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一种新的将脊髓损伤与石膏固定相结合的啮齿动物模型中的骨质流失。

Bone loss in a new rodent model combining spinal cord injury and cast immobilization.

作者信息

Yarrow J F, Ye F, Balaez A, Mantione J M, Otzel D M, Chen C, Beggs L A, Baligand C, Keener J E, Lim W, Vohra R S, Batra A, Borst S E, Bose P K, Thompson F J, Vandenborne K

机构信息

Research Service, Department of Veterans Affairs Medical Center, North Florida/South Georgia Veterans Health System, Gainesville, FL, United States, 32608.

出版信息

J Musculoskelet Neuronal Interact. 2014 Sep;14(3):255-66.

PMID:25198220
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8349504/
Abstract

OBJECTIVES

Characterize bone loss in our newly developed severe contusion spinal cord injury (SCI) plus hindlimb immobilization (IMM) model and determine the influence of muscle contractility on skeletal integrity after SCI.

METHODS

Female Sprague-Dawley rats were randomized to: (a) intact controls, (b) severe contusion SCI euthanized at Day 7 (SCI-7) or (c) Day 21 (SCI-21), (d) 14 days IMM-alone, (e) SCI+IMM, or (f) SCI+IMM plus 14 days body weight supported treadmill exercise (SCI+IMM+TM).

RESULTS

SCI-7 and SCI-21 exhibited a >20% reduction in cancellous volumetric bone mineral density (vBMD) in the hindlimbs (p⋜0.01), characterized by reductions in cancellous bone volume (cBV/TV%), trabecular number (Tb.N), and trabecular thickness. IMM-alone induced no observable bone loss. SCI+IMM exacerbated cancellous vBMD deficits with values being >45% below Controls (p⋜0.01) resulting from reduced cBV/TV% and Tb.N. SCI+IMM also produced the greatest cortical bone loss with distal femoral cortical area and cortical thickness being 14-28% below Controls (p⋜0.01) and bone strength being 37% below Controls (p⋜0.01). SCI+IMM+TM partially alleviated bone deficits, but values remained below Controls.

CONCLUSIONS

Residual and/or facilitated muscle contractility ameliorate bone decrements after severe SCI. Our novel SCI+IMM model represents a clinically-relevant means of assessing strategies to prevent SCI-induced skeletal deficits.

摘要

目的

在我们新开发的严重挫伤性脊髓损伤(SCI)加后肢固定(IMM)模型中描述骨质流失情况,并确定SCI后肌肉收缩性对骨骼完整性的影响。

方法

将雌性Sprague-Dawley大鼠随机分为:(a)完整对照组,(b)在第7天安乐死的严重挫伤性SCI组(SCI-7)或(c)第21天安乐死的严重挫伤性SCI组(SCI-21),(d)单独后肢固定14天组,(e)SCI+IMM组,或(f)SCI+IMM加14天体重支持跑步机运动组(SCI+IMM+TM)。

结果

SCI-7组和SCI-21组后肢松质骨体积骨密度(vBMD)降低超过20%(p<0.01),其特征为松质骨体积(cBV/TV%)、骨小梁数量(Tb.N)和骨小梁厚度减少。单独后肢固定未引起明显骨质流失。SCI+IMM加剧了松质骨vBMD缺陷,其值比对照组低>45%(p<0.01),这是由于cBV/TV%和Tb.N降低所致。SCI+IMM还导致了最大程度的皮质骨流失,股骨远端皮质面积和皮质厚度比对照组低14-28%(p<0.01),骨强度比对照组低37%(p<0.01)。SCI+IMM+TM部分缓解了骨缺损,但数值仍低于对照组。

结论

残余和/或增强的肌肉收缩性可改善严重SCI后的骨质减少。我们新的SCI+IMM模型是一种评估预防SCI引起的骨骼缺陷策略的临床相关方法。

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