椎体生长机械调节中的静态与动态负荷

Static versus dynamic loading in the mechanical modulation of vertebral growth.

作者信息

Akyuz Ephraim, Braun John T, Brown Nicholas A T, Bachus Kent N

机构信息

Orthopaedic Research Laboratory, Department of Orthopaedics, University of Utah, School of Medicine, Salt Lake City, UT, USA.

出版信息

Spine (Phila Pa 1976). 2006 Dec 1;31(25):E952-8. doi: 10.1097/01.brs.0000248810.77151.22.

DOI:10.1097/01.brs.0000248810.77151.22

PMID:17139211

Abstract

STUDY DESIGN

Measures of absolute and relative growth modulation were used to determine the effects of static and dynamic asymmetric loading of vertebrae in the rat tail.

OBJECTIVES

To quantify the differences between static and dynamic asymmetric loading in vertebral bone growth modulation.

SUMMARY OF BACKGROUND DATA

The creation and correction of vertebral wedge deformities have been previously described in a rat-tail model using static loading. The effects of dynamic loading on growth modulation in the spine have not been characterized.

METHODS

A total of 36 immature Sprague-Dawley rats were divided among four different groups: static loading (n = 12, 0.0 Hz), dynamic loading (n = 12, 1.0 Hz), sham operated (n = 6), and growth controls (n = 6). An external fixator was placed across the sixth and eighth caudal vertebrae as the unviolated seventh caudal vertebra was evaluated for growth modulation. Static or dynamic asymmetric loads were applied at a loading magnitude of 55% body weight. After 3 weeks of loading, growth modulation was assessed using radiographic measurements of vertebral wedge angles and vertebral body heights.

RESULTS

The dynamically loaded rats had a final average wedge deformity of 15.2+/- 6.4 degrees, which was significantly greater than the statically loaded rats whose final deformity averaged 10.3 degrees +/- 3.7 degrees (P < 0.03). The deformity in both groups was statistically greater than the sham-operated (1.1+/- 2.0 degrees) and growth control rats (0.0+/- 1.0 degrees) (P < 0.001). The longitudinal growth was significantly lower on the concavity compared with the convexity in both the dynamically (0.34 +/- 0.23 mm vs. 0.86 +/- 0.23 mm) and statically (0.46 +/- 0.19 mm vs. 0.83 +/- 0.32 mm) loaded rats (P < 0.001). These growth rates were significantly less than the sham operated and growth control rats (P < 0.001).

CONCLUSIONS

A variety of fusionless scoliosis implant strategies have been proposed that use both rigid and flexible implants to modulate vertebral bone growth. The results from this study demonstrate that dynamic loading of the vertebrae provides the greatest growth modulation potential.

摘要

研究设计

采用绝对和相对生长调节测量方法来确定大鼠尾部椎体静态和动态不对称负荷的影响。

目的

量化椎体骨生长调节中静态和动态不对称负荷之间的差异。

背景资料总结

先前已在大鼠尾部模型中使用静态负荷描述了椎体楔形畸形的形成和矫正。动态负荷对脊柱生长调节的影响尚未得到描述。

方法

总共36只未成熟的Sprague-Dawley大鼠被分为四个不同组：静态负荷组（n = 12，0.0 Hz）、动态负荷组（n = 12，1.0 Hz）、假手术组（n = 6）和生长对照组（n = 6）。在第六和第八尾椎上放置外固定器，同时评估未受干扰的第七尾椎的生长调节情况。以体重的55%作为负荷大小施加静态或动态不对称负荷。负荷3周后，通过放射学测量椎体楔形角和椎体高度来评估生长调节情况。

结果

动态负荷组大鼠最终平均楔形畸形为15.2±6.4度，显著大于静态负荷组大鼠，后者最终畸形平均为10.3度±3.7度（P < 0.03）。两组的畸形在统计学上均大于假手术组（1.1±2.0度）和生长对照组大鼠（0.0±1.0度）（P < 0.001）。动态负荷组（0.34±0.23 mm对0.86±0.23 mm）和静态负荷组（0.46±0.19 mm对0.83±0.32 mm）大鼠凹侧的纵向生长均显著低于凸侧（P < 0.001）。这些生长速率显著低于假手术组和生长对照组大鼠（P < 0.001）。