Volumetric MRI thermometry using a three‐dimensional stack‐of‐stars echo‐planar imaging pulse sequence

Volumetric MRI thermometry using a three‐dimensional stack‐of‐stars echo‐planar imaging pulse sequence

Purpose To measure temperature over a large brain volume with fine spatiotemporal resolution. Methods A three‐dimensional stack‐of‐stars echo‐planar imaging sequence combining echo‐planar imaging and radial sampling with golden angle spacing was implemented at 3T for proton resonance frequency‐shift...

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Bibliographic Details
Published in:Magnetic resonance in medicine Vol. 79; no. 4; pp. 2003 - 2013
Main Authors: Jonathan, Sumeeth V., Grissom, William A.
Format: Journal Article
Language:English
Published: United States Wiley Subscription Services, Inc 01-04-2018
Subjects:
Acceleration
Aliasing
Brain
Brain mapping
Dimensional tolerances
echo‐planar imaging
Fourier transforms
high‐intensity focused ultrasound
Image acquisition
Image processing
Image reconstruction
In vivo methods and tests
Magnetic resonance imaging
magnetic resonance imaging‐guided focused ultrasound
Mapping
MR thermometry
Neuroimaging
non‐Cartesian
Proton resonance
Resonance
Sonication
Spatial discrimination
Spatial resolution
Standard deviation
Stars
Temperature effects
Temperature tolerance
Thermometers
Thermometry
Ultrasound
echo-planar imaging
non-Cartesian
MR thermometry
magnetic resonance imaging-guided focused ultrasound
high-intensity focused ultrasound
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Summary:Purpose To measure temperature over a large brain volume with fine spatiotemporal resolution. Methods A three‐dimensional stack‐of‐stars echo‐planar imaging sequence combining echo‐planar imaging and radial sampling with golden angle spacing was implemented at 3T for proton resonance frequency‐shift temperature imaging. The sequence acquires a 188x188x43 image matrix with 1.5x1.5x2.75 mm3 spatial resolution. Temperature maps were reconstructed using sensitivity encoding (SENSE) image reconstruction followed by the image domain hybrid method, and using the k‐space hybrid method. In vivo temperature maps were acquired without heating to measure temperature precision in the brain, and in a phantom during high‐intensity focused ultrasound sonication. Results In vivo temperature standard deviation was less than 1°C at dynamic scan times down to 0.75 s. For a given frame rate, scanning at a minimum repetition time (TR) with minimum acceleration yielded the lowest standard deviation. With frame rates around 3 s, the scan was tolerant to a small number of receive coils, and temperature standard deviation was 48% higher than a standard two‐dimensional Fourier transform temperature mapping scan, but provided whole‐brain coverage. Phantom temperature maps with no visible aliasing were produced for dynamic scan times as short as 0.38 s. k‐Space hybrid reconstructions were more tolerant to acceleration. Conclusion Three‐dimensional stack‐of‐stars echo‐planar imaging temperature mapping provides volumetric brain coverage and fine spatiotemporal resolution. Magn Reson Med 79:2003–2013, 2018. © 2017 International Society for Magnetic Resonance in Medicine.
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ISSN:0740-3194
1522-2594
DOI:10.1002/mrm.26862