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Three-dimensional Optical-resolution Photoacoustic Microscopy
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Speckle Variance Photoacoustic Microscopy for Microhemodynamic Imaging.

Wei Song1, Yiyan Zhuang1, Yifan Yang1

  • 1Nanophotonics Research Center, Institute of Microscale Optoelectronics, Shenzhen University, Shenzhen 518060, China.

ACS Sensors
|April 16, 2024
PubMed
Summary
This summary is machine-generated.

Speckle variance photoacoustic microscopy (SV-PAM) offers label-free, high-resolution 3D hemodynamic imaging of microvasculature. This technique visualizes blood flow and perfusion in real-time, aiding in the study of conditions like stroke.

Keywords:
blood occlusionblood perfusionhemodynamicsin vivo vascular imagingphotoacoustic microscopyspeckle variance

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Area of Science:

  • Biomedical Optics
  • Medical Imaging
  • Microcirculation Research

Background:

  • Photoacoustic microscopy (PAM) uses hemoglobin's optical absorption for label-free microvasculature imaging.
  • Existing PAM methods provide morphological and functional data but can be limited in dynamic hemodynamic assessment.

Purpose of the Study:

  • To introduce Speckle Variance Photoacoustic Microscopy (SV-PAM) for high-resolution, 3D in vivo hemodynamic imaging.
  • To leverage intrinsic contrast from moving red blood cells for enhanced microvascular visualization.

Main Methods:

  • Acquisition of consecutive photoacoustic B-scan frames at identical lateral positions.
  • Calculation of speckle variance from these frames to identify blood perfusion and occlusion.
  • In vivo imaging of microvascular occlusion and reperfusion in mouse ears.

Main Results:

  • SV-PAM successfully recovered 3D hemodynamic images with capillary-level resolution.
  • Accurate identification of blood perfusion and occlusion was achieved, revealing dynamic blood flow.
  • High-resolution hemodynamic imaging demonstrated vascular occlusion and reperfusion dynamics.

Conclusions:

  • SV-PAM provides intrinsic contrast for label-free, high-resolution 3D hemodynamic imaging of microvasculature.
  • The technique enables visualization of dynamic blood flow, perfusion, and occlusion.
  • SV-PAM shows significant potential for biomedical hemodynamic investigations, including stroke imaging.