Complex In Vivo Motion of the Bovine Tail Provides Unique Insights Into Intervertebral Disc Adaptation

IF 3.9 3区医学 Q1 ORTHOPEDICS

JOR Spine Pub Date : 2025-06-17 DOI:10.1002/jsp2.70084

Arthur J. Michalek, Isabelle M. Wood, Daniela Gonzalez Carranza, Lindsay Ferlito

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Abstract

Introduction

The intervertebral disc (IVD) of the bovine tail is a commonly used research analogue for the human disc at the organ, tissue, and cellular levels. While these tails are subjected to thousands of dynamic motion events daily, little is known about how these motions might induce tissue remodeling, particularly in the outer annulus fibrosus (AF) of IVDs connecting adjacent vertebrae. This study hypothesized that despite the similarities in geometry and biochemical composition of IVDs in the bovine tail, level-wise variations in repetitive in-vivo motion would be associated with tissue level adaptations.

Methods

In-vivo active range of motion (RoM) was measured by placing inertial measurement unit sensors on the tails of adult cows and using a multi-segment rigid body model to calculate level-wise flexion-extension and lateral bending angles. Level-wise passive RoM was measured from cadaveric adult bovine tails in flexion, extension, and lateral bending with skin and muscles removed. IVDs were extracted for measurement of height, diameters, AF radial thicknesses, and AF fiber crimp periods.

Results

In-vivo joint RoM was found to vary drastically by level, largely due to a prominent second order mode with inflection point at the fourth joint. Joint levels near this inflection point were found to have the highest passive RoMs. In the proximal tail, decreased RoM was associated with an increased fiber crimp period in the outer AF, while in the distal tail it was associated with increased AF thickness.

Discussion

Taken together, these findings suggest that IVDs in the bovine tail respond to repeated complex dynamic motions through a process of adaptation at the mesoscale (AF thickening during growth) and microscale (residual strain accumulation in the mature state). The bovine tail thus provides a powerful tool for modeling how the human lumbar intervertebral disc may remodel in response to changes in exposure to repetitive motions.

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牛尾巴复杂的体内运动为椎间盘适应提供了独特的见解

牛尾椎间盘（IVD）是一种在器官、组织和细胞水平上常用的人类椎间盘的研究模拟物。虽然这些尾巴每天要经历数千次动态运动事件，但人们对这些运动如何诱导组织重塑知之甚少，特别是连接相邻椎骨的ivd的纤维外环（AF）。本研究假设，尽管牛尾部ivd的几何形状和生化组成相似，但重复体内运动的水平变化可能与组织水平的适应有关。方法通过在成年奶牛尾部放置惯性测量单元传感器，利用多段刚体模型计算水平屈伸角和侧向弯曲角，测量奶牛体内主动运动范围（RoM）。水平方向被动RoM测量从尸体成年牛尾巴在屈曲，延伸和侧屈，皮肤和肌肉去除。提取ivd用于测量高度、直径、AF径向厚度和AF纤维卷曲周期。结果体内关节RoM在不同水平下变化很大，主要是由于在第四个关节有明显的二阶模式。在这个拐点附近的关节水平被发现有最高的被动rom。在尾部近端，RoM的减少与AF外层纤维卷曲时间的增加有关，而在尾部远端，RoM的减少与AF厚度的增加有关。综上所述，这些研究结果表明，牛尾部的ivd通过中尺度（生长期间AF增厚）和微观尺度（成熟状态下残余应变积累）的适应过程来响应重复的复杂动态运动。因此，牛尾巴提供了一个强大的工具，用于模拟人类腰椎间盘如何在暴露于重复运动变化时进行重塑。

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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