PURPOSE: Physiological nonrigid motion is inevitable when imaging, e.g., abdominal viscera, and can lead to serious deterioration of the image quality. Prospective techniques for motion correction can handle only special types of nonrigid motion, as they only allow global correction. Retrospective methods developed so far need guidance from navigator sequences or external sensors. We propose a fully retrospective nonrigid motion correction scheme that only needs raw data as an input. METHODS: Our method is based on a forward model that describes the effects of nonrigid motion by partitioning the image into patches with locally rigid motion. Using this forward model, we construct an objective function that we can optimize with respect to both unknown motion parameters per patch and the underlying sharp image. RESULTS: We evaluate our method on both synthetic and real data in 2D and 3D. In vivo data was acquired using standard imaging sequences. The correction algorithm significantly improves the image quality. Our compute unified device architecture (CUDA)-enabled graphic processing unit implementation ensures feasible computation times. CONCLUSION: The presented technique is the first computationally feasible retrospective method that uses the raw data of standard imaging sequences, and allows to correct for nonrigid motion without guidance from external motion sensors.
PURPOSE: Physiological nonrigid motion is inevitable when imaging, e.g., abdominal viscera, and can lead to serious deterioration of the image quality. Prospective techniques for motion correction can handle only special types of nonrigid motion, as they only allow global correction. Retrospective methods developed so far need guidance from navigator sequences or external sensors. We propose a fully retrospective nonrigid motion correction scheme that only needs raw data as an input. METHODS: Our method is based on a forward model that describes the effects of nonrigid motion by partitioning the image into patches with locally rigid motion. Using this forward model, we construct an objective function that we can optimize with respect to both unknown motion parameters per patch and the underlying sharp image. RESULTS: We evaluate our method on both synthetic and real data in 2D and 3D. In vivo data was acquired using standard imaging sequences. The correction algorithm significantly improves the image quality. Our compute unified device architecture (CUDA)-enabled graphic processing unit implementation ensures feasible computation times. CONCLUSION: The presented technique is the first computationally feasible retrospective method that uses the raw data of standard imaging sequences, and allows to correct for nonrigid motion without guidance from external motion sensors.
Authors: Daniel Polak; Daniel Nicolas Splitthoff; Bryan Clifford; Wei-Ching Lo; Susie Y Huang; John Conklin; Lawrence L Wald; Kawin Setsompop; Stephen Cauley Journal: Magn Reson Med Date: 2021-08-13 Impact factor: 4.668
Authors: Lucilio Cordero-Grande; Emer J Hughes; Jana Hutter; Anthony N Price; Joseph V Hajnal Journal: Magn Reson Med Date: 2017-06-19 Impact factor: 4.668
Authors: Lucilio Cordero-Grande; Giulio Ferrazzi; Rui Pedro A G Teixeira; Jonathan O'Muircheartaigh; Anthony N Price; Joseph V Hajnal Journal: Magn Reson Med Date: 2020-01-03 Impact factor: 4.668