Biomechanical changes occur in myopic choroidal stroma and mirror those in the adjacent sclera

Kazuyo Ito, Cameron Hoerig, Yee Shan Dan, Sally A. McFadden, Jonathan Mamou, Quan V. Hoang
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Abstract

Retina-derived growth signals relayed from the choroid to the sclera cause remodeling of the extracellular scleral matrix, resulting in myopic ocular elongation. However, to the best of our knowledge, no studies have assessed changes in choroidal stromal biomechanical properties during myopia progression. Here we utilized 7 µm-resolution scanning acoustic microscopy (SAM) to assess biomechanical properties (bulk modulus (K) and mass density (rho)) of choroidal stroma from guinea pig eyes with form-deprivation (FD) induced myopia. The choroidal stroma had considerable intrinsic strength arising from its biomechanical properties and these were differentially affected by myopia in central and peripheral regions. Choroidal stromal biomechanical values were also highly correlated with those in adjacent scleral regions, and the choroidal stromal-scleral association was stronger in myopic eyes. Biomechanical changes observed in the choroidal stroma of myopic eyes were mirrored to those observed in the adjacent sclera. These findings suggest that choroidal stromal remodeling may accompany myopia and open the door to the source of the signals that cause scleral remodeling in myopia. Prof Hoang and colleagues used scanning acoustic microscopy to investigate the biomechanical properties of the choroid in myopic eyes. Their biomechanical analytics reveal changes in choroidal stroma from remodeling were mirrored to those in the adjacent sclera. This finding opens the door to the source of the signals that cause scleral remodeling in myopia.

Abstract Image

近视眼脉络膜基质会发生生物力学变化,并与邻近巩膜的生物力学变化相一致。
从脉络膜到巩膜的视网膜生长信号会导致细胞外基质的重塑,从而导致近视眼的伸长。然而,据我们所知,还没有研究对近视发展过程中脉络膜基质生物力学特性的变化进行评估。在这里,我们利用 7 微米分辨率的扫描声学显微镜(SAM)评估了豚鼠近视眼脉络膜基质的生物力学特性(体积模量(K)和质量密度(rho))。脉络膜基质的生物力学特性使其具有相当大的内在强度,而近视对中央和周边区域的影响各不相同。脉络膜基质的生物力学值与邻近巩膜区域的生物力学值也高度相关,近视眼的脉络膜基质与巩膜的关联性更强。在近视眼脉络膜基质中观察到的生物力学变化与在相邻巩膜中观察到的变化如出一辙。这些研究结果表明,脉络膜基质重塑可能伴随着近视的发生,并揭示了导致近视眼巩膜重塑的信号来源。
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