A new design and rationale for 3D orthogonally oversampled k-space trajectories.
about
Magnetic Resonance Imaging of Phosphocreatine and Determination of BOLD Kinetics in Lower Extremity Muscles using a Dual-Frequency Coil Array.Biomedical applications of sodium MRI in vivoClassification of sodium MRI data of cartilage using machine learningHigh-performance radiofrequency coils for (23)Na MRI: brain and musculoskeletal applications.Sodium MRI: methods and applicationsA method for estimating intracellular sodium concentration and extracellular volume fraction in brain in vivo using sodium magnetic resonance imagingRepeatability of quantitative sodium magnetic resonance imaging for estimating pseudo-intracellular sodium concentration and pseudo-extracellular volume fraction in brain at 3 TGraphical programming interface: A development environment for MRI methods.A nested phosphorus and proton coil array for brain magnetic resonance imaging and spectroscopy.Sodium inversion recovery MRI on the knee joint at 7 T with an optimal control pulse.A radial sampling strategy for uniform k-space coverage with retrospective respiratory gating in 3D ultrashort-echo-time lung imaging.Quantitative sodium MRI of kidney.Evaluation of cartilage repair and osteoarthritis with sodium MRI.Longitudinal study of sodium MRI of articular cartilage in patients with knee osteoarthritis: initial experience with 16-month follow-up.Dynamic phosphocreatine imaging with unlocalized pH assessment of the human lower leg muscle following exercise at 3T.Quantitative sodium MR imaging: A review of its evolving role in medicine.Quantitative sodium magnetic resonance imaging of cartilage, muscle, and tendon.Three-dimensional ultrashort echo-time imaging using a FLORET trajectory.3D image-based navigators for coronary MR angiography.Hybrid radial-cones trajectory for accelerated MRI.A flexible nested sodium and proton coil array with wideband matching for knee cartilage MRI at 3T.Sodium MR Imaging of Articular Cartilage Pathologies.Multidirectional high-moment encoding in phase contrast MRI.Spiral trajectory design: a flexible numerical algorithm and base analytical equations.Distributed spirals: a new class of three-dimensional k-space trajectories.Multipulse sodium magnetic resonance imaging for multicompartment quantification: Proof-of-concept.Fast 3D magnetic resonance fingerprinting for a whole-brain coverage.An eight-channel sodium/proton coil for brain MRI at 3 T.Fast, variable system delay correction for spiral MRI.Quadrupolar jump-and-return pulse sequence for fluid-suppressed sodium MRI of the knee joint at 7T.Efficient sample density estimation by combining gridding and an optimized kernel.Variable density randomized stack of spirals (VDR-SoS) for compressive sensing MRI.Quantitative sodium imaging and gliomas: a feasibility study.
P2860
Q30377009-3B9D37C8-ED6E-4AAB-BE6C-6150E88D32ADQ30636790-B3834B40-9C93-45CE-92C5-39C2E8551633Q30867278-A031B02F-1439-49EC-A567-EA59C84DE558Q30997086-5C619B55-4416-4E9B-930C-EE360CB63485Q34018921-7B3A2D3A-7EE9-4741-B1FC-6AEC063011CFQ34416568-74CD7EED-DDB3-445A-BD4B-DF8BA254DFD4Q35159414-F0BE7E3E-2F18-4133-A9B5-C2CCC8959B32Q35408890-D7C1E93A-1396-44A6-AAC3-BE76F5F40A10Q36296613-0ED9F94C-8C45-49DA-92F5-6EC361362311Q36474078-0E2119F7-1DA6-4D92-84AE-2222C9214DF8Q36803742-06FDBBEE-9004-4405-8602-64399CEC8597Q38366542-4D664565-D75E-4A91-A18C-BB6936AA4461Q38391542-A23F7E30-8DFF-4F49-88F7-5E72207256BBQ38688762-4B11D6E2-9212-4087-8DDE-CE418461D361Q38754830-2FE9AB45-F866-4389-B1EA-CBAF1DBEBBFDQ39021644-78802526-6087-40E3-B7EB-BFB64BB1159FQ39089983-27B295D6-8034-4B3B-BE44-EAB44C4A155DQ39254707-DFF9652C-0F01-4A46-B9FD-63FF3F502037Q39770070-E2B128BF-DF9B-4928-B384-36CD39B2AEB0Q40362399-776F850A-B4D9-47E6-AA4F-4FDEFBC5BA0FQ41652722-1B1A32CC-C5CC-4683-ABA2-618CBBB5B53AQ42399044-370A8F97-A15F-49CF-8B8C-9DD25B07E5A1Q44930113-2A4D46E0-6A2C-4D43-AB29-2D0B67362E13Q46123916-53891AF4-49B0-4EC6-B049-AA2BD434FBFEQ46521958-A2A9F06D-6C62-4194-80B7-10C49CB09D2BQ47138429-CCA5C815-FA55-48DA-901D-1175B5F90EE3Q47289985-A8F6634C-A89B-401E-9793-F8D14C27B0E3Q47894382-F608056E-72AE-4A55-B4F3-192511B3A876Q48119671-B8DD70DB-C344-4564-83CE-F158ED7D9FF7Q48367945-78498FA8-A971-4EB3-8CB0-BF2D6C737E8CQ49150698-F2AE025D-FDB1-41C3-AD88-08222B2D8185Q50874811-624DCF19-E637-4300-B68B-8FE22323343CQ55456914-0FA072F1-9629-451C-A332-8A5A6EAF688D
P2860
A new design and rationale for 3D orthogonally oversampled k-space trajectories.
description
2011 nî lūn-bûn
@nan
2011年の論文
@ja
2011年学术文章
@wuu
2011年学术文章
@zh
2011年学术文章
@zh-cn
2011年学术文章
@zh-hans
2011年学术文章
@zh-my
2011年学术文章
@zh-sg
2011年學術文章
@yue
2011年學術文章
@zh-hant
name
A new design and rationale for 3D orthogonally oversampled k-space trajectories.
@en
A new design and rationale for 3D orthogonally oversampled k-space trajectories.
@nl
type
label
A new design and rationale for 3D orthogonally oversampled k-space trajectories.
@en
A new design and rationale for 3D orthogonally oversampled k-space trajectories.
@nl
prefLabel
A new design and rationale for 3D orthogonally oversampled k-space trajectories.
@en
A new design and rationale for 3D orthogonally oversampled k-space trajectories.
@nl
P2093
P2860
P356
P1476
A new design and rationale for 3D orthogonally oversampled k-space trajectories.
@en
P2093
Ajit Devaraj
Eric A Aboussouan
James G Pipe
Kenneth O Johnson
Nicholas R Zwart
Ryan K Robison
P2860
P304
P356
10.1002/MRM.22918
P577
2011-04-05T00:00:00Z