adolescent idiopathic scoliosis (AIS).

Methods: Computerised patient-specific biomechanical models of six AIS cases were used to simulate PSF and evaluate the effects of 5.5-mm cobalt-chrome rod contouring angle (concave-convex angles: 30°-15°, 45°-15° and 60°-15°), length (spanning 4 and 7 vertebrae), and apex location (T7, T9). 3D correction and bone-implant forces were computed and analysed.

Results: By increasing the concave rod contour from 30° to 60°, thoracic kyphosis (TK) increased from 18° ± 2° (15°-19°) to 24° ± 2° (22°-26°), apical vertebra rotation (AVR) correction increased from 41% (SD8%) to 66% (SD18%) whilst the main thoracic curve (MT) correction decreased from 68% (SD6%) to 56% (SD8%). With a contouring length of 4 vs. 7 vertebrae, the resulting TK, AVR and MT corrections were 22° ± 1° (19°-26°) vs. 19° ± 10° (15°-22°), 57% (SD18%) vs. 50% (SD26%) and 59% (SD1%) vs. 69% (SD35%), respectively. With the rod contouring apex at T7 (vs. T9), AVR corrections were 69% (SD19%) vs. 44% (SD9%), with no significant difference in TK and MT corrections, and with comparatively 67% of screw pull-out forces. Corrective forces were more evenly shared with fixation on 7 vs. 4 vertebrae.

Conclusion: Rod contouring of a greater angulation, over a shorter portion of the rod, and more centred at the apex of the main thoracic curve apex improved AVR correction and allowed greater restoration of TK, but resulted in significantly higher screw pull-out forces and came at the expense of less coronal plane correction.

Keywords: Adolescent idiopathic scoliosis; Posterior spinal fusion; Rod contouring.

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References

    1. Sucato DJ (2010) Management of severe spinal deformity: scoliosis and kyphosis. Spine 35(25):2186–2192 - DOI - PubMed
    1. Zuckerman SL et al (2022) Three-dimensional assessment of vertebral derotation in adolescent idiopathic scoliosis: review of a surgical technique and its success in achieving derotation in the instrumented and uninstrumented spine. Oper Neurosurg 22(6):380–386 - DOI
    1. Ruwald JM et al (2020) An overview of the current state of pediatric scoliosis management. Z Orthop Unfall 158(5):508–516 - DOI - PubMed
    1. Wang X et al (2016) How does differential rod contouring contribute to 3-dimensional correction and affect the bone-screw forces in adolescent idiopathic scoliosis instrumentation? Clin Biomech 39:115–121 - DOI
    1. Seki S et al (2019) Differential rod contouring on thoracolumbar/lumbar curvature in patients with adolescent idiopathic scoliosis: an analysis with intraoperative acquisition of three-dimensional imaging. J Orthop Sci 24(5):780–786 - DOI - PubMed

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