View-sharing PROPELLER with pixel-based optimal blade selection: application on dynamic contrast-enhanced imaging.

PURPOSE To achieve better spatial and temporal resolution of dynamic contrast-enhanced MR imaging, the concept of k-space data sharing, or view sharing, can be implemented for PROPELLER acquisition. As found in other view-sharing methods, the loss of high-resolution dynamics is possible for view-sharing PROPELLER (VS-Prop) due to the temporal smoothing effect. The degradation can be more severe when a narrow blade with less phase encoding steps is chosen in the acquisition for higher frame rate. In this study, an iterative algorithm termed pixel-based optimal blade selection (POBS) is proposed to allow spatially dependent selection of the rotating blades, to generate high-resolution dynamic images with minimal reconstruction artifacts. METHODS In the reconstruction of VS-Prop, the central k-space which dominates the image contrast is only provided by the target blade with the peripheral k-space contributed by a minimal number of consecutive rotating blades. To reduce the reconstruction artifacts, the set of neighboring blades exhibiting the closest image contrast with the target blade is picked by POBS algorithm. Numerical simulations and phantom experiments were conducted in this study to investigate the dynamic response and spatial profiles of images generated using our proposed method. In addition, dynamic contrast-enhanced cardiovascular imaging of healthy subjects was performed to demonstrate the feasibility and advantages. RESULTS The simulation results show that POBS VS-Prop can provide timely dynamic response to rapid signal change, especially for a small region of interest or with the use of narrow blades. The POBS algorithm also demonstrates its capability to capture nonsimultaneous signal changes over the entire FOV. In addition, both phantom and in vivo experiments show that the temporal smoothing effect can be avoided by means of POBS, leading to higher wash-in slope of contrast enhancement after the bolus injection. CONCLUSIONS With the satisfactory reconstruction quality provided by the POBS algorithm, VS-Prop acquisition technique may find useful clinical applications in DCE MR imaging studies where both spatial and temporal resolutions play important roles.

[1]  G. Pohost,et al.  Block Regional Interpolation Scheme for k‐Space (BRISK): A Rapid Cardiac Imaging Technique , 1995, Magnetic resonance in medicine.

[2]  K. B. Larson,et al.  A half-Fourier gradient echo technique for dynamic MR imaging. , 1993, Magnetic resonance imaging.

[3]  M. Lustig,et al.  Compressed Sensing MRI , 2008, IEEE Signal Processing Magazine.

[4]  J Hennig,et al.  Phase contrast MRI with improved temporal resolution by view sharing: k-space related velocity mapping properties. , 2001, Magnetic resonance imaging.

[5]  J. J. van Vaals,et al.  “Keyhole” method for accelerating imaging of contrast agent uptake , 1993, Journal of magnetic resonance imaging : JMRI.

[6]  Walter F Block,et al.  Time‐resolved contrast‐enhanced imaging with isotropic resolution and broad coverage using an undersampled 3D projection trajectory , 2002, Magnetic resonance in medicine.

[7]  R Frayne,et al.  Time‐resolved contrast‐enhanced 3D MR angiography , 1996, Magnetic resonance in medicine.

[8]  Tzu-Chao Chuang,et al.  Accelerating EPI Distortion Correction by Utilizing a Modern GPU‐Based Parallel Computation , 2013, Journal of neuroimaging : official journal of the American Society of Neuroimaging.

[9]  Peter Boesiger,et al.  k‐t BLAST and k‐t SENSE: Dynamic MRI with high frame rate exploiting spatiotemporal correlations , 2003, Magnetic resonance in medicine.

[10]  Jürgen R Reichenbach,et al.  Functional magnetic resonance imaging using PROPELLER‐EPI , 2012, Magnetic resonance in medicine.

[11]  F H Epstein,et al.  Adaptive sensitivity encoding incorporating temporal filtering (TSENSE) † , 2001, Magnetic resonance in medicine.

[12]  Peter Boesiger,et al.  Compressed sensing in dynamic MRI , 2008, Magnetic resonance in medicine.

[13]  D C Peters,et al.  Undersampled projection‐reconstruction imaging for time‐resolved contrast‐enhanced imaging , 2000, Magnetic resonance in medicine.

[14]  F. Korosec,et al.  Time-resolved three-dimensional contrast-enhanced MR angiography of the peripheral vessels. , 2002, Radiology.

[15]  J. Pipe Motion correction with PROPELLER MRI: Application to head motion and free‐breathing cardiac imaging , 1999, Magnetic resonance in medicine.

[16]  N J Pelc,et al.  Unaliasing by Fourier‐encoding the overlaps using the temporal dimension (UNFOLD), applied to cardiac imaging and fMRI , 1999, Magnetic resonance in medicine.

[17]  O. Haraldseth,et al.  K‐space substitution: A novel dynamic imaging technique , 1993, Magnetic resonance in medicine.

[18]  T M Grist,et al.  Time‐resolved, undersampled projection reconstruction imaging for high‐resolution CE‐MRA of the distal runoff vessels , 2002, Magnetic resonance in medicine.

[19]  Nicole Seiberlich,et al.  Improved radial GRAPPA calibration for real‐time free‐breathing cardiac imaging , 2011, Magnetic resonance in medicine.

[20]  X Hu,et al.  Reduction of field of view for dynamic imaging , 1994, Magnetic resonance in medicine.

[21]  J Velikina,et al.  Highly constrained backprojection for time‐resolved MRI , 2006, Magnetic resonance in medicine.

[22]  Tzu-Chao Chuang,et al.  PROPELLER EPI: An MRI technique suitable for diffusion tensor imaging at high field strength with reduced geometric distortions , 2005, Magnetic resonance in medicine.