使用压力驱动流系统评估激光散斑对比成像。

Using pressure-driven flow systems to evaluate laser speckle contrast imaging.

机构信息

The University of Texas at Austin, Department of Biomedical Engineering, Austin, Texas, United States.

出版信息

J Biomed Opt. 2023 Mar;28(3):036003. doi: 10.1117/1.JBO.28.3.036003. Epub 2023 Mar 11.

DOI:10.1117/1.JBO.28.3.036003

PMID:36915371

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10007838/

Abstract

SIGNIFICANCE

Microfluidic flow phantom studies are commonly used for characterizing the performance of laser speckle contrast imaging (LSCI) instruments. The selection of the flow control system is critical for the reliable generation of flow during testing. The majority of recent LSCI studies using microfluidics used syringe pumps for flow control.

AIM

We quantified the uncertainty in flow generation for a syringe pump and a pressure-regulated flow system. We then assessed the performance of both LSCI and multi-exposure speckle imaging (MESI) using the pressure-regulated flow system across a range of flow speeds.

APPROACH

The syringe pump and pressure-regulated flow systems were evaluated during stepped flow profile experiments in a microfluidic device using an inline flow sensor. The uncertainty associated with each flow system was calculated and used to determine the reliability for instrument testing. The pressure-regulated flow system was then used to characterize the relative performance of LSCI and MESI during stepped flow profile experiments while using the inline flow sensor as reference.

RESULTS

The pressure-regulated flow system produced much more stable and reproducible flow outputs compared to the syringe pump. The expanded uncertainty for the syringe pump was 8 to higher than that of the pressure-regulated flow system across the tested flow speeds. Using the pressure-regulated flow system, MESI outperformed single-exposure LSCI at all flow speeds and closely mirrored the flow sensor measurements, with average errors of and , respectively.

CONCLUSIONS

Pressure-regulated flow systems should be used instead of syringe pumps when assessing the performance of flow measurement techniques with microfluidic studies. MESI offers more accurate relative flow measurements than traditional LSCI across a wide range of flow speeds.

摘要

意义

微流控流动体模研究常用于评估激光散斑对比成像（LSCI）仪器的性能。流动控制系统的选择对于测试过程中可靠地产生流动至关重要。大多数最近使用微流控的 LSCI 研究使用注射器泵进行流量控制。

目的

我们量化了注射器泵和压力调节流量系统产生流动的不确定性。然后，我们使用压力调节流量系统在一系列流速下评估了 LSCI 和多曝光散斑成像（MESI）的性能。

方法

在微流控装置中的在线流量传感器中，通过分步流量曲线实验评估注射器泵和压力调节流量系统。计算每个流量系统的不确定度，并用于确定仪器测试的可靠性。然后，使用压力调节流量系统在使用在线流量传感器作为参考的分步流量曲线实验中表征 LSCI 和 MESI 的相对性能。

结果

与注射器泵相比，压力调节流量系统产生的流量更稳定且可重复。在测试的流速范围内，注射器泵的扩展不确定度比压力调节流量系统高 8 倍。使用压力调节流量系统，MESI 在所有流速下都优于单次曝光 LSCI，并且与流量传感器测量结果非常吻合，平均误差分别为和。

结论

在使用微流控研究评估流量测量技术的性能时，应使用压力调节流量系统代替注射器泵。MESI 在广泛的流速范围内提供比传统 LSCI 更准确的相对流量测量。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/21b7/10007838/3c8821769b56/JBO-028-036003-g003.jpg

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使用压力驱动流系统评估激光散斑对比成像。

Using pressure-driven flow systems to evaluate laser speckle contrast imaging.

机构信息

出版信息

SIGNIFICANCE

AIM

APPROACH

RESULTS

CONCLUSIONS

意义

目的

方法

结果

结论

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