Photoacoustic Flow Cytometry for Single Sickle Cell Detection In Vitro and In Vivo

Analytical Cellular Pathology (Amsterdam) Pub Date : 2016-09-01 DOI:10.1155/2016/2642361

C. Cai, D. Nedosekin, Y. Menyaev, M. Sarimollaoglu, M. Proskurnin, V. Zharov

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引用次数: 29

Abstract

Control of sickle cell disease (SCD) stage and treatment efficiency are still time-consuming which makes well-timed prevention of SCD crisis difficult. We show here that in vivo photoacoustic (PA) flow cytometry (PAFC) has a potential for real-time monitoring of circulating sickled cells in mouse model. In vivo data were verified by in vitro PAFC and photothermal (PT) and PA spectral imaging of sickle red blood cells (sRBCs) expressing SCD-associated hemoglobin (HbS) compared to normal red blood cells (nRBCs). We discovered that PT and PA signal amplitudes from sRBCs in linear mode were 2–4-fold lower than those from nRBCs. PT and PA imaging revealed more profound spatial hemoglobin heterogeneity in sRBCs than in nRBCs, which can be associated with the presence of HbS clusters with high local absorption. This hypothesis was confirmed in nonlinear mode through nanobubble formation around overheated HbS clusters accompanied by spatially selective signal amplification. More profound differences in absorption of sRBCs than in nRBCs led to notable increase in PA signal fluctuation (fluctuation PAFC mode) as an indicator of SCD. The obtained data suggest that noninvasive label-free fluctuation PAFC has a potential for real-time enumeration of sRBCs both in vitro and in vivo.

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光声流式细胞术在体外和体内检测单镰状细胞

镰状细胞病(SCD)阶段的控制和治疗效率的提高仍然是一个耗时的过程，这给及时预防SCD危机带来了困难。我们在这里展示了体内光声(PA)流式细胞术(PAFC)具有实时监测小鼠模型中循环镰状细胞的潜力。体内数据通过体外PAFC、光热(PT)和PA光谱成像对表达scd相关血红蛋白(HbS)的镰状红细胞(srbc)进行验证，与正常红细胞(nrbc)进行比较。我们发现srbc在线性模式下的PT和PA信号幅度比nrbc低2 - 4倍。PT和PA成像显示srbc中血红蛋白的空间异质性比nrbc更深刻，这可能与存在高局部吸收的HbS簇有关。这一假设在非线性模式下得到了证实，通过在过热的HbS团簇周围形成纳米气泡并伴有空间选择性信号放大。与nrbc相比，srbc的吸收差异更大，导致作为SCD指标的PA信号波动(波动PAFC模式)显著增加。所获得的数据表明，无创无标签波动PAFC具有实时计数体外和体内红细胞的潜力。

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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Analytical Cellular Pathology (Amsterdam)

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