Programmable Scanning Diffuse Speckle Contrast Imaging of Cerebral Blood Flow

Overview

Journal Neurophotonics

Date 2025 Jan 28

PMID 39872020

Authors

Faezeh Akbari

Xuhui Liu

Fatemeh Hamedi

Mehrana Mohtasebi

Li Chen

Lei Chen

Guoqiang Yu

Affiliations

Soon will be listed here.

Abstract

Significance: Cerebral blood flow (CBF) imaging is crucial for diagnosing cerebrovascular diseases. However, existing large neuroimaging techniques with high cost, low sampling rate, and poor mobility make them unsuitable for continuous and longitudinal CBF monitoring at the bedside.

Aim: We aimed to develop a low-cost, portable, programmable scanning diffuse speckle contrast imaging (PS-DSCI) technology for fast, high-density, and depth-sensitive imaging of CBF in rodents.

Approach: The PS-DSCI employed a programmable digital micromirror device (DMD) for remote line-shaped laser (785 nm) scanning on tissue surface and synchronized a 2D camera for capturing boundary diffuse laser speckle contrasts. New algorithms were developed to address deformations of line-shaped scanning, thus minimizing CBF reconstruction artifacts. The PS-DSCI was examined in head-simulating phantoms and adult mice.

Results: The PS-DSCI enables resolving intralipid particle flow contrasts at different tissue depths. experiments in adult mice demonstrated the capability of PS-DSCI to image global/regional CBF variations induced by 8% inhalation and transient carotid artery ligations.

Conclusions: Compared with conventional point scanning, line scanning in PS-DSCI significantly increases spatiotemporal resolution. The high sampling rate of PS-DSCI is crucial for capturing rapid CBF changes while high spatial resolution is important for visualizing brain vasculature.

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