Laser speckle decorrelation time-based platelet function testing in microfluidic system

Jeon, Hee‐Jae; Qureshi, Muhammad Mohsin; Lee, Seung Yeob; Badadhe, Jaya Dilip; Cho, Hee-Joo; Chung, Euiheon

doi:10.1038/s41598-019-52953-5

Cited by 17 publications

(15 citation statements)

References 29 publications

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“…DT was defined as the time shift required for the correlation coefficient to reach 0.5, similar to Jeon at al. 39,47 NLC mode US videos of each model were captured and stored as real-valued matrices ( m × n × t ) ( m - image depth, n - image width, t - number of frames collected at frame rate, fs ; matrix depiction in Fig. 4-A.)…”

Section: Methodsmentioning

confidence: 99%

Decorrelation Time Mapping as an Analysis Tool for Nanobubble-Based Contrast Enhanced Ultrasound Imaging

Wegierak

Cooley

Perera

et al. 2022

Preprint

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Nanobubbles (NBs) are nanoscale (∼100-500 nm diameter) ultrasound (US) contrast agents that enable new robust applications of contrast enhanced US and US-mediated therapy. Due to their sub-micron size, high particle density, and highly deformable shell, NBs exhibit unique properties. In pathological states of heightened vascular permeability, such as in tumours, NBs can extravasate, enabling extravascular applications not currently possible with clinically available microbubbles (∼1000-10,000 nm diameter). This ability can be explored to develop imaging biomarkers to improve tumour detection. There is a need for an imaging method that can rapidly and effectively separate intravascular versus extravascular NB signal when imaged using nonlinear dynamic contrast enhanced US. Herein, we demonstrated the use of decorrelation time (DT) mapping to achieve this goal. Twoin vitromodels were used to explore the roles of NB velocity and diffusion on DTs. Mice bearing prostate specific membrane antigen (PSMA) expressing flank tumours (n = 7) were injected with bubble agents to evaluate thein vivopotential of this technique. The DT was calculated at each pixel of nonlinear contrast videos to produce DT maps. Across all models, long DT correlated with slowly moving or entrapped NBs while short DT correlated with flowing NBs. DT maps were sensitive to NBs in tumour tissue with high average DT in tumour regions (∼10 s) compared to surrounding normal tissue (∼1 s). Molecular NB targeting to PSMA extended DT (17 s) compared to non-targeted NBs (12 s), demonstrating sensitivity to NB adherence dynamics. Overall, DT mapping ofin vivoNB dynamics produced detailed information of tumour tissue and showed potential for quantifying extravascular NB kinetics. This new NB-contrast enhanced US-based biomarker can be useful in molecular ultrasound imaging, with improved sensitivity and specificity of target tissue detection and potential for use as a predictor of vascular permeability and the enhanced permeability and retention (EPR) effect in tumours.

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Section: Methodsmentioning

confidence: 99%

Decorrelation Time Mapping as an Analysis Tool for Nanobubble-Based Contrast Enhanced Ultrasound Imaging

Wegierak

Cooley

Perera

et al. 2022

Preprint

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“…A speckle pattern remains unchanged over time if the laser light interacts with a static medium. However, if the sample is not static (e.g., blood flowing in a living tissue), the laser speckle pattern would be dynamic, as shown in our previous studies [33][34][35][36].…”

Section: Working Principle Of Osivmentioning

confidence: 97%

Quantitative blood flow estimationin vivoby optical speckle image velocimetry

Qureshi

Liu

Mac

et al. 2021

Preprint

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Speckle based methods are popular non-invasive, label-free full-field optical techniques for imaging blood flow maps at single vessel resolution with a high temporal resolution. However, conventional speckle approach cannot provide an absolute velocity map with magnitude and direction. Here, we report a novel optical speckle image velocimetry (OSIV) technique for measuring the quantitative blood flow vector map by utilizing particle image velocimetry with speckle cross-correlations. We demonstrate that our OSIV instrument has a linearity range up to 7 mm/s, higher than conventional optical methods. Our method can measure the absolute flow vector map at up to 190 Hz without sacrificing the image size, and it eliminates the need for a high-speed camera/detector. We applied OSIV to image the blood flow in a mouse brain, and as a proof of concept, imaged the real-time dynamic changes in the cortical blood flow field during the stroke process in vivo. Our wide-field quantitative flow measurement OSIV method without the need of tracers provides a valuable tool for studying the healthy and diseased brain.

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“…Decorrelation time was defined as the time shift required for the autocorrelation coefficient to reach 0.5. 41,42 Analysis was conducted for continuous imaging experiments with both S-NBs and L-NBs. For each reported data point, approximately 10 adjacent pixels from the same depth were taken as the ROI.…”

Section: Autocorrelation Analysismentioning

confidence: 99%

“…Decorrelation time is defined as the time-shift for the correlation coefficient to reach 0.5. 41,42 Non-zero decorrelation time indicates that there is a pattern between imaging frames. We used this analysis to differentiate flowing bubbles from bubbles that are slowly diffusing through the matrix.…”

Section: Autocorrelation Analysismentioning

confidence: 99%

Real-time imaging of nanobubble ultrasound contrast agent flow, extravasation, and diffusion through an extracellular matrix using a microfluidic model

et al. 2023

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Laser speckle decorrelation time-based platelet function testing in microfluidic system

Cited by 17 publications

References 29 publications

Decorrelation Time Mapping as an Analysis Tool for Nanobubble-Based Contrast Enhanced Ultrasound Imaging

Decorrelation Time Mapping as an Analysis Tool for Nanobubble-Based Contrast Enhanced Ultrasound Imaging

Quantitative blood flow estimationin vivoby optical speckle image velocimetry

Real-time imaging of nanobubble ultrasound contrast agent flow, extravasation, and diffusion through an extracellular matrix using a microfluidic model

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