From stress to sight: The role of mechanical forces in the retinal diseases

IF 3.4

Advances in ophthalmology practice and research Pub Date : 2025-04-15 DOI:10.1016/j.aopr.2025.04.002

Di Wu , Ye Liu , Xiaogang Luo , Chengshou Zhang , Yifei Zheng , Jianfeng Meng , Mei Yang , Hemlata Bisnauthsing , Ping Rao , Baohua Ji , Wai Kit Chu

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Abstract

Background

The retina, a light-sensitive neural tissue critical for vision, exists in a dynamic mechanical environment where it is continuously exposed to mechanical forces. These forces, including traction forces, intraocular pressure-related stress, and hemodynamic forces, are closely linked to the progression of retinal diseases. A comprehensive understanding of retinal mechanosensation and mechanotransduction is essential for understanding the pathological mechanisms under aberrant mechanical conditions.

Main Text

This review synthesizes current knowledge on advanced biomechanical assessment techniques, and aging-associated biomechanical alterations in retinal tissues, emphasizing how mechanical forces drive structural and functional pathology.

Conclusions

By elucidating the mechanosensitive mechanisms remodeling retinal cell behavior and fate, this review highlights the critical role of biomechanics in retinal disease pathogenesis. The integration of mechanistic insights with biomechanical assessment techniques offers transformative potential for diagnosing mechanical dysfunction and developing mechanotargeted therapies.

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从压力到视力：机械力在视网膜疾病中的作用

视网膜是一种对视觉至关重要的光敏神经组织，它存在于一个动态的机械环境中，不断地暴露在机械力下。这些力，包括牵引力、眼压相关应力和血流动力学力，与视网膜疾病的进展密切相关。全面了解视网膜机械感觉和机械转导对于理解异常机械条件下的病理机制至关重要。本文综合了目前先进的生物力学评估技术和视网膜组织中与衰老相关的生物力学变化的知识，强调了机械力如何驱动结构和功能病理。结论通过阐明视网膜细胞行为和命运的机械敏感性机制，强调了生物力学在视网膜疾病发病机制中的重要作用。机械力学见解与生物力学评估技术的整合为诊断机械功能障碍和开发机械靶向治疗提供了变革性的潜力。

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