基于低相干光干涉的眼睛光学生物参数测量研究

目的 眼睛的光学生物参数中的眼轴长度（AL）和角膜曲率半径（CR）可以作为预防和监测眼球近视的两个重要参数。为了提高测量眼轴长度的速度与精度和同步实现角膜曲率高精度动态测量，本文提出一种基于低相干光干涉技术眼睛光学生物参数测量的系统。方法 该系统使用旋转光学延迟线快速改变参考光的光程，利用曲率半径为8 mm的标准件标定人眼角膜顶点到靶环之间的距离，利用角膜的干涉信号对相机和数据采集卡进行触发实现同步采集，从而实现眼轴长度的快速测量和精准定位靶环到角膜顶点之间的距离，同时保证成像系统的放大倍率恒定和数据的实时采集。结果 实验结果表明，这种低相干光干涉测量系统，可以实时测量眼轴长度和角膜曲率半径，眼轴长度误差低于40 μm，人眼角膜曲率半径方差为2.082 36×10^-2 μm。结论 该系统能够快速、精准地测量AL和CR，可在近视的预防和监测中发挥重要作用。     

Full-field optical multi-functional angiography based on endogenous hemodynamic characteristics

Blood flow functional imaging is widely applied in biological research to provide vascular morphological and statistical parameters. It relies on the absorption difference and is, therefore, easily affected by complex biological structures, and it cannot accommodate abundant functional information. We propose a full-field multi-functional angiography method to classify arteriovenous vessels and to display flow velocity and vascular diameter distribution simultaneously. Unlike previous methods, an under-sampled laser Doppler acquisition mode is used to record the low-coherence speckle, and multi-functional angiography is achieved by modulating the endogenous hemodynamic characteristics from low-coherence speckle. To demonstrate the combination of classified angiography, blood flow velocity measurement, and vascular diameter measurement realized using our method, we performed experiments on the flow phantom and living chicken embryos and generated multi-functional angiograms. The proposed method can be used as a label-free multi-functional angiography technique in which red blood cells provide a strong endogenous source of naturally hemodynamic characteristics.     

The measurement of ocular axial length in normal human eyes based on an improved Twyman-Green interferometer

In order to meet the demands of myopia prevention, as well as the increasing needs of measurement for refractive and cataract operations in China, a new axial length (AL) measurement system combining an improved Twyman-Green interferometer with digital signal processing has been established. The ALs of 33 eyes of different optical refractive subjects (−8.50 ~ 0.50 D) were measured with the New AL and intraocular lens (IOL) master. The repeatability of measurements with the New AL was assessed using coefficient of variation (CoV) and intra-group correlation coefficient (ICC). Comparison, correlation, linear regression and agreement of AL between devices were analyzed. There was good repeatability (CoV = 0.0617%, ICC = 0.9999) with the New AL and great agreement has been obtained with both devices. These show that the New AL is capable of providing precise AL values over the normal AL range compared to the IOL master, and indicate that the New AL developed can be used for routine clinical AL measurements.