Alexandria Mallinos, Camille Pillot, Xiaoyu Wang, Todd Ritzman, Lorena V Floccari, Richard M Schwend, Carl-Eric Aubin
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引用次数: 0
Abstract
Purpose: To evaluate the impact of increasing the differential precontouring angle of concave and convex rods on three-dimensional correction during posterior spinal fusion in patients with adolescent idiopathic scoliosis (AIS) and determine the threshold beyond which additional contouring yields no further correctional benefit in a computational model.
Methods: Patient-specific computational biomechanical models were developed using radiographs from 10 thoracic Lenke 1 AIS patients. Posterior instrumentation included bilateral uniaxial pedicle screws from T4 to L1 and rods of various diameters and materials. First-order simulations of the primary correction maneuver using the rod translation technique were performed using MSC Adams. The effects of varying concave rod precontouring angles on the forces at play and resulting correction in the coronal, sagittal, and axial planes were analyzed.
Results: Coronal plane correction decreased progressively with increasing rod contouring angles (p < 0.05) due to posterior displacement of the rod relative to the spine, reducing coronally-directed torque at the curve apex. Aggressive rod contouring (> 55°) improved sagittal plane correction (thoracic kyphosis), with the benefit depending on presenting kyphosis (p < 0.05). Normo-kyphotic curves showed better outcomes with moderate rod contouring (< 55°), whereas hypo-kyphotic curves required more aggressive bending (55-85°) to restore kyphosis, despite reduced coronal correction. Transverse plane effects from these simulations appeared less influential (p > 0.05). Screw axial forces increased linearly with concave rod bending angle.
Conclusion: Increasing concave rod precontouring beyond 35° to 55° yields diminishing coronal plane correction, while offering selective benefit in restoring thoracic kyphosis in hypo-kyphotic AIS patients.
期刊介绍:
Spine Deformity the official journal of the?Scoliosis Research Society is a peer-refereed publication to disseminate knowledge on basic science and clinical research into the?etiology?biomechanics?treatment?methods and outcomes of all types of?spinal deformities. The international members of the Editorial Board provide a worldwide perspective for the journal's area of interest.The?journal?will enhance the mission of the Society which is to foster the optimal care of all patients with?spine?deformities worldwide. Articles published in?Spine Deformity?are Medline indexed in PubMed.? The journal publishes original articles in the form of clinical and basic research. Spine Deformity will only publish studies that have institutional review board (IRB) or similar ethics committee approval for human and animal studies and have strictly observed these guidelines. The minimum follow-up period for follow-up clinical studies is 24 months.
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