PURPOSE: To demonstrate the feasibility of accelerating measurements of cardiac fiber structure using simultaneous multislice (SMS) imaging. METHODS: SMS excitation with a blipped controlled aliasing (CAIPI) readout was incorporated into a diffusion-encoded stimulated echo pulse sequence to obtain diffusion measurements in three separate slices of the heart (8-mm thickness, 12-mm gap). A novel image entropy-based method for removing image ghosts in blipped CAIPI acquisitions is also introduced that enables SMS imaging of closely spaced slices in the heart. RESULTS: The average retained signal-to-noise ratio (SNR) using this acquisition scheme is 70% ± 5%, higher than the standard 1/3 = 57% SNR penalty with three-fold acceleration. No significant difference was observed in the apparent diffusion coefficient and helix angle diffusion parameters between a time-equivalent conventional single-slice scan and the three-fold accelerated SMS acquisition. A 10% mean bias was observed in fractional anisotropy between single-slice and SMS acquisitions. CONCLUSION: The new sequence was used to obtain high-quality diffusion measurements in three closely spaced cardiac slices in a clinically feasible nine breath-hold examination. The accelerated multiband sequence is anticipated to improve quantitative measurements of cardiac microstructure by reducing the number of breath-holds required for the scan, making it practical to incorporate diffusion tensor measurements within a comprehensive clinical examination.
PURPOSE: To demonstrate the feasibility of accelerating measurements of cardiac fiber structure using simultaneous multislice (SMS) imaging. METHODS: SMS excitation with a blipped controlled aliasing (CAIPI) readout was incorporated into a diffusion-encoded stimulated echo pulse sequence to obtain diffusion measurements in three separate slices of the heart (8-mm thickness, 12-mm gap). A novel image entropy-based method for removing image ghosts in blipped CAIPI acquisitions is also introduced that enables SMS imaging of closely spaced slices in the heart. RESULTS: The average retained signal-to-noise ratio (SNR) using this acquisition scheme is 70% ± 5%, higher than the standard 1/3 = 57% SNR penalty with three-fold acceleration. No significant difference was observed in the apparent diffusion coefficient and helix angle diffusion parameters between a time-equivalent conventional single-slice scan and the three-fold accelerated SMS acquisition. A 10% mean bias was observed in fractional anisotropy between single-slice and SMS acquisitions. CONCLUSION: The new sequence was used to obtain high-quality diffusion measurements in three closely spaced cardiac slices in a clinically feasible nine breath-hold examination. The accelerated multiband sequence is anticipated to improve quantitative measurements of cardiac microstructure by reducing the number of breath-holds required for the scan, making it practical to incorporate diffusion tensor measurements within a comprehensive clinical examination.
Authors: Lukas Filli; Marco Piccirelli; David Kenkel; Andreas Boss; Andrei Manoliu; Gustav Andreisek; Himanshu Bhat; Val M Runge; Roman Guggenberger Journal: Eur Radiol Date: 2015-09-15 Impact factor: 5.315
Authors: Jana Taron; Petros Martirosian; Thomas Kuestner; Nina F Schwenzer; Ahmed Othman; Jakob Weiß; Mike Notohamiprodjo; Konstantin Nikolaou; Christina Schraml Journal: Eur Radiol Date: 2017-11-13 Impact factor: 5.315
Authors: Choukri Mekkaoui; Timothy G Reese; Marcel P Jackowski; Stephen F Cauley; Kawin Setsompop; Himanshu Bhat; David E Sosnovik Journal: Radiology Date: 2016-09-28 Impact factor: 11.105
Authors: Jana Taron; Petros Martirosian; Nina F Schwenzer; Michael Erb; Thomas Kuestner; Jakob Weiß; Ahmed Othman; Mike Notohamiprodjo; Konstantin Nikolaou; Christina Schraml Journal: MAGMA Date: 2016-04-02 Impact factor: 2.310
Authors: Christian T Stoeck; Aleksandra Kalinowska; Constantin von Deuster; Jack Harmer; Rachel W Chan; Markus Niemann; Robert Manka; David Atkinson; David E Sosnovik; Choukri Mekkaoui; Sebastian Kozerke Journal: PLoS One Date: 2014-09-05 Impact factor: 3.240