Visualizing cortical blood perfusion after photothrombotic stroke in vivo by needle-shaped beam optical coherence tomography angiography

IF 15.7 Q1 OPTICS PhotoniX Pub Date : 2024-03-27 DOI:10.1186/s43074-024-00124-9
Xiangyu Guo, Jingjing Zhao, Liqun Sun, Varun Gupta, Lin Du, Komal Sharma, Aidan Van Vleck, Kaitlyn Liang, Liangcai Cao, Lingjie Kong, Yuanmu Yang, Yong Huang, Adam de la Zerda, Guofan Jin
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Abstract

Optical imaging techniques provide low-cost, non-radiative images with high spatiotemporal resolution, making them advantageous for long-term dynamic observation of blood perfusion in stroke research and other brain studies compared to non-optical methods. However, high-resolution imaging in optical microscopy fundamentally requires a tight optical focus, and thus a limited depth of field (DOF). Consequently, large-scale, non-stitched, high-resolution images of curved surfaces, like brains, are difficult to acquire without z-axis scanning. To overcome this limitation, we developed a needle-shaped beam optical coherence tomography angiography (NB-OCTA) system, and for the first time, achieved a volumetric resolution of less than 8 μm in a non-stitched volume space of 6.4 mm × 4 mm × 620 μm in vivo. This system captures the distribution of blood vessels at 3.4-times larger depths than normal OCTA equipped with a Gaussian beam (GB-OCTA). We then employed NB-OCTA to perform long-term observation of cortical blood perfusion after stroke in vivo, and quantitatively analyzed the vessel area density (VAD) and the diameters of representative vessels in different regions over 10 days, revealing different spatiotemporal dynamics in the acute, sub-acute and chronic phase of post-ischemic revascularization. Benefiting from our NB-OCTA, we revealed that the recovery process is not only the result of spontaneous reperfusion, but also the formation of new vessels. This study provides visual and mechanistic insights into strokes and helps to deepen our understanding of the spontaneous response of brain after stroke.

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通过针形光束光学相干断层血管成像技术观察光血栓性中风后体内皮层血液灌注情况
光学成像技术可提供低成本、无辐射、高时空分辨率的图像,因此与非光学方法相比,在中风研究和其他脑研究中长期动态观察血液灌注方面具有优势。然而,光学显微镜的高分辨率成像从根本上要求光学聚焦紧密,因此景深(DOF)有限。因此,在没有 Z 轴扫描的情况下,很难获取大脑等曲面的大规模、非拼接、高分辨率图像。为了克服这一限制,我们开发了针形光束光学相干断层血管成像(NB-OCTA)系统,并首次在 6.4 mm × 4 mm × 620 μm 的非缝合体积空间内实现了小于 8 μm 的活体体积分辨率。该系统捕捉到的血管分布深度是配备高斯光束的普通 OCTA(GB-OCTA)的 3.4 倍。随后,我们利用 NB-OCTA 对脑卒中后的皮层血液灌注进行了长期观察,并定量分析了 10 天内不同区域的血管面积密度(VAD)和代表性血管的直径,揭示了缺血后血管再通的急性期、亚急性期和慢性期的不同时空动态。得益于我们的 NB-OCTA,我们发现恢复过程不仅是自发再灌注的结果,也是新血管形成的过程。这项研究提供了对脑卒中的直观和机理认识,有助于加深我们对脑卒中后大脑自发反应的理解。
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CiteScore
25.70
自引率
0.00%
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0
审稿时长
13 weeks
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