Balanced Basic Multicellular Unit Activity in Cortical Bone of Ovariohysterectomized Rabbits.

IF 3.2 3区医学 Q2 ENDOCRINOLOGY & METABOLISM

Calcified Tissue International Pub Date : 2025-09-19 DOI:10.1007/s00223-025-01426-1

Lindsay L Loundagin, Kim D Harrison, David M L Cooper

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引用次数: 0

Abstract

It is well documented that the activation frequency of basic multicellular units (BMUs) is increased following menopause, but it is unclear if a negative BMU balance also contributes to osteoporosis-related bone loss or how remodeling dynamics are altered to maintain or disrupt BMU balance. Time-lapsed imaging was used to track individual BMUs in cortical bone and investigate their spatio-temporal balance in a rabbit model of osteoporosis. The distal tibiae of female New Zealand White rabbits that received ovariohysterectomy (OVH) or SHAM surgery were scanned in vivo using synchrotron radiation micro-CT and two weeks later ex vivo using desktop micro-CT. Remodeling spaces were partitioned into resorption and formation zones based on their 3D morphology. BMU balance was assessed by the maximum radius, canal radius, wall thickness, and relative resorption and formation volumes. The longitudinal erosion rate and zone lengths were used to calculate the radial rate and duration of resorption and formation. Remodeling spaces were larger in OVH vs. SHAM rabbits; however, this augmented resorption was accompanied by increased formation such that OVH and SHAM BMUs were similarly balanced. Maintaining this balance was achieved by a 50% longer formation period in OVH vs. SHAM (21.0 vs 13.2days) as the radial infill rate was equivalent (OVH = 2.1 vs SHAM = 2.0μm/day). Radial erosion rate was faster in OVH (10.3 vs 8.6 μm/day), but resorption duration (OVH = 4.2 vs SHAM = 3.5days) and longitudinal erosion rate (OVH=41.3 vs SHAM = 40.1μm/day) were not different. This novel imaging pipeline demonstrated that the spatio-temporal dynamics of cortical BMUs are altered in this rabbit model of osteoporosis, but the collective changes in resorption and formation activity work in concert to maintain BMU balance. In contrast to the common perspective in the literature, this suggests that the elevated cortical porosity in osteoporosis is predominately due to increased activation of remodeling events rather than negative BMU balance.

查看原文本刊更多论文

卵巢子宫切除兔皮质骨平衡基本多细胞单位活性。

已有文献表明，绝经后基本多细胞单位（BMUs）的激活频率增加，但目前尚不清楚BMU负平衡是否也会导致骨质疏松相关的骨质流失，也不清楚如何改变重塑动力学以维持或破坏BMU平衡。在兔骨质疏松症模型中，采用延时成像技术跟踪皮质骨中的个体骨密度，并研究其时空平衡。对接受卵巢子宫切除术（OVH）或假手术（SHAM）的雌性新西兰大白兔进行体内同步辐射微ct扫描，两周后在体外使用桌面微ct扫描胫骨远端。重构空间根据其三维形态划分为吸收区和形成区。通过最大半径、管径、管壁厚度、相对吸收和地层体积来评估BMU平衡。利用纵向侵蚀速率和带长来计算径向吸收速率和形成时间。OVH兔与SHAM兔相比，重塑空间更大；然而，这种吸收的增强伴随着形成的增加，因此OVH和SHAM的BMUs类似地平衡。由于径向填充速率相同（OVH = 2.1 μm/天vs SHAM = 2.0μm/天），OVH与SHAM的地层周期延长了50%（21.0天vs 13.2天），从而保持了这种平衡。径向侵蚀速率在OVH组更快（10.3 vs 8.6 μm/d），但吸收持续时间（OVH= 4.2 vs SHAM = 3.5d）和纵向侵蚀速率（OVH=41.3 vs SHAM = 40.1μm/d）无显著差异。这种新的成像管道表明，在骨质疏松兔模型中，皮质BMUs的时空动态发生了改变，但吸收和形成活性的集体变化共同维持了BMUs的平衡。与文献中常见的观点相反，这表明骨质疏松症中皮质孔隙度升高主要是由于重塑事件激活增加，而不是由于负的BMU平衡。

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

Calcified Tissue International 医学-内分泌学与代谢

CiteScore

8.00

自引率

2.40%

发文量

112

审稿时长

4-8 weeks

期刊介绍： Calcified Tissue International and Musculoskeletal Research publishes original research and reviews concerning the structure and function of bone, and other musculoskeletal tissues in living organisms and clinical studies of musculoskeletal disease. It includes studies of cell biology, molecular biology, intracellular signalling, and physiology, as well as research into the hormones, cytokines and other mediators that influence the musculoskeletal system. The journal also publishes clinical studies of relevance to bone disease, mineral metabolism, muscle function, and musculoskeletal interactions.