Advances in Signal Processing for Relaxometry

Noam Ben-Eliezer

doi:10.1016/B978-0-12-817057-1.00007-X

Advances in Signal Processing for Relaxometry

Noam Ben-Eliezer

Department of Bio-Medical Engineering

Research output: Chapter in Book/Report/Conference proceeding › Chapter › peer-review

Abstract

Spin relaxation is probably the most common contrast mechanisms in MRI. Despite it being a molecular mechanism, macroscopic relaxation-weighted images provide valuable clinical information regarding tissue viability and pathological state, while also reflecting microscopic features such as architecture, exchange rates, and biochemical state. In order to tap into the plethora of information offered by spin relaxation the field of MRI is gradually adopting a quantitative approach, where the actual values of T1, T2, and T2* relaxation times are being measured, in contrast to traditional collection of relaxation-weighted images. Notwithstanding the challenges of qMRI, this approach optimally utilizes the dynamic range of each parameter, offers higher sensitivity to tissue changes, and most importantly, improves data reproducibility, and standardization. This chapter focuses on advanced techniques for quantification of relaxation times, the use of comprehensive biophysical signal models, and acceleration schemes designed to shorten qMRI scan time and facilitate its use in the clinic.

Original language	English
Title of host publication	Quantitative Magnetic Resonance Imaging
Editors	Nicole Seiberlich, Vikas Gulani, Fernando Calamante, Adrienne Campbell-Washburn, Mariya Doneva, Houchun Harry Hu, Steven Sourbron
Publisher	Academic Press
Chapter	6
Pages	123-147
Number of pages	25
Volume	1
ISBN (Print)	9780128170571
DOIs	https://doi.org/10.1016/B978-0-12-817057-1.00007-X
State	Published - 2020

Publication series

Name	Advances in Magnetic Resonance Technology and Applications
Publisher	Academic Press

Keywords

Relaxometry
Quantitative MRI
Model-based reconstruction
Dictionary-based reconstruction
Accelerated acquisitions
Quantitative

Access to Document

10.1016/B978-0-12-817057-1.00007-X

https://www.sciencedirect.com/science/article/pii/B978012817057100007X

Cite this

Ben-Eliezer, N. (2020). Advances in Signal Processing for Relaxometry. In N. Seiberlich, V. Gulani, F. Calamante, A. Campbell-Washburn, M. Doneva, H. H. Hu, & S. Sourbron (Eds.), Quantitative Magnetic Resonance Imaging (Vol. 1, pp. 123-147). (Advances in Magnetic Resonance Technology and Applications). Academic Press. https://doi.org/10.1016/B978-0-12-817057-1.00007-X

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keywords = "Relaxometry, Quantitative MRI, Model-based reconstruction, Dictionary-based reconstruction, Accelerated acquisitions, Quantitative",

author = "Noam Ben-Eliezer",

year = "2020",

doi = "10.1016/B978-0-12-817057-1.00007-X",

language = "אנגלית",

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publisher = "Academic Press",

pages = "123--147",

editor = "Nicole Seiberlich and Vikas Gulani and Fernando Calamante and Adrienne Campbell-Washburn and Mariya Doneva and Hu, {Houchun Harry} and Steven Sourbron",

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Advances in Signal Processing for Relaxometry. / Ben-Eliezer, Noam.
Quantitative Magnetic Resonance Imaging. ed. / Nicole Seiberlich; Vikas Gulani; Fernando Calamante; Adrienne Campbell-Washburn; Mariya Doneva; Houchun Harry Hu; Steven Sourbron. Vol. 1 Academic Press, 2020. p. 123-147 (Advances in Magnetic Resonance Technology and Applications).

Research output: Chapter in Book/Report/Conference proceeding › Chapter › peer-review

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AB - Spin relaxation is probably the most common contrast mechanisms in MRI. Despite it being a molecular mechanism, macroscopic relaxation-weighted images provide valuable clinical information regarding tissue viability and pathological state, while also reflecting microscopic features such as architecture, exchange rates, and biochemical state. In order to tap into the plethora of information offered by spin relaxation the field of MRI is gradually adopting a quantitative approach, where the actual values of T1, T2, and T2* relaxation times are being measured, in contrast to traditional collection of relaxation-weighted images. Notwithstanding the challenges of qMRI, this approach optimally utilizes the dynamic range of each parameter, offers higher sensitivity to tissue changes, and most importantly, improves data reproducibility, and standardization. This chapter focuses on advanced techniques for quantification of relaxation times, the use of comprehensive biophysical signal models, and acceleration schemes designed to shorten qMRI scan time and facilitate its use in the clinic.

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KW - Model-based reconstruction

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KW - Accelerated acquisitions

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A2 - Hu, Houchun Harry

A2 - Sourbron, Steven

PB - Academic Press

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Advances in Signal Processing for Relaxometry

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