Joint multi-field T1 quantification for fast field-cycling MRI

Markus Bödenler; Oliver Maier; Rudolf Stollberger; Lionel M Broche; P James Ross; Mary-Joan MacLeod; Hermann Scharfetter

doi:10.1002/mrm.28857

Joint multi-field T1 quantification for fast field-cycling MRI

Markus Bödenler^*, Oliver Maier, Rudolf Stollberger, Lionel M Broche, P James Ross, Mary-Joan MacLeod, Hermann Scharfetter

^*Korrespondierende/r Autor/-in für diese Arbeit

Publikation: Beitrag in einer Fachzeitschrift › Artikel › Begutachtung

Abstract

PURPOSE: Recent developments in hardware design enable the use of fast field-cycling (FFC) techniques in MRI to exploit the different relaxation rates at very low field strength, achieving novel contrast. The method opens new avenues for in vivo characterizations of pathologies but at the expense of longer acquisition times. To mitigate this, we propose a model-based reconstruction method that fully exploits the high information redundancy offered by FFC methods.

METHODS: The proposed model-based approach uses joint spatial information from all fields by means of a Frobenius - total generalized variation regularization. The algorithm was tested on brain stroke images, both simulated and acquired from FFC patients scans using an FFC spin echo sequences. The results are compared to three non-linear least squares fits with progressively increasing complexity.

RESULTS: The proposed method shows excellent abilities to remove noise while maintaining sharp image features with large signal-to-noise ratio gains at low-field images, clearly outperforming the reference approach. Especially patient data show huge improvements in visual appearance over all fields.

CONCLUSION: The proposed reconstruction technique largely improves FFC image quality, further pushing this new technology toward clinical standards.

Originalsprache	englisch
Seiten (von - bis)	2049-2063
Seitenumfang	15
Fachzeitschrift	Magnetic Resonance in Medicine
Jahrgang	86
Ausgabenummer	4
Frühes Online-Datum	10 Juni 2021
DOIs	https://doi.org/10.1002/mrm.28857
Publikationsstatus	Veröffentlicht - Okt. 2021

ASJC Scopus subject areas

Radiologie, Nuklearmedizin und Bildgebung

Fields of Expertise

Human- & Biotechnology

Kooperationen

BioTechMed-Graz

UN SDGs

Dieser Output leistet einen Beitrag zu folgendem(n) Ziel(en) für nachhaltige Entwicklung

Zugriff auf Dokument

10.1002/mrm.28857Lizenz: CC BY-NC-ND 4.0

Andere Dateien und Links

http://www.scopus.com/inward/record.url?scp=85107439729&partnerID=8YFLogxK

Dieses zitieren

@article{f56a14744f614060a10a0ffcab4b63a8,

title = "Joint multi-field T1 quantification for fast field-cycling MRI",

abstract = "PURPOSE: Recent developments in hardware design enable the use of fast field-cycling (FFC) techniques in MRI to exploit the different relaxation rates at very low field strength, achieving novel contrast. The method opens new avenues for in vivo characterizations of pathologies but at the expense of longer acquisition times. To mitigate this, we propose a model-based reconstruction method that fully exploits the high information redundancy offered by FFC methods.METHODS: The proposed model-based approach uses joint spatial information from all fields by means of a Frobenius - total generalized variation regularization. The algorithm was tested on brain stroke images, both simulated and acquired from FFC patients scans using an FFC spin echo sequences. The results are compared to three non-linear least squares fits with progressively increasing complexity.RESULTS: The proposed method shows excellent abilities to remove noise while maintaining sharp image features with large signal-to-noise ratio gains at low-field images, clearly outperforming the reference approach. Especially patient data show huge improvements in visual appearance over all fields.CONCLUSION: The proposed reconstruction technique largely improves FFC image quality, further pushing this new technology toward clinical standards.",

keywords = "dispersion, fast field-cycling, low-field MRI, model-based reconstruction, T quantification",

