Evaluation of eye tissue elasticity by means of sound propagation speed measuring in vivo

Biophotonics South America Pub Date : 2015-06-19 DOI:10.1117/12.2179598

J. Crispim, Adriano Bogar, N. Allemann, J. C. C. Neto, W. Chamon

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Abstract

Introduction: To date, it has never been demonstrated the propagation sound speed in human corneas and lens in vivo. With the advent of Optical Coherence Tomography (OCT), it became possible to determine the dimensions of the ocular tissues without the interference of sound propagation speed and to use this information to define the real propagation sound speed for each patient and individualized structure. Aim: To determine the sound propagation speed in the cornea and lens from patients that theoretically exhibits differences in tissue elasticity (normal corneas and keratoconus, corneas of young and elderly patients, in addition to clear crystalline lens from young and elderly patients with cataract). Then, relate the determined velocity in each group with the expected tissue elasticity of the cornea and lens. Methods: We studied 100 eyes from 50 patients: 50 with keratoconus and no cataract and 50 with cataract and no corneal changes. All patients measured corneal and lens thickness by ultrasound methods (Ultrasonic Biomicroscopy - UBM and Ultrasonic Pachymetry - USP) and by OCT (RTVue®, Lenstar® and Visante®), then were divided into 2 groups: Group 1 (Cornea) analyzed the central corneal thickness (UBM, USP, RTVue®, Visante®, Lenstar®); Group 2 (Lens) analyzed the axial thickness of the lens (UBM and Lenstar®). Based on standard ultrasonic speed from USP (1640 m/s) and UBM (1548 m/s), we calculated the real sound propagation speed in each tissue. Results: Based on USP, the corneal sound speed on control group (1616 m/s) was faster than on keratoconus group (1547 m/s) (P < 0.0001). Based on UBM, the lens sound speed on cataract group (1664 m/s) was faster that on control group (1605 m/s) (P < 0.0001). Discussion: It is known that sound propagates faster in materials with lower elasticity. We found that the sound speed on keratoconic corneas (high elasticity) was slower and on cataract lens (lower elasticity) was faster than normal corneas and lens in vivo.

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用体内声传播速度测量法评价眼组织弹性

迄今为止，还没有在人体角膜和晶状体中证明声音的传播速度。随着光学相干断层扫描(OCT)的出现，在不受声音传播速度干扰的情况下确定眼部组织的尺寸成为可能，并利用这些信息来定义每个患者的真实传播声速和个性化结构。目的:测定组织弹性理论上存在差异的患者(正常角膜和圆锥角膜，青年和老年患者的角膜，以及青年和老年白内障患者的透明晶状体)角膜和晶状体中的声音传播速度。然后，将各组确定的速度与角膜和晶状体的预期组织弹性联系起来。方法:对50例患者100只眼进行研究，其中50例为圆锥角膜无白内障，50例为白内障无角膜改变。所有患者均采用超声方法(超声生物显微镜- UBM和超声厚测法- USP)和OCT (RTVue®，Lenstar®和Visante®)测量角膜和晶状体厚度，然后分为2组:1组(角膜)分析角膜中央厚度(UBM, USP, RTVue®，Visante®，Lenstar®);第二组(Lens)分析晶状体(UBM和Lenstar®)的轴向厚度。根据USP (1640 m/s)和UBM (1548 m/s)的标准超声速度，我们计算了每个组织中的真实声音传播速度。结果:基于USP，对照组角膜声速(1616 m/s)快于圆锥角膜组(1547 m/s) (P < 0.0001)。基于UBM，白内障组晶状体声速(1664 m/s)明显快于对照组(1605 m/s) (P < 0.0001)。讨论:众所周知，声音在弹性较低的材料中传播得更快。实验结果表明，与正常角膜和晶状体相比，在高弹性角膜上声速较慢，在低弹性白内障晶状体上声速较快。

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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Biophotonics South America

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