Abstract
Despite being used clinically as a noninvasive flow visualization tool, color flow imaging (CFI) is known to be prone to aliasing artifacts that arise due to fast blood flow beyond the detectable limit. From a visualization standpoint, these aliasing artifacts obscure proper interpretation of flow patterns in the image view. Current solutions for resolving aliasing artifacts are typically not robust against issues such as double aliasing. In this article, we present a new dealiasing technique based on deep learning principles to resolve CFI aliasing artifacts that arise from single- and double-aliasing scenarios. It works by first using two convolutional neural networks (CNNs) to identify and segment CFI pixel positions with aliasing artifacts, and then it performs phase unwrapping at these aliased pixel positions. The CNN for aliasing identification was devised as a U-net architecture, and it was trained with in vivo CFI frames acquired from the femoral bifurcation that had known presence of single- and double-aliasing artifacts. Results show that the segmentation of aliased CFI pixels was achieved successfully with intersection over union approaching 90%. After resolving these artifacts, the dealiased CFI frames consistently rendered the femoral bifurcation's triphasic flow dynamics over a cardiac cycle. For dealiased CFI pixels, their root-mean-squared difference was 2.51% or less compared with manual dealiasing. Overall, the proposed dealiasing framework can extend the maximum flow detection limit by fivefold, thereby improving CFI's flow visualization performance.
Highlights
C OLOR flow imaging (CFI) [1] has long been a popular modality for noninvasive mapping of blood flow in Manuscript received May 5, 2020; accepted June 7, 2020
We present a new dealiasing framework that is based on deep learning principles to suppress aliasing artifacts in color flow imaging (CFI) frames
To facilitate performance investigation on the convolutional neural networks (CNNs)-based dealiasing framework, in vivo data sets were acquired from ultrasound long-axis acquisitions of the femoral bifurcation, which was chosen for its non-trivial geometry and triphasic flow characteristics with large variations in flow velocity over a cardiac cycle [31]
Summary
C OLOR flow imaging (CFI) [1] has long been a popular modality for noninvasive mapping of blood flow in Manuscript received May 5, 2020; accepted June 7, 2020. Date of publication June 10, 2020; date of current version November 23, 2020. 04042), Canadian Institutes of Health Research (PJT-153240), Canada. Foundations for Innovation (36138), and Ontario Early Researcher Award (ER16-12-186). H. Yu are with the Schlegel Research Institute for Aging, University of Waterloo, Waterloo, ON N2L 3G1, Canada, and with the Department of Electrical and Computer Engineering, University of Waterloo, Waterloo, Jason S. Au is with the Department of Kinesiology, University of Waterloo, Waterloo, ON N2L 3G1, Canada
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