Noninvasive optical imaging of thrombus formation in mechanical circulatory support devices

Q4 Engineering

Journal of Biorheology Pub Date : 2016-01-01 DOI:10.17106/JBR.30.6

D. Sakota, Tomotaka Murashige, R. Kosaka, Tatsuki Fujiwara, K. Ouchi, M. Nishida, O. Maruyama

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引用次数: 6

Abstract

We developed a hyperspectral imaging (HSI) method to image a rotary blood pump rotating at high speed, and we investigated the optical properties of blood associated with the blood clotting. In vitro antithrombogenic testing was conducted. Fresh porcine blood was circulated by a hydrodynamically levitated centrifugal blood pump while light pulsed at the same frequency as the rotational speed illuminated the bottom surface of the pump. Back scattering was captured with an HSI camera, and the spectral image in the wavelength range from 608 to 752 nm was constructed. Back scattering in the area of suspected thrombus formation decreased. the shape of the spectral image was consistent with that of the thrombus formed in the pump. Moreover, the hemoglobin concentration of the thrombus was quantified, and its value was significantly lower than the total hemoglobin concentration. therefore, it is speculated that the decrease in back scattering is caused by a decrease in the number of red blood cells (rBcs) trapped in the thrombus area due to the surrounding blood flow. It was concluded that this optical technique is able to detect blood clotting using the behavior of rBcs as the optical marker for its detection.

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机械循环支持装置血栓形成的无创光学成像

我们开发了一种高光谱成像(HSI)方法来成像高速旋转的旋转血泵，并研究了与血液凝固相关的血液光学特性。进行体外抗血栓形成试验。新鲜的猪血通过流体动力悬浮离心血泵循环，以与转速相同频率的脉冲光照射泵底表面。利用HSI相机捕获后向散射，构建了608 ~ 752 nm波长范围内的光谱图像。疑似血栓形成区域的后向散射减弱。光谱图像的形状与泵内形成的血栓形状一致。并且对血栓的血红蛋白浓度进行了量化，其值明显低于总血红蛋白浓度。因此，推测后向散射的减少是由于周围血流导致血栓区域内的红细胞数量减少所致。结论是，该光学技术能够检测血凝，使用红细胞的行为作为其检测的光学标记。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Biorheology Engineering-Mechanical Engineering

CiteScore

0.50

自引率

0.00%

发文量