Accelerated Coronary MRI with sRAKI: A Database-Free Self-Consistent Neural Network k-space Reconstruction for Arbitrary Undersampling
Seyed Amir Hossein Hosseini (1, 2), Chi Zhang (1, 2), Sebastian, Weing\"artner (1, 2, 3), Steen Moeller (2), Matthias Stuber (4, 5),, K\^amil U\v{g}urbil (2), Mehmet Ak\c{c}akaya (1, 2) ((1) Electrical and, Computer Engineering, University of Minnesota, Minneapolis, MN

TL;DR
This paper introduces sRAKI, a neural network-based reconstruction method that accelerates coronary MRI by supporting arbitrary undersampling patterns and improving image quality without requiring a training database.
Contribution
sRAKI extends existing linear methods to nonlinear neural network interpolation, enabling scan-specific, database-free MRI reconstruction with enhanced noise reduction and image sharpness.
Findings
sRAKI outperforms SPIRiT and $ abla$-SPIRiT in noise reduction and artifact suppression.
sRAKI achieves approximately 44% and 21% lower normalized mean-squared-error at acceleration rate 5.
Whole-heart MRI with sRAKI shows 11-15% improvement in vessel sharpness.
Abstract
This study aims to accelerate coronary MRI using a novel reconstruction algorithm, called self-consistent robust artificial-neural-networks for k-space interpolation (sRAKI). sRAKI performs iterative parallel imaging reconstruction by enforcing coil self-consistency using subject-specific neural networks. This approach extends the linear convolutions in SPIRiT to nonlinear interpolation using convolutional neural networks (CNNs). These CNNs are trained individually for each scan using the scan-specific autocalibrating signal (ACS) data. Reconstruction is performed by imposing the learned self-consistency and data-consistency enabling sRAKI to support random undersampling patterns. Fully-sampled targeted right coronary artery MRI was acquired in six healthy subjects for evaluation. The data were retrospectively undersampled, and reconstructed using SPIRiT, -SPIRiT and sRAKI for…
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