血流形态:超声监测脊髓微循环的形态学分割。

Denis Routkevitch, Andrew M Hersh, Kelley M Kempski, Max Kerensky, Nicholas Theodore, Nitish V Thakor, Amir Manbachi
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引用次数: 2

摘要

脊髓微血管成像在指导脊髓损伤(SCI)的重症监护管理方面具有巨大的潜力。传统上,造影剂首选用于脊髓血管成像,这不利于长期监测损伤。在这里,我们提出了FlowMorph,一种使用数学形态学技术来分割大鼠脊髓非对比多普勒视频的算法。通过分割,它测量单个血管的参数,如流速、速率和半径,并在单个血管中显示可见的心脏周期,以显示时空分辨率。分割血管轮廓很好,几乎没有多余的标记,轮廓随着时间的推移是平滑的。穿孔血管的半径测量与文献中通过其他方法看到的相似。通过与人工测量和体外微影标准的比较验证了该算法,突出了未来改进的重点。该方法对今后研究脊髓损伤血管效应具有重要意义,也可应用于其他物种。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
FlowMorph: Morphological Segmentation of Ultrasound-Monitored Spinal Cord Microcirculation.

Imaging of spinal cord microvasculature holds great potential in directing critical care management of spinal cord injury (SCI). Traditionally, contrast agents are preferred for imaging of the spinal cord vasculature, which is disadvantageous for long-term monitoring of injury. Here, we present FlowMorph, an algorithm that uses mathematical morphology techniques to segment non-contrast Doppler-based videos of rat spinal cord. Using the segmentation, it measures single-vessel parameters such as flow velocity, rate, and radius, with visible cardiac cycles in individual vessels showcasing the spatiotemporal resolution. The segmentation outlines vessels well with little extraneous labeling, and outlines are smooth through time. Radius measurements of perforating vessels are similar to what is seen in the literature through other methods. Verification of the algorithm through comparison to manual measurement and in vitro microphantom standards highlights points of future improvement. This method will be vital for future work studying the vascular effects of SCI and can be adopted to other species as well.

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