肌腱附着点的异速生长:肌腱与骨骼之间的负荷传递机制
Allometry of the Tendon Enthesis: Mechanisms of Load Transfer Between Tendon and Bone.
作者信息
Deymier-Black Alix C, Pasteris Jill D, Genin Guy M, Thomopoulos Stavros
出版信息
J Biomech Eng. 2015 Nov;137(11):111005. doi: 10.1115/1.4031571.
Abstract
Several features of the tendon-to-bone attachment were examined allometrically to determine load transfer mechanisms. The humeral head diameter increased geometrically with animal mass. Area of the attachment site exhibited a near isometric increase with muscle physiological cross section. In contrast, the interfacial roughness as well as the mineral gradient width demonstrated a hypoallometric relationship with physiologic cross-sectional area (PCSA). The isometric increase in attachment area indicates that as muscle forces increase, the attachment area increases accordingly, thus maintaining a constant interfacial stress. Due to the presence of constant stresses at the attachment, the micrometer-scale features may not need to vary with increasing load.
摘要
对肌腱与骨附着的几个特征进行了异速生长分析,以确定负荷传递机制。肱骨头直径随动物体重呈几何增长。附着部位的面积随肌肉生理横截面积呈近等距增长。相比之下,界面粗糙度以及矿物质梯度宽度与生理横截面积(PCSA)呈低异速生长关系。附着面积的等距增长表明,随着肌肉力量增加,附着面积相应增加,从而保持恒定的界面应力。由于附着处存在恒定应力,微米级特征可能无需随负荷增加而变化。
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