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用视网膜功能成像仪(RFI)评估人眼结合膜微血管。

Human conjunctival microvasculature assessed with a retinal function imager (RFI).

机构信息

Bascom Palmer Eye Institute, University of Miami, Miami, FL 33136, USA.

出版信息

Microvasc Res. 2013 Jan;85:134-7. doi: 10.1016/j.mvr.2012.10.003. Epub 2012 Oct 16.

DOI:10.1016/j.mvr.2012.10.003
PMID:23084966
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3534915/
Abstract

The conjunctival and cerebral vasculatures share similar embryological origins, with similar structural and physiological characteristics. Tracking the conjunctival microvasculature may provide useful information for predicting the onset, progression and prognosis of both systemic and central nervous system (CNS) vascular diseases. The bulbar conjunctival vasculature was imaged using a retinal function imager (RFI, Optical Imaging Ltd, Rehovot, Israel). Hemoglobin in red blood cells was used as an intrinsic motion-contrast agent in the generation of detailed noninvasive capillary-perfusion maps (nCPMs) and the calculation of the blood flow velocity. Five healthy subjects were imaged under normal conditions and again under the stress condition of wearing a contact lens. The retina was also imaged in one eye of one subject for comparison. The nCPMs showed the conjunctival microvasculature in exquisite detail, which appeared as clear as the retinal nCPMs. The blood flow velocities in the temporal conjunctival microvasculature were 0.86±0.08 (mean±SD, mm/s) for the bare eye and 0.99±0.11 mm/s with contact lens wear. It is feasible to use RFI for imaging the conjunctival vasculature.

摘要

结膜和脑脉管系统具有相似的胚胎起源,具有相似的结构和生理特征。追踪结膜微血管可以为预测全身和中枢神经系统 (CNS) 血管疾病的发作、进展和预后提供有用信息。使用视网膜功能成像仪 (RFI,以色列 Optical Imaging Ltd) 对球结膜脉管系统进行成像。红细胞中的血红蛋白用作固有运动对比剂,以生成详细的非侵入性毛细血管灌注图 (nCPM) 并计算血流速度。在正常条件下和佩戴隐形眼镜的应激条件下对 5 名健康受试者进行成像。还对一只眼睛的视网膜进行成像,以进行比较。nCPM 以非常精细的细节显示了结膜微血管,其清晰度与视网膜 nCPM 相当。裸眼时颞侧结膜微血管的血流速度为 0.86±0.08(平均值±标准差,mm/s),戴隐形眼镜时为 0.99±0.11mm/s。使用 RFI 对结膜脉管系统进行成像是可行的。

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