利用影像学方法预测分支视网膜动脉阻塞中初始神经元细胞损伤。
Imaging Hypoxia to Predict Primary Neuronal Cell Damage in Branch Retinal Artery Occlusion.
机构信息
Department of Ophthalmology and Visual Sciences, Vanderbilt University School of Medicine, Nashville, Tennessee, USA.
Department of Molecular Physiology and Biophysics, Vanderbilt University School of Medicine, Nashville, Tennessee, USA.
出版信息
Microcirculation. 2024 Oct;31(7):e12883. doi: 10.1111/micc.12883. Epub 2024 Aug 30.
PURPOSE
To develop a reliable method to generate a mouse model of branch retinal artery occlusion (BRAO) using laser-induced thrombosis of a major artery in the mouse retina. Also, to develop a reliable method to detect retinal hypoxia as predictive biomarker for the risk of neuronal cell damage in BRAO.
METHODS
A reliable and reproducible model of laser-induced BRAO was developed in mouse retina using Rose Bengal. To characterize retinal hypoxia in BRAO, pimonidazole immunostaining and HYPOX-4 molecular imaging methods were used. Terminal deoxynucleotidyl transferase dUTP nick end labelling (TUNEL) was used to characterize neuronal cell damage in the BRAO retina. Expression of mRNA in retinal tissues from BRAO and age-matched control retinas were analyzed using qRT-PCR.
RESULTS
Occlusion of a branch retinal artery near the optic nerve head (ONH) caused a pattern of retinal tissue hypoxia covering about 12.5% of the entire retina. TUNEL-positive cells were localized in all layers in BRAO retinal tissue cross sections. In addition, qRT-PCR data analysis suggests that BRAO is associated with both inflammation and hypoxia.
CONCLUSIONS
This study provides a reliable method for BRAO in mouse retina and demonstrates the utility of molecular imaging method to detect retinal hypoxia as predictive biomarker for the risk of neuronal cell damage in BRAO. In addition, our data suggest that BRAO retinas are associated with inflammation and also associated with hypoxia-related neuronal cell damage.
PERSPECTIVES
Imaging areas of retinal hypoxia may provide accurate diagnosis, evaluating retinal tissue injury from BRAO.
目的
开发一种使用激光诱导小鼠视网膜主要动脉血栓形成来生成分支视网膜动脉闭塞(BRAO)小鼠模型的可靠方法。此外,还开发了一种可靠的方法来检测视网膜缺氧,作为 BRAO 神经元细胞损伤风险的预测生物标志物。
方法
使用孟加拉玫瑰红在小鼠视网膜中开发了一种可靠且可重复的激光诱导 BRAO 模型。为了表征 BRAO 中的视网膜缺氧,使用了 pimonidazole 免疫染色和 HYPOX-4 分子成像方法。末端脱氧核苷酸转移酶 dUTP 缺口末端标记(TUNEL)用于表征 BRAO 视网膜中的神经元细胞损伤。使用 qRT-PCR 分析 BRAO 和年龄匹配对照视网膜组织中的 mRNA 表达。
结果
视神经头(ONH)附近分支视网膜动脉的闭塞导致覆盖整个视网膜约 12.5%的视网膜组织缺氧模式。TUNEL 阳性细胞定位于 BRAO 视网膜组织横切片的所有层中。此外,qRT-PCR 数据分析表明,BRAO 与炎症和缺氧都有关。
结论
本研究为小鼠视网膜中的 BRAO 提供了一种可靠的方法,并证明了分子成像方法检测视网膜缺氧作为 BRAO 神经元细胞损伤风险的预测生物标志物的实用性。此外,我们的数据表明,BRAO 视网膜与炎症有关,也与缺氧相关的神经元细胞损伤有关。
展望
对视网膜缺氧区域进行成像可能为 BRAO 提供准确的诊断,评估视网膜组织损伤。
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