Impact of growth on spinal biomechanics and tether force in VBT: a simulation study.

IF 2.7 3区医学 Q2 CLINICAL NEUROLOGY European Spine Journal Pub Date : 2025-07-01 Epub Date: 2025-03-22 DOI:10.1007/s00586-025-08738-8

Jil Frank, Miguel Pishnamaz, Per David Trobisch, Frank Hildebrand, Maximilian Praster

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Abstract

Purpose: Vertebral Body Tethering (VBT) allows correction of scoliosis while preserving the spinal mobility. Despite an increasing availability of data on clinical experience and surgical techniques, there is still a lack of knowledge on the underlying biomechanics, specifically when considered in combination with growth. Therefore, the purpose of this study is to develop a growing flexible spine model to investigate spinal biomechanics after VBT surgery.

Methods: A multi-body simulation approach was chosen. A growing, flexible thoracolumbar VBT spine model was developed to analyze the spinal biomechanics during various physiological movements and growth. The model includes a flexible spine with a VBT device and a musculoskeletal system. Therefore, the resulting tether tension and intervertebral compression force can be calculated with respect to the human anatomy and material properties of the VBT device.

Results: During growth, the tether and compression forces increase continuously with the highest forces between L1 and L2. The highest tether force is measured at 50° lateral bend at 200 N pre-tension. The compression forces in a tethered spine are during adolescence up to twice higher than in a healthy spine.

Conclusion: The simulated biomechanical data provides insight into the forces exerted on the spine during various physiological movements and the remaining growth. They are consistent with previously published clinical data and underlie the finding that age at surgery or residual growth doesn't greatly affect tether forces. During growth, however, intervertebral compression forces increase.

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生长对VBT脊柱生物力学和系索力影响的模拟研究。

目的：椎体系扎术（VBT）可以在保持脊柱活动的同时矫正脊柱侧凸。尽管关于临床经验和手术技术的数据越来越多，但关于潜在生物力学的知识仍然缺乏，特别是当与生长结合考虑时。因此，本研究的目的是建立一个生长的柔性脊柱模型来研究VBT手术后的脊柱生物力学。方法：采用多体仿真方法。建立了一种生长中的、灵活的胸腰椎VBT脊柱模型，以分析各种生理运动和生长过程中的脊柱生物力学。该模型包括一个带有VBT装置的柔性脊柱和一个肌肉骨骼系统。因此，由此产生的系绳张力和椎间压缩力可以根据人体解剖结构和VBT装置的材料特性来计算。结果：在生长过程中，束缚力和压缩力不断增加，L1和L2之间的力最大。在200 N的预张力下，在50°侧弯时测得绳系力最高。在青少年时期，栓系脊柱的压缩力是健康脊柱的两倍。结论：模拟的生物力学数据提供了在各种生理运动和剩余生长过程中施加在脊柱上的力的见解。他们与先前发表的临床数据一致，并支持手术年龄或残余生长对系索力的影响不大的发现。然而，在生长过程中，椎间压缩力增加。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

European Spine Journal 医学-临床神经学

CiteScore

4.80

自引率

10.70%

发文量

373

审稿时长

2-4 weeks

期刊介绍： "European Spine Journal" is a publication founded in response to the increasing trend toward specialization in spinal surgery and spinal pathology in general. The Journal is devoted to all spine related disciplines, including functional and surgical anatomy of the spine, biomechanics and pathophysiology, diagnostic procedures, and neurology, surgery and outcomes. The aim of "European Spine Journal" is to support the further development of highly innovative spine treatments including but not restricted to surgery and to provide an integrated and balanced view of diagnostic, research and treatment procedures as well as outcomes that will enhance effective collaboration among specialists worldwide. The “European Spine Journal” also participates in education by means of videos, interactive meetings and the endorsement of educative efforts. Official publication of EUROSPINE, The Spine Society of Europe