Magnetic resonance imaging at 9.4 T: the Maastricht journey

Dimo Ivanov; Federico De Martino; Elia Formisano; F.J. Fritz; Rainer Goebel; Laurentius Huber; S. Kashyap; Valentin Kemper; Denizhan Kurban; Alard Roebroeck; S. Sengupta; Bettina Sorger; Desmond H.Y. Tse; K. Uludag; C.J. Wiggins; Benedikt A. Poser

doi:10.1007/s10334-023-01080-4

Magnetic resonance imaging at 9.4 T: the Maastricht journey

Dimo Ivanov^*, Federico De Martino, Elia Formisano, F.J. Fritz, Rainer Goebel, Laurentius Huber, S. Kashyap, Valentin Kemper, Denizhan Kurban, Alard Roebroeck, S. Sengupta, Bettina Sorger, Desmond H.Y. Tse, K. Uludag, C.J. Wiggins, Benedikt A. Poser

^*Corresponding author for this work

Research output: Contribution to journal › (Systematic) Review article › peer-review

Abstract

The 9.4 T scanner in Maastricht is a whole-body magnet with head gradients and parallel RF transmit capability. At the time of the design, it was conceptualized to be one of the best fMRI scanners in the world, but it has also been used for anatomical and diffusion imaging. 9.4 T offers increases in sensitivity and contrast, but the technical ultra-high field (UHF) challenges, such as field inhomogeneities and constraints set by RF power deposition, are exacerbated compared to 7 T. This article reviews some of the 9.4 T work done in Maastricht. Functional imaging experiments included blood oxygenation level-dependent (BOLD) and blood-volume weighted (VASO) fMRI using different readouts. BOLD benefits from shorter T-2* at 9.4 T while VASO from longer T-1. We show examples of both ex vivo and in vivo anatomical imaging. For many applications, pTx and optimized coils are essential to harness the full potential of 9.4 T. Our experience shows that, while considerable effort was required compared to our 7 T scanner, we could obtain high-quality anatomical and functional data, which illustrates the potential of MR acquisitions at even higher field strengths. The practical challenges of working with a relatively unique system are also discussed.

Original language	English
Pages (from-to)	159–173
Number of pages	15
Journal	Magnetic Resonance Materials in Physics, Biology and Medicine
Volume	36
Issue number	2
Early online date	Apr 2023
DOIs	https://doi.org/10.1007/s10334-023-01080-4
Publication status	Published - 20 Apr 2023

Keywords

Ultra-high field
9
4 T
fMRI
pTx
POSTMORTEM HUMAN BRAINS
RF PULSES
FUNCTIONAL MRI
GRADIENT-ECHO
FMRI
FIELD
DESIGN
EXCITATION
SHIFT
ARRAY

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Cite this

Ivanov, D., De Martino, F., Formisano, E., Fritz, F. J., Goebel, R., Huber, L., Kashyap, S., Kemper, V., Kurban, D., Roebroeck, A., Sengupta, S., Sorger, B., Tse, D. H. Y., Uludag, K., Wiggins, C. J., & Poser, B. A. (2023). Magnetic resonance imaging at 9.4 T: the Maastricht journey. Magnetic Resonance Materials in Physics, Biology and Medicine, 36(2), 159–173. https://doi.org/10.1007/s10334-023-01080-4

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title = "Magnetic resonance imaging at 9.4 T: the Maastricht journey",

abstract = "The 9.4 T scanner in Maastricht is a whole-body magnet with head gradients and parallel RF transmit capability. At the time of the design, it was conceptualized to be one of the best fMRI scanners in the world, but it has also been used for anatomical and diffusion imaging. 9.4 T offers increases in sensitivity and contrast, but the technical ultra-high field (UHF) challenges, such as field inhomogeneities and constraints set by RF power deposition, are exacerbated compared to 7 T. This article reviews some of the 9.4 T work done in Maastricht. Functional imaging experiments included blood oxygenation level-dependent (BOLD) and blood-volume weighted (VASO) fMRI using different readouts. BOLD benefits from shorter T-2* at 9.4 T while VASO from longer T-1. We show examples of both ex vivo and in vivo anatomical imaging. For many applications, pTx and optimized coils are essential to harness the full potential of 9.4 T. Our experience shows that, while considerable effort was required compared to our 7 T scanner, we could obtain high-quality anatomical and functional data, which illustrates the potential of MR acquisitions at even higher field strengths. The practical challenges of working with a relatively unique system are also discussed.",

keywords = "Ultra-high field, 9, 4 T, fMRI, pTx, POSTMORTEM HUMAN BRAINS, RF PULSES, FUNCTIONAL MRI, GRADIENT-ECHO, FMRI, FIELD, DESIGN, EXCITATION, SHIFT, ARRAY",

author = "Dimo Ivanov and {De Martino}, Federico and Elia Formisano and F.J. Fritz and Rainer Goebel and Laurentius Huber and S. Kashyap and Valentin Kemper and Denizhan Kurban and Alard Roebroeck and S. Sengupta and Bettina Sorger and Tse, {Desmond H.Y.} and K. Uludag and C.J. Wiggins and Poser, {Benedikt A.}",

