紫外线激活角膜胶原交联的疗效概况建模

Modeling the efficacy profiles of UV-light activated corneal collagen crosslinking.

作者信息

Lin Jui-Teng, Cheng Da-Chuan

机构信息

New Vision Inc., Taipei, Taiwan.

Department of Biomedical Imaging and Radiological Science, China Medical University, Taichung, Taiwan.

出版信息

PLoS One. 2017 Apr 6;12(4):e0175002. doi: 10.1371/journal.pone.0175002. eCollection 2017.

DOI:10.1371/journal.pone.0175002

PMID:28384251

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5383147/

Abstract

OBJECTIVE

Analysis of the crosslink time, depth and efficacy profiles of UV-light-activated corneal collagen crosslinking (CXL).

METHODS

A modeling system described by a coupled dynamic equations are numerically solved and analytic formulas are derived for the crosslinking time (T*) and crosslinking depth (z*). The z-dependence of the CXL efficacy is numerically produced to show the factors characterizing the profiles.

RESULTS

Optimal crosslink depth (z*) and maximal CXL efficacy (Ceff) have opposite trend with respective to the UV light intensity and RF concentration, where z* is a decreasing function of the riboflavin concentration (C0). In comparison, Ceff is an increasing function of C0 and the UV exposure time (for a fixed UV dose), but it is a decreasing function of the UV light intensity. CXL efficacy is a nonlinear increasing function of [C0/I0]-0.5 and more accurate than that of the linear theory of Bunsen Roscoe law. Depending on the UV exposure time and depth, the optimal intensity ranges from 3 to 30 mW/cm2 for maximal CXL efficacy. For steady state (with long exposure time), low intensity always achieves high efficacy than that of high intensity, when same dose is applied on the cornea.

CONCLUSIONS

The crosslinking depth (z*) and the crosslinking time (T*) have nonlinear dependence on the UV light dose and the efficacy of corneal collagen crosslinking should be characterized by both z* and the efficacy profiles. A nonlinear scaling law is needed for more accurate protocol.

摘要

目的

分析紫外线激活的角膜胶原交联（CXL）的交联时间、深度和疗效曲线。

方法

对由耦合动力学方程描述的建模系统进行数值求解，并推导交联时间（T*）和交联深度（z*）的解析公式。通过数值计算得出CXL疗效随深度（z）的变化情况，以展示表征这些曲线的因素。

结果

最佳交联深度（z*）和最大CXL疗效（Ceff）与紫外线强度和核黄素浓度呈现相反的趋势，其中z*是核黄素浓度（C0）的递减函数。相比之下，Ceff是C0和紫外线暴露时间（对于固定紫外线剂量）的递增函数，但它是紫外线强度的递减函数。CXL疗效是[C0/I0]-0.5的非线性递增函数，比本生-罗斯科定律的线性理论更准确。根据紫外线暴露时间和深度，最大CXL疗效的最佳强度范围为3至30 mW/cm2。对于稳态（长时间暴露），当在角膜上施加相同剂量时，低强度总是比高强度获得更高的疗效。

结论

交联深度（z*）和交联时间（T*）对紫外线剂量具有非线性依赖性，角膜胶原交联的疗效应以z*和疗效曲线来表征。需要一个非线性标度律来制定更准确的方案。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/644c/5383147/3fe9ab33bb49/pone.0175002.g001.jpg

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紫外线激活角膜胶原交联的疗效概况建模

Modeling the efficacy profiles of UV-light activated corneal collagen crosslinking.

作者信息

机构信息

出版信息

OBJECTIVE

METHODS

RESULTS

CONCLUSIONS

目的

方法

结果

结论

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