Hypergravity stimulates mechanical behavior and micro-architecture of tibia in rats

IF 2.4 3区 医学 Q3 ENDOCRINOLOGY & METABOLISM
Lilan Gao, Ruiqi Chen, Jin Liu, Yansong Tan, Qijun Gao, Chunqiu Zhang, Linwei Lv
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Abstract

Introduction

The bone tissue is susceptible to hypergravity (+ G) environment. It is necessary to discuss the extent to which specific + G values are beneficial or detrimental to bone tissue. The objective of this study was to characterize the effects of high + G values on mechanical properties, microstructures, and cellular metabolism of bone.

Materials and methods

30 male Wistar rats aged 12 weeks were randomly divided into 5 groups, and bore different + G (namely + 1G, + 4G, + 8G, + 10G and + 12G) environments respectively for 4 weeks, 5 days each week, and 3 minutes each day. The macro-mechanical parameters, microstructure parameters, and mRNA transcription levels of the tibia were determined through the three-point bending method, micro-CT detection, and q-PCR analysis, respectively.

Results

As the + G value increases, hypergravity becomes increasingly detrimental to the macro-mechanical performance of rat tibia. Concerning the microstructure of cancellous bone, there appears to be a favorable trend at + 4G, followed by a progressively detrimental trend at higher G values. In addition, the mRNA transcription levels of OPG and RANKL show an initial tendency of enhanced bone absorption at +4G, followed by an increase in bone remodeling capacity as G value increases.

Conclusion

The higher G values correspond to poorer macro-mechanical properties of the tibia, and a + 4G environment benefits the microstructure of the tibia. At the cellular level, bone resorption is enhanced in the + 4G group, but the bone remodeling capability gradually increases with further increments in G values.

Abstract Image

超重力刺激大鼠胫骨的机械行为和微观结构
导言骨组织容易受到超重力(+G)环境的影响。有必要讨论特定的 + G 值在多大程度上对骨组织有利或有害。材料与方法30 只年龄为 12 周的雄性 Wistar 大鼠被随机分为 5 组,分别在不同的 + G(即 + 1G、+ 4G、+ 8G、+ 10G 和 + 12G)环境下生活 4 周,每周生活 5 天,每天生活 3 分钟。结果 随着 + G 值的增加,超重力对大鼠胫骨宏观力学性能的损害越来越大。关于松质骨的微观结构,在 + 4G 值时似乎出现了有利的趋势,而在更高的 G 值时则出现了逐渐不利的趋势。此外,OPG 和 RANKL 的 mRNA 转录水平在 +4G 时显示出骨吸收增强的初始趋势,随着 G 值的增加,骨重塑能力也随之增强。在细胞水平上,+ 4G 组的骨吸收增强,但随着 G 值的进一步增加,骨重塑能力逐渐增强。
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来源期刊
Journal of Bone and Mineral Metabolism
Journal of Bone and Mineral Metabolism 医学-内分泌学与代谢
CiteScore
6.30
自引率
3.00%
发文量
89
审稿时长
6-12 weeks
期刊介绍: The Journal of Bone and Mineral Metabolism (JBMM) provides an international forum for researchers and clinicians to present and discuss topics relevant to bone, teeth, and mineral metabolism, as well as joint and musculoskeletal disorders. The journal welcomes the submission of manuscripts from any country. Membership in the society is not a prerequisite for submission. Acceptance is based on the originality, significance, and validity of the material presented. The journal is aimed at researchers and clinicians dedicated to improvements in research, development, and patient-care in the fields of bone and mineral metabolism.
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