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树懒和食蚁兽前肢软骨下骨的表观密度模式。

Apparent density patterns in subchondral bone of the sloth and anteater forelimb.

作者信息

Patel Biren A, Carlson Kristian J

机构信息

Department of Biomedical Sciences, Ohio University College of Osteopathic Medicine, Athens, OH 45701, USA.

出版信息

Biol Lett. 2008 Oct 23;4(5):486-9. doi: 10.1098/rsbl.2008.0297.

Abstract

Vertebrate morphologists often are interested in inferring limb-loading patterns in animals characterized by different locomotor repertoires. Because bone apparent density (i.e. mass per unit volume of bone inclusive of porosities) is a determinant of compressive strength, and thus indicative of compressive loading, recent comparative studies in primates have proposed a structure-function relationship between apparent density of subchondral bone and locomotor behaviours that vary in compressive loading. If such patterns are found in other mammals, then these relationships would be strengthened further. Here, we examine the distal radius of suspensory sloths that generally load their forelimbs (FLs) in tension and of quadrupedal anteaters that generally load their FLs in compression. Computed tomography osteoabsorptiometry was used to visualize the patterns in subchondral apparent density. Suspensory sloths exhibit relatively smaller areas of high apparent density than quadrupedal anteaters. This locomotor-based pattern is analogous to the pattern observed in suspensory and quadrupedal primates. Similarity between xenarthran and primate trends suggests broad-scale applicability for analysing subchondral bone apparent density and supports the idea that bone functionally alters its material properties in response to locomotor behaviours.

摘要

脊椎动物形态学家常常对推断具有不同运动方式的动物的肢体负荷模式感兴趣。由于骨表观密度(即包含孔隙的单位体积骨的质量)是抗压强度的一个决定因素,因此可指示压缩负荷,灵长类动物最近的比较研究提出了软骨下骨表观密度与在压缩负荷方面有所不同的运动行为之间的结构-功能关系。如果在其他哺乳动物中也发现了这样的模式,那么这些关系将得到进一步加强。在这里,我们研究了通常以前肢承受拉力的悬垂树懒和通常以前肢承受压力的四足食蚁兽的桡骨远端。使用计算机断层扫描骨吸收测定法来观察软骨下表观密度的模式。与四足食蚁兽相比,悬垂树懒表现出相对较小的高表观密度区域。这种基于运动方式的模式类似于在悬垂和四足灵长类动物中观察到的模式。贫齿目动物和灵长类动物趋势之间的相似性表明,分析软骨下骨表观密度具有广泛的适用性,并支持这样一种观点,即骨骼会根据运动行为在功能上改变其材料特性。

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