PURPOSE: Breath-holding is an established strategy for reducing motion artifacts in abdominal imaging. However, the breath-holding capabilities of patients are often overstrained by scans with large coverage and high resolution. In this work, a new strategy for coping with resulting incomplete breath-holds in abdominal imaging is suggested. METHODS: A sampling pattern is designed to support image reconstruction from undersampled data acquired up to any point in time using compressed sensing and parallel imaging. In combination with a navigator-based detection of the onset of respiration, it allows scan termination and thus reconstruction only from consistent data, which suppresses motion artifacts. The spatial resolution is restricted by a lower bound of the sampling density and is increased over the scan, to strike a compromise with the signal-to-noise ratio and undersampling artifacts for any breath-hold duration. RESULTS: The sampling pattern is optimized in phantom experiments and is successfully applied in abdominal gradient-echo imaging including water-fat separation on volunteers. CONCLUSIONS: The new strategy provides images in which motion artifacts are minimized independent of the breath-holding capabilities of patients, and which enhance in terms of spatial resolution, signal-to-noise ratio, and undersampling artifacts with the a priori unknown breath-hold duration actually achieved in a particular scan.
PURPOSE: Breath-holding is an established strategy for reducing motion artifacts in abdominal imaging. However, the breath-holding capabilities of patients are often overstrained by scans with large coverage and high resolution. In this work, a new strategy for coping with resulting incomplete breath-holds in abdominal imaging is suggested. METHODS: A sampling pattern is designed to support image reconstruction from undersampled data acquired up to any point in time using compressed sensing and parallel imaging. In combination with a navigator-based detection of the onset of respiration, it allows scan termination and thus reconstruction only from consistent data, which suppresses motion artifacts. The spatial resolution is restricted by a lower bound of the sampling density and is increased over the scan, to strike a compromise with the signal-to-noise ratio and undersampling artifacts for any breath-hold duration. RESULTS: The sampling pattern is optimized in phantom experiments and is successfully applied in abdominal gradient-echo imaging including water-fat separation on volunteers. CONCLUSIONS: The new strategy provides images in which motion artifacts are minimized independent of the breath-holding capabilities of patients, and which enhance in terms of spatial resolution, signal-to-noise ratio, and undersampling artifacts with the a priori unknown breath-hold duration actually achieved in a particular scan.
Authors: Tao Zhang; Ufra Yousaf; Albert Hsiao; Joseph Y Cheng; Marcus T Alley; Michael Lustig; John M Pauly; Shreyas S Vasanawala Journal: Pediatr Radiol Date: 2015-06-04
Authors: C S de Jonge; B F Coolen; E S Peper; A G Motaal; C Y Nio; I Somers; G J Strijkers; J Stoker; A J Nederveen Journal: Eur Radiol Exp Date: 2019-02-06
Authors: Mary A Neal; Benjamin J Pippard; Kieren G Hollingsworth; Adam Maunder; Prosenjit Dutta; A John Simpson; Andrew M Blamire; James M Wild; Peter E Thelwall Journal: Magn Reson Med Date: 2019-05-17 Impact factor: 4.668