author = "Markus B{\"o}denler and Oliver Maier and Rudolf Stollberger and Broche, {Lionel M} and Ross, {P James} and Mary-Joan MacLeod and Hermann Scharfetter",

note = "{\textcopyright} 2021 The Authors. Magnetic Resonance in Medicine published by Wiley Periodicals LLC on behalf of International Society for Magnetic Resonance in Medicine.",

year = "2021",

month = oct,

doi = "10.1002/mrm.28857",

language = "English",

volume = "86",

pages = "2049--2063",

journal = "Magnetic Resonance in Medicine",

issn = "0740-3194",

publisher = "John Wiley and Sons Inc.",

number = "4",

}

TY - JOUR

T1 - Joint multi-field T1 quantification for fast field-cycling MRI

AU - Bödenler, Markus

AU - Maier, Oliver

AU - Stollberger, Rudolf

AU - Broche, Lionel M

AU - Ross, P James

AU - MacLeod, Mary-Joan

AU - Scharfetter, Hermann

PY - 2021/10

Y1 - 2021/10

N2 - PURPOSE: Recent developments in hardware design enable the use of fast field-cycling (FFC) techniques in MRI to exploit the different relaxation rates at very low field strength, achieving novel contrast. The method opens new avenues for in vivo characterizations of pathologies but at the expense of longer acquisition times. To mitigate this, we propose a model-based reconstruction method that fully exploits the high information redundancy offered by FFC methods.METHODS: The proposed model-based approach uses joint spatial information from all fields by means of a Frobenius - total generalized variation regularization. The algorithm was tested on brain stroke images, both simulated and acquired from FFC patients scans using an FFC spin echo sequences. The results are compared to three non-linear least squares fits with progressively increasing complexity.RESULTS: The proposed method shows excellent abilities to remove noise while maintaining sharp image features with large signal-to-noise ratio gains at low-field images, clearly outperforming the reference approach. Especially patient data show huge improvements in visual appearance over all fields.CONCLUSION: The proposed reconstruction technique largely improves FFC image quality, further pushing this new technology toward clinical standards.

AB - PURPOSE: Recent developments in hardware design enable the use of fast field-cycling (FFC) techniques in MRI to exploit the different relaxation rates at very low field strength, achieving novel contrast. The method opens new avenues for in vivo characterizations of pathologies but at the expense of longer acquisition times. To mitigate this, we propose a model-based reconstruction method that fully exploits the high information redundancy offered by FFC methods.METHODS: The proposed model-based approach uses joint spatial information from all fields by means of a Frobenius - total generalized variation regularization. The algorithm was tested on brain stroke images, both simulated and acquired from FFC patients scans using an FFC spin echo sequences. The results are compared to three non-linear least squares fits with progressively increasing complexity.RESULTS: The proposed method shows excellent abilities to remove noise while maintaining sharp image features with large signal-to-noise ratio gains at low-field images, clearly outperforming the reference approach. Especially patient data show huge improvements in visual appearance over all fields.CONCLUSION: The proposed reconstruction technique largely improves FFC image quality, further pushing this new technology toward clinical standards.

KW - dispersion

KW - fast field-cycling

KW - low-field MRI

KW - model-based reconstruction

KW - T quantification

UR - http://www.scopus.com/inward/record.url?scp=85107439729&partnerID=8YFLogxK

U2 - 10.1002/mrm.28857

DO - 10.1002/mrm.28857

M3 - Article

C2 - 34110028

SN - 0740-3194

VL - 86

SP - 2049

EP - 2063

JO - Magnetic Resonance in Medicine

JF - Magnetic Resonance in Medicine

IS - 4

ER -

Joint multi-field T1 quantification for fast field-cycling MRI

Abstract

ASJC Scopus subject areas

Fields of Expertise

Kooperationen

UN SDGs

Zugriff auf Dokument

Andere Dateien und Links

Fingerprint

Dieses zitieren