High resolution time-of-flight MR-angiography at 7 T exploiting VERSE saturation, compressed sensing and segmentation
Meixner C, Liebig P, Speier P, Forman C, Hensel B, Schmidt M, Saake M, Uder M, Dörfler A, Heidemann RM, Schmitter S, Nagel AM (2019)
Publication Type: Journal article
Publication year: 2019
Journal
Book Volume: 63
Pages Range: 193-204
DOI: 10.1016/j.mri.2019.08.014
Abstract
Background: 3D Time-of-Flight (TOF) MR-angiography (MRA) substantially benefits from ultra-high magnetic field strengths (≥7 T) due to increased Signal-to-Noise ratio and improved contrast. However, high-resolution TOF-MRA usually requires long acquisition times. In addition, specific absorption rate constraints limit the choice of optimal pulse sequence parameters, especially if venous saturation is employed. Purpose: To implement and evaluate an arterial TOF-MRA for accelerated high-resolution angiography at ultra-high magnetic field strength. Field strengths/sequence: 7 T modified gradient-echo TOF sequence including venous saturation using Variable-Rate Selective Excitation (VERSE), Compressed Sensing (CS) and sparse application of saturation pulses, called segmentation, were included for acceleration. Assessment: To analyze the acceleration techniques all volunteers were examined with the same protocols. CS with different sampling patterns and regularization factors as well as segmentation were applied for acceleration. For comparison, conventional acceleration techniques were applied (GRAPPA PAT 3 and Partial Fourier (6/8 in slice/phase encoding)). Images were co-registered and 40 mm thick transversal maximum intensity projections were created to calculate the relative number of vessels. To analyze the visibility of small vessels, the lenticulostriate arteries (LSA) were examined. This was done via multiscale vessel enhancement filtering in a VOI and quantification via Fiji ImageJ as well as qualitatively evaluation by two radiologists. Additionally, the venous/arterial vessel-to-background ratios (vVBR/aVBR) were calculated for chosen protocols. Results: For the acceleration of a high resolution TOF-MRA (0.31 mm isotropic), under-sampling of 9.6 showed aliasing artifacts, whereas 7.2 showed no aliasing. The regularization factor R had a strong impact on the image quality according to smoothing (R = 0.01 to R = 0.005) and noise (R = 0.0005 to R = 0.00005). With the alternating sampling patterns it was shown that the k-space center should not be under-sampled too much. Additionally segmentation could be verified to be feasible for stronger acceleration with sufficient venous suppression. Conclusion: The combination of several independent techniques (VERSE, CS with acceleration factor 7.2, R = 0.001, Poisson disc radius of 80%, 3 segments) enables the application of high-resolution (0.31 mm isotropic) TOF-MRA with venous saturation at 7 T in clinical time settings (TA ≈ 5 min) and within the SAR limits.
Authors with CRIS profile
Christian Meixner
Institute of Radiology
Bernhard Hensel
Max Schaldach-Stiftungsprofessur für Biomedizinische Technik
Manuel Schmidt
Department of Neuroradiology
Marc Saake
Medizinische Fakultät
Michael Uder
Lehrstuhl für Diagnostische Radiologie
Arnd Dörfler
Department of Neuroradiology
Armin Michael Nagel
Professur für metabolische und funktionelle MR-Bildgebung
Involved external institutions
Germany (DE)How to cite
APA:
Meixner, C., Liebig, P., Speier, P., Forman, C., Hensel, B., Schmidt, M.,... Nagel, A.M. (2019). High resolution time-of-flight MR-angiography at 7 T exploiting VERSE saturation, compressed sensing and segmentation. Magnetic Resonance Imaging, 63, 193-204. https://dx.doi.org/10.1016/j.mri.2019.08.014
MLA:
Meixner, Christian, et al. "High resolution time-of-flight MR-angiography at 7 T exploiting VERSE saturation, compressed sensing and segmentation." Magnetic Resonance Imaging 63 (2019): 193-204.
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