Abstract
Doppler optical coherence tomography (DOCT) is considered one of the most promising functional imaging modalities for neuro biology research and has demonstrated the ability to quantify cerebral blood flow velocity at a high accuracy. However, the measurement of total absolute blood flow velocity (BFV) of major cerebral arteries is still a difficult problem since it is related to vessel geometry. In this paper, we present a volumetric vessel reconstruction approach that is capable of measuring the absolute BFV distributed along the entire middle cerebral artery (MCA) within a large field-of-view. The Doppler angle at each point of the MCA, representing the vessel geometry, is derived analytically by localizing the artery from pure DOCT images through vessel segmentation and skeletonization. Our approach could achieve automatic quantification of the fully distributed absolute BFV across different vessel branches. Experiments on rodents using swept-source optical coherence tomography showed that our approach was able to reveal the consequences of permanent MCA occlusion with absolute BFV measurement.
Highlights
Doppler Optical Coherence Tomography (DOCT) [1,2,3,4,5,6], or Optical Doppler Tomography, is a functional imaging modality based on Optical Coherence Tomography [7] which is used to image optical scattering media with high resolution based on light interference
DOCT has been shown to be able to image cerebral blood vessel networks in the brain cortex and to reveal changes in blood flow velocity (BFV) within the brain cortex during different types of brain damage such as dura removal [20], cocaine administration [21], and ischemia induced by photodynamic therapy (PDT) [22]
Focusing on the analysis of cerebral hemodynamics, this paper presents a method to quantify the total absolute blood flow velocity in middle cerebral artery (MCA) based on volumetric vessel reconstruction from pure DOCT images
Summary
Doppler Optical Coherence Tomography (DOCT) [1,2,3,4,5,6], or Optical Doppler Tomography, is a functional imaging modality based on Optical Coherence Tomography [7] which is used to image optical scattering media with high resolution based on light interference. First developed in the late ‘90s, DOCT takes advantage of Doppler effects happening at the intersection of light and moving substances (e.g., flowing particles in blood vessels) that result in shifts in the phase component of the back-scattering light. Leveraging this phase shift (Doppler shift), the velocity of such moving substances can be derived. DOCT has been shown to be able to image cerebral blood vessel networks in the brain cortex and to reveal changes in blood flow velocity (BFV) within the brain cortex during different types of brain damage such as dura removal [20], cocaine administration [21], and ischemia induced by photodynamic therapy (PDT) [22]. Given the laser central wavelength λ and the refractive index n of the scattering media, the absolute velocity of the moving particles can be described by v= λ f (1)
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