使用整合生长调节的患者特异性有限元模型对小儿特发性脊柱侧弯进行椎体前路生长调节的手术规划与随访
Surgical Planning and Follow-up of Anterior Vertebral Body Growth Modulation in Pediatric Idiopathic Scoliosis Using a Patient-Specific Finite Element Model Integrating Growth Modulation.
作者信息
Cobetto Nikita, Aubin Carl-Eric, Parent Stefan
机构信息
Department of Mechanical Engineering, Polytechnique Montréal, P.O. Box 6079, Downtown Station, Montreal, Quebec H3C 3A7, Canada; Research Center, Sainte-Justine University Hospital Center, 3175 Côte-Sainte-Catherine Road, Montreal, Quebec H3T 1C5, Canada.
Department of Mechanical Engineering, Polytechnique Montréal, P.O. Box 6079, Downtown Station, Montreal, Quebec H3C 3A7, Canada; Research Center, Sainte-Justine University Hospital Center, 3175 Côte-Sainte-Catherine Road, Montreal, Quebec H3T 1C5, Canada.
出版信息
Spine Deform. 2018 Jul-Aug;6(4):344-350. doi: 10.1016/j.jspd.2017.11.006.
STUDY DESIGN
Numerical planning and simulation of immediate and post-two-year growth modulation effects of Anterior Vertebral Body Growth Modulation (AVBGM).
OBJECTIVES
To develop a planning tool based on a patient-specific finite element model (FEM) of pediatric scoliosis integrating growth to computationally assess the 3D biomechanical effects of AVBGM.
SUMMARY OF BACKGROUND DATA
AVBGM is a recently introduced fusionless compression-based approach for pediatric scoliotic patients presenting progressive curves. Surgical planning is mostly empirical, with reported issues including overcorrection (inversion of the side) of the curve and a lack of control on 3D correction.
METHODS
Twenty pediatric scoliotic patients instrumented with AVBGM were assessed. An osseoligamentous FEM of the spine, rib cage, and pelvis was generated before surgery using the patient's 3D reconstruction obtained from calibrated biplanar radiographs. For each case, different scenarios of AVBGM and two years of vertebral growth and growth modulation due to gravitational loads and forces from AVBGM were simulated. Simulated correction indices in the coronal, sagittal, and transverse planes for the retained scenario were computed and a posteriori compared to actual patient's postoperative and two years' follow-up data.
RESULTS
The simulated immediate postoperative Cobb angles were on average within 3° of that of the actual correction, while it was ±5° for kyphosis/lordosis angles, and ±5° for apical axial rotation. For the simulated 2-year postoperative follow-up, correction results were predicted at ±3° for Cobb angles and ±5° for kyphosis/lordosis angles, ±2% for T1-L5 height, and ±4° for apical axial rotation.
CONCLUSION
A numeric model simulating immediate and post-two-year effects of AVBGM enabled to assess different implant configurations to support surgical planning.
LEVEL OF EVIDENCE
Level III.
研究设计
椎体前路生长调节(AVBGM)即刻及两年后生长调节效果的数值规划与模拟。
目的
基于整合生长因素的小儿脊柱侧弯患者个体化有限元模型(FEM)开发一种规划工具,以通过计算评估AVBGM的三维生物力学效应。
背景数据总结
AVBGM是一种最近引入的针对呈现进展性侧弯的小儿脊柱侧弯患者的非融合性基于压缩的方法。手术规划大多基于经验,报告的问题包括曲线过度矫正(侧弯方向反转)以及缺乏对三维矫正的控制。
方法
对20例接受AVBGM治疗的小儿脊柱侧弯患者进行评估。术前使用从校准的双平面X线片获得的患者三维重建数据生成脊柱、胸廓和骨盆的骨韧带有限元模型。对于每个病例,模拟了AVBGM的不同情况以及由于重力载荷和AVBGM产生的力导致的两年椎体生长和生长调节。计算了保留方案在冠状面、矢状面和横断面的模拟矫正指数,并与实际患者术后及两年随访数据进行事后比较。
结果
模拟的术后即刻Cobb角平均与实际矫正角度相差在3°以内,后凸/前凸角度相差±5°,顶椎轴向旋转相差±5°。对于模拟的术后两年随访,Cobb角矫正结果预测相差±3°,后凸/前凸角度相差±5°,T1-L5高度相差±2%,顶椎轴向旋转相差±4°。
结论
模拟AVBGM即刻及两年后效果的数值模型能够评估不同的植入物配置以支持手术规划。
证据水平
三级。
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