English

SPICER: Self-Supervised Learning for MRI with Automatic Coil Sensitivity Estimation and Reconstruction

Image and Video Processing 2024-06-07 v2

Abstract

Deep model-based architectures (DMBAs) integrating physical measurement models and learned image regularizers are widely used in parallel magnetic resonance imaging (PMRI). Traditional DMBAs for PMRI rely on pre-estimated coil sensitivity maps (CSMs) as a component of the measurement model. However, estimation of accurate CSMs is a challenging problem when measurements are highly undersampled. Additionally, traditional training of DMBAs requires high-quality groundtruth images, limiting their use in applications where groundtruth is difficult to obtain. This paper addresses these issues by presenting SPICE as a new method that integrates self-supervised learning and automatic coil sensitivity estimation. Instead of using pre-estimated CSMs, SPICE simultaneously reconstructs accurate MR images and estimates high-quality CSMs. SPICE also enables learning from undersampled noisy measurements without any groundtruth. We validate SPICE on experimentally collected data, showing that it can achieve state-of-the-art performance in highly accelerated data acquisition settings (up to 10x).

Keywords

Cite

@article{arxiv.2210.02584,
  title  = {SPICER: Self-Supervised Learning for MRI with Automatic Coil Sensitivity Estimation and Reconstruction},
  author = {Yuyang Hu and Weijie Gan and Chunwei Ying and Tongyao Wang and Cihat Eldeniz and Jiaming Liu and Yasheng Chen and Hongyu An and Ulugbek S. Kamilov},
  journal= {arXiv preprint arXiv:2210.02584},
  year   = {2024}
}
R2 v1 2026-06-28T02:53:39.693Z