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Publications

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SNR‐efficient whole‐brain pseudo‐continuous arterial spin labeling perfusion imaging at 7 T

Woods JG. et al, (2025), Magnetic Resonance in Medicine

Combined Angiographic, Structural and Perfusion Radial Imaging using Arterial Spin Labeling

Okell TW. et al, (2025)

Ultra-high temporal resolution 4D angiography using arterial spin labeling with subspace reconstruction.

Shen Q. et al, (2025), Magn Reson Med, 93, 1924 - 1941

Few-shot learning for highly accelerated 3D time-of-flight MRA reconstruction

Li H. et al, (2025)

SNR-Efficient Whole-Brain Pseudo-Continuous Arterial Spin Labeling Perfusion Imaging at 7 Tesla

Woods JG. et al, (2024)

Trial of the cerebral perfusion response to sodium nitrite infusion in patients with acute subarachnoid haemorrhage using arterial spin labelling MRI.

Ezra M. et al, (2024), Nitric Oxide, 153, 50 - 60

Motion correction with subspace-based self-navigation for combined angiography, perfusion and structural imaging

Shen Q. et al, (2024)

Improved visualization of intracranial distal arteries with multiple 2D slice dynamic ASL-MRA and super-resolution convolutional neural network.

Suzuki Y. et al, (2024), Magn Reson Med

Ultra-high temporal resolution 4D angiography using arterial spin labeling with subspace reconstruction

Shen Q. et al, (2024)

Recommendations for quantitative cerebral perfusion MRI using multi‐timepoint arterial spin labeling: Acquisition, quantification, and clinical applications

Woods JG. et al, (2024), Magnetic Resonance in Medicine

The past, present, and future of the brain imaging data structure (BIDS).

Poldrack RA. et al, (2024), Imaging Neurosci (Camb), 2, 1 - 19

Efficient 3D cone trajectory design for improved combined angiographic and perfusion imaging using arterial spin labeling

Shen Q. et al, (2024)

The Past, Present, and Future of the Brain Imaging Data Structure (BIDS).

Poldrack RA. et al, (2024)

Dynamic B0field shimming for improving pseudo-continuous arterial spin labeling at 7 Tesla

Ji Y. et al, (2024)

Why every lab needs a handbook.

Tendler BC. et al, (2023), Elife, 12

Highly accelerated intracranial time-of-flight magnetic resonance angiography using wave-encoding.

Ji Y. et al, (2023), Magn Reson Med

Aerobic exercise increases brain vessel lumen size and blood flow in young adults with elevated blood pressure. Secondary analysis of the TEPHRA randomized clinical trial.

Lapidaire W. et al, (2023), Neuroimage Clin, 37

Time‐encoded pseudo‐continuous arterial spin labeling: Increasing SNR in ASL dynamic angiography

Woods JG. et al, (2022), Magnetic Resonance in Medicine

ASL-BIDS, the brain imaging data structure extension for arterial spin labeling.

Clement P. et al, (2022), Sci Data, 9

Optimization of 4D Combined Angiography and Perfusion using Radial Imaging and Arterial Spin Labeling

Okell TW. and Chiew M., (2022)

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