Optical Coherence Elastography Measures Mechanical Tension in the Lens and Capsule in situ.

ArXiv Pub Date : 2024-12-17

Xu Feng, Guo-Yang Li, Yuxuan Jiang, Owen Shortt-Nguyen, Seok-Hyun Yun

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Abstract

Lens tension is essential for accommodative vision but remains challenging to measure with precision. Here, we present an optical coherence elastography (OCE) technique that quantifies both the tension and elastic modulus of lens tissue and capsule. This method derives mechanical parameters from surface wave dispersion across a critical frequency range of 1-30 kHz. Using isolated lenses from six-month-old pigs, we measured intrinsic anterior capsular tensions of 0-20 kPa and posterior capsular tensions of 40-50 kPa, induced by intra-lenticular pressure at the cortical surface. Young's modulus $(E)$ was 1.9 MPa for anterior capsules and 1.2 MPa for posterior capsules. Tensions in cortical tissue $(E \sim 10 kPa)$ were below 1 kPa. Biaxial zonular stretching (~4% strain) increased anterior capsular tension from near zero to 64 kPa. This acousto-optical method holds significant promise for diagnosing and managing accommodative dysfunctions through lens mechanics assessment in clinical settings.

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光学相干弹性成像在原位测量透镜和胶囊的机械张力。

透镜张力是必不可少的调节视力，但仍然具有挑战性的测量精度。在这里，我们提出了一种光学相干弹性成像（OCE）技术，可以量化晶状体组织和囊的张力和弹性模量。该方法从表面波在1- 30khz临界频率范围内的色散中导出机械参数。使用6月龄猪的离体晶状体，我们测量了皮层表面晶状体内压力诱导的内源性前囊张力0-20 kPa和后囊张力40-50 kPa。杨氏模量(E)前囊1.9 MPa，后囊1.2 MPa。皮质组织的张力（E ~ 10 kPa）低于1 kPa。双轴带状拉伸（~4%应变）使前囊张力从接近零增加到64 kPa。这种声光方法在临床上通过晶状体力学评估诊断和管理适应性功能障碍方面具有重要的前景。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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