# Accelerated Coronary MRI with sRAKI: A Database-Free Self-Consistent   Neural Network k-space Reconstruction for Arbitrary Undersampling

**Authors:** 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, (2) Center, for Magnetic Resonance Research, University of Minnesota, Minneapolis, MN,, (3) Department of Imaging Physics, Delft University of Technology, Delft,, Netherlands, (4) Department of Radiology, University Hospital (CHUV) and, University of Lausanne (UNIL), Lausanne, Switzerland, (5) Center for, Biomedical Imaging (CIBM), Lausanne, Switzerland)

arXiv: 1907.08137 · 2020-07-01

## 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.

## Key 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, $\ell_1$-SPIRiT and sRAKI for acceleration rates of 2 to 5. Additionally, prospectively undersampled whole-heart coronary MRI was acquired to further evaluate performance. The results indicate that sRAKI reduces noise amplification and blurring artifacts compared with SPIRiT and $\ell_1$-SPIRiT, especially at high acceleration rates in targeted data. Quantitative analysis shows that sRAKI improves normalized mean-squared-error (~44% and ~21% over SPIRiT and $\ell_1$-SPIRiT at rate 5) and vessel sharpness (~10% and ~20% over SPIRiT and $\ell_1$-SPIRiT at rate 5). In addition, whole-heart data shows the sharpest coronary arteries when resolved using sRAKI, with 11% and 15% improvement in vessel sharpness over SPIRiT and $\ell_1$-SPIRiT, respectively. Thus, sRAKI is a database-free neural network-based reconstruction technique that may further accelerate coronary MRI with arbitrary undersampling patterns, while improving noise resilience over linear parallel imaging and image sharpness over $\ell_1$ regularization techniques.

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Source: https://tomesphere.com/paper/1907.08137