Tanabene, A., Chaithya, G. R., Massire, A., Nadar, M., & Ciuciu, P. (2024). Benchmarking 3D multi-coil NC-PDNet MRI reconstruction. arXiv preprint arXiv:2411.05883.
This research paper investigates the efficacy of NC-PDNet, a deep learning model, in reconstructing 3D multi-coil MRI data acquired using non-Cartesian undersampling techniques. The study aims to benchmark the model's performance with various undersampling patterns and assess the impact of different training strategies.
The researchers utilized the Calgary-Campinas dataset, comprising 3D T1-weighted gradient-recalled echo scans from healthy subjects, to train and evaluate the NC-PDNet model. They retrospectively undersampled the data using four distinct non-Cartesian trajectories: 3D radial, 3D cones, twisted projection imaging (TPI), and GoLF-SPARKLING. The model was trained using channel-specific and channel-agnostic approaches, with and without coil compression, to analyze the impact on reconstruction quality. Performance was evaluated using peak signal-to-noise ratio (PSNR) and structural similarity index (SSIM).
The study revealed that NC-PDNet, trained with the GoLF-SPARKLING trajectory, outperformed other undersampling patterns, achieving higher PSNR and SSIM scores. This superior performance is attributed to the unique design of GoLF-SPARKLING, which incorporates Cartesian sampling in the central k-space region, enabling accurate sensitivity map estimation. Channel-agnostic training proved to be a practical and efficient approach, yielding comparable results to channel-specific training without requiring separate models. Coil compression, while slightly reducing PSNR, significantly reduced memory footprint and computational demand without compromising structural integrity, making it a viable option for resource-constrained scenarios.
The research concludes that NC-PDNet, coupled with the GoLF-SPARKLING trajectory, offers a promising solution for fast and high-quality 3D multi-coil non-Cartesian MRI reconstruction. The study highlights the importance of trajectory design in achieving optimal reconstruction quality and advocates for channel-agnostic training with coil compression as a practical and efficient strategy.
This research significantly contributes to the field of MRI reconstruction by demonstrating the potential of deep learning models like NC-PDNet in accelerating scan times without compromising image quality. The findings have important implications for clinical practice, particularly in time-sensitive applications and for improving patient comfort by reducing scan durations.
The study acknowledges the retrospective nature of the data used and suggests validating the findings on prospectively undersampled data. Future research directions include exploring the scalability of NC-PDNet in more challenging imaging setups, such as higher resolution acquisitions, and investigating its performance with other emerging non-Cartesian trajectories.
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