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Deep‐learning‐based motion correction in <scp>optical coherence tomography</scp> angiography

Ang Li, Congwu Du, Yingtian Pan

2021Journal of Biophotonics17 citationsDOIOpen Access PDF

Abstract

Optical coherence tomography angiography (OCTA) is a widely applied tool to image microvascular networks with high spatial resolution and sensitivity. Due to limited imaging speed, the artifacts caused by tissue motion can severely compromise visualization of the microvascular networks and quantification of OCTA images. In this article, we propose a deep-learning-based framework to effectively correct motion artifacts and retrieve microvascular architectures. This method comprised two deep neural networks in which the first subnet was applied to distinguish motion corrupted B-scan images from a volumetric dataset. Based on the classification results, the artifacts could be removed from the en face maximum-intensity-projection (MIP) OCTA image. To restore the disturbed vasculature induced by artifact removal, the second subnet, an inpainting neural network, was utilized to reconnect the broken vascular networks. We applied the method to postprocess OCTA images of the microvascular networks in mouse cortex in vivo. Both image comparison and quantitative analysis show that the proposed method can significantly improve OCTA image by efficiently recovering microvasculature from the overwhelming motion artifacts.

Topics & Concepts

Optical coherence tomographyOptical coherence tomography angiographyTomographyMotion (physics)Coherence (philosophical gambling strategy)AngiographyComputer scienceArtificial intelligenceOpticsPhysicsComputer visionMedicineRadiologyQuantum mechanicsOptical Coherence Tomography ApplicationsPhotoacoustic and Ultrasonic ImagingRetinal Imaging and Analysis
Deep‐learning‐based motion correction in <scp>optical coherence tomography</scp> angiography | Litcius