使用多曝光激光散斑对比成像和机器学习的实时视频速率灌注成像。

Real-time video-rate perfusion imaging using multi-exposure laser speckle contrast imaging and machine learning.

机构信息

Linköping University, Department of Biomedical Engineering, Linköping, Sweden.

Perimed AB, Järfälla, Stockholm, Sweden.

出版信息

J Biomed Opt. 2020 Nov;25(11). doi: 10.1117/1.JBO.25.11.116007.

DOI:10.1117/1.JBO.25.11.116007

PMID:33191685

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7666876/

Abstract

SIGNIFICANCE

Multi-exposure laser speckle contrast imaging (MELSCI) estimates microcirculatory blood perfusion more accurately than single-exposure LSCI. However, the technique has been hampered by technical limitations due to massive data throughput requirements and nonlinear inverse search algorithms, limiting it to an offline technique where data must be postprocessed.

AIM

To present an MELSCI system capable of continuous acquisition and processing of MELSCI data, enabling real-time video-rate perfusion imaging with high accuracy.

APPROACH

The MELSCI algorithm was implemented in programmable hardware (field programmable gate array) closely interfaced to a high-speed CMOS sensor for real-time calculation. Perfusion images were estimated in real-time from the MELSCI data using an artificial neural network trained on simulated data. The MELSCI perfusion was compared to two existing single-exposure metrics both quantitatively in a controlled phantom experiment and qualitatively in vivo.

RESULTS

The MELSCI perfusion shows higher signal dynamics compared to both single-exposure metrics, both spatially and temporally where heartbeat-related variations are resolved in much greater detail. The MELSCI perfusion is less susceptible to measurement noise and is more linear with respect to laser Doppler perfusion in the phantom experiment (R2 = 0.992).

CONCLUSIONS

The presented MELSCI system allows for real-time acquisition and calculation of high-quality perfusion at 15.6 frames per second.

摘要

意义

多曝光激光散斑对比成像（MELSCI）比单次曝光 LSCI 更能准确估计微循环血液灌注。然而，由于需要大量的数据吞吐量和非线性逆搜索算法，该技术受到技术限制的阻碍，限制了其作为离线技术的应用，其中数据必须进行后处理。

目的

介绍一种能够连续采集和处理 MELSCI 数据的 MELSCI 系统，实现高精度的实时视频帧率灌注成像。

方法

将 MELSCI 算法实现在可编程硬件（现场可编程门阵列）中，并与高速 CMOS 传感器紧密接口，以便实时计算。使用基于模拟数据训练的人工神经网络，从 MELSCI 数据中实时估计灌注图像。在受控的体模实验中，以及在体内进行定性比较，将 MELSCI 灌注与两种现有的单次曝光指标进行了定量比较。

结果

与两种现有的单次曝光指标相比，MELSCI 灌注在空间和时间上都显示出更高的信号动态，其中与心跳相关的变化能够以更高的细节分辨率进行解析。在体模实验中，MELSCI 灌注对测量噪声的敏感性较低，并且与激光多普勒灌注的线性度更高（R2=0.992）。

结论

所提出的 MELSCI 系统允许以 15.6 帧/秒的速度实时采集和计算高质量的灌注。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/ee18/7666876/08dab9de9c06/JBO-025-116007-g001.jpg

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使用多曝光激光散斑对比成像和机器学习的实时视频速率灌注成像。

Real-time video-rate perfusion imaging using multi-exposure laser speckle contrast imaging and machine learning.

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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