猴眼晶状体弹性的原子力显微镜测量

Atomic force microscopy measurements of lens elasticity in monkey eyes.

作者信息

Ziebarth Noël M, Wojcikiewicz Ewa P, Manns Fabrice, Moy Vincent T, Parel Jean-Marie

机构信息

The Ophthalmic Biophysics Center, Bascom Palmer Eye Institute, University of Miami Miller School of Medicine, Miami, FL 33136, USA.

出版信息

Mol Vis. 2007 Apr 2;13:504-10.

PMID:17417612

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2649306/

Abstract

PURPOSE

To demonstrate the feasibility of measuring the elasticity of intact crystalline lenses using atomic force microscopy (AFM).

METHODS

AFM elasticity measurements were performed on intact lenses from 18 fresh cynomolgus monkey cadaver eyes (4-10 years old, <1 day postmortem) that had been left attached to their zonule-ciliary body-sclera framework. The eyes were prepared by bonding a plastic ring on the sclera after removal of the conjunctival, adipose, and muscle tissues. The posterior pole was sectioned, with the excess vitreous removed, and the eye's anterior section was placed on a Teflon slide to protect the posterior pole of the lens. The cornea and iris were then sectioned. The lens-zonule-ciliary body-sclera section was then placed in a Petri dish filled with balanced salt solution in an AFM system designed for force measurements. Next, the central pole of the anterior surface of the intact lens was probed with the AFM cantilever tip. The recorded AFM cantilever deflection-indentation curves were used to derive force-indentation curves for the lens after factoring out the deflection of the cantilever on a hard surface. Young's modulus of the lens was calculated from the force-indentation relation using the Hertz model.

RESULTS

Young's modulus was 1,720+/-880 Pa (range: 409-3,210 Pa) in the 18 cynomolgus monkey lenses.

CONCLUSIONS

AFM can be used to provide measurements of the elasticity of the whole lens including the capsule. Values obtained using AFM on cynomolgus monkey lenses are similar to published values obtained using dynamic mechanical analysis on young human lenses.

摘要

目的

证明使用原子力显微镜（AFM）测量完整晶状体弹性的可行性。

方法

对18只新鲜食蟹猴尸体眼睛（4 - 10岁，死后<1天）的完整晶状体进行AFM弹性测量，这些眼睛仍附着在其小带 - 睫状体 - 巩膜框架上。在去除结膜、脂肪和肌肉组织后，通过在巩膜上粘结一个塑料环来制备眼睛。切开后极，去除多余的玻璃体，将眼睛的前部放在聚四氟乙烯载玻片上以保护晶状体的后极。然后切开角膜和虹膜。接着将晶状体 - 小带 - 睫状体 - 巩膜切片放入充满平衡盐溶液的培养皿中，置于专为力测量设计的AFM系统中。接下来，用AFM悬臂尖端探测完整晶状体前表面的中心极。记录的AFM悬臂偏转 - 压痕曲线用于在排除悬臂在硬表面上的偏转后得出晶状体的力 - 压痕曲线。使用赫兹模型根据力 - 压痕关系计算晶状体的杨氏模量。

结果

18只食蟹猴晶状体的杨氏模量为1720±880 Pa（范围：409 - 3210 Pa）。

结论

AFM可用于测量包括晶状体囊膜在内的整个晶状体的弹性。在食蟹猴晶状体上使用AFM获得的值与在年轻人类晶状体上使用动态力学分析获得的已发表值相似。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/6540/2649306/a50896d0ece7/mv-v13-504-f1.jpg

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猴眼晶状体弹性的原子力显微镜测量

Atomic force microscopy measurements of lens elasticity in monkey eyes.

作者信息

机构信息

出版信息

PURPOSE

METHODS

RESULTS

CONCLUSIONS

目的

方法

结果

结论

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