note = "Funding Information: With the neuroscientific focus in Maastricht, we rely heavily on echo-planar imaging (EPI) sequences, and a head-gradient set was thus chosen for our Siemens system with passively shielded Magnex whole-body magnet. The passively shielded 9.4 T system is part of the Brains Unlimited project including actively shielded whole-body 7 T and 3 T systems by the same vendor. The project was initiated by Rainer Goebel and the funding was provided by the university and the regional government. The system was delivered in May 2013 and first in vivo images were acquired in September 2013. The head-gradient set allows for the rapid gradient switching needed for EPI readouts as well as diffusion imaging. This keeps echo times relatively short for harnessing the SNR gains, while meeting the desire for higher spatial resolutions and countering the shortening of T* and T at 9.4 T. 2 2 Publisher Copyright: {\textcopyright} 2023, The Author(s).",

year = "2023",

month = apr,

day = "20",

doi = "10.1007/s10334-023-01080-4",

language = "English",

volume = "36",

pages = "159–173",

journal = "Magnetic Resonance Materials in Physics, Biology and Medicine",

issn = "1352-8661",

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Ivanov, D , De Martino, F , Formisano, E, Fritz, FJ, Goebel, R, Huber, L, Kashyap, S, Kemper, V, Kurban, D , Roebroeck, A, Sengupta, S, Sorger, B, Tse, DHY, Uludag, K, Wiggins, CJ & Poser, BA 2023, 'Magnetic resonance imaging at 9.4 T: the Maastricht journey', Magnetic Resonance Materials in Physics, Biology and Medicine, vol. 36, no. 2, pp. 159–173. https://doi.org/10.1007/s10334-023-01080-4

TY - JOUR

T1 - Magnetic resonance imaging at 9.4 T: the Maastricht journey

AU - Ivanov, Dimo

AU - De Martino, Federico

AU - Formisano, Elia

AU - Fritz, F.J.

AU - Goebel, Rainer

AU - Huber, Laurentius

AU - Kashyap, S.

AU - Kemper, Valentin

AU - Kurban, Denizhan

AU - Roebroeck, Alard

AU - Sengupta, S.

AU - Sorger, Bettina

AU - Tse, Desmond H.Y.

AU - Uludag, K.

AU - Wiggins, C.J.

AU - Poser, Benedikt A.

N1 - Funding Information: With the neuroscientific focus in Maastricht, we rely heavily on echo-planar imaging (EPI) sequences, and a head-gradient set was thus chosen for our Siemens system with passively shielded Magnex whole-body magnet. The passively shielded 9.4 T system is part of the Brains Unlimited project including actively shielded whole-body 7 T and 3 T systems by the same vendor. The project was initiated by Rainer Goebel and the funding was provided by the university and the regional government. The system was delivered in May 2013 and first in vivo images were acquired in September 2013. The head-gradient set allows for the rapid gradient switching needed for EPI readouts as well as diffusion imaging. This keeps echo times relatively short for harnessing the SNR gains, while meeting the desire for higher spatial resolutions and countering the shortening of T* and T at 9.4 T. 2 2 Publisher Copyright: © 2023, The Author(s).

PY - 2023/4/20

Y1 - 2023/4/20

N2 - The 9.4 T scanner in Maastricht is a whole-body magnet with head gradients and parallel RF transmit capability. At the time of the design, it was conceptualized to be one of the best fMRI scanners in the world, but it has also been used for anatomical and diffusion imaging. 9.4 T offers increases in sensitivity and contrast, but the technical ultra-high field (UHF) challenges, such as field inhomogeneities and constraints set by RF power deposition, are exacerbated compared to 7 T. This article reviews some of the 9.4 T work done in Maastricht. Functional imaging experiments included blood oxygenation level-dependent (BOLD) and blood-volume weighted (VASO) fMRI using different readouts. BOLD benefits from shorter T-2* at 9.4 T while VASO from longer T-1. We show examples of both ex vivo and in vivo anatomical imaging. For many applications, pTx and optimized coils are essential to harness the full potential of 9.4 T. Our experience shows that, while considerable effort was required compared to our 7 T scanner, we could obtain high-quality anatomical and functional data, which illustrates the potential of MR acquisitions at even higher field strengths. The practical challenges of working with a relatively unique system are also discussed.

AB - The 9.4 T scanner in Maastricht is a whole-body magnet with head gradients and parallel RF transmit capability. At the time of the design, it was conceptualized to be one of the best fMRI scanners in the world, but it has also been used for anatomical and diffusion imaging. 9.4 T offers increases in sensitivity and contrast, but the technical ultra-high field (UHF) challenges, such as field inhomogeneities and constraints set by RF power deposition, are exacerbated compared to 7 T. This article reviews some of the 9.4 T work done in Maastricht. Functional imaging experiments included blood oxygenation level-dependent (BOLD) and blood-volume weighted (VASO) fMRI using different readouts. BOLD benefits from shorter T-2* at 9.4 T while VASO from longer T-1. We show examples of both ex vivo and in vivo anatomical imaging. For many applications, pTx and optimized coils are essential to harness the full potential of 9.4 T. Our experience shows that, while considerable effort was required compared to our 7 T scanner, we could obtain high-quality anatomical and functional data, which illustrates the potential of MR acquisitions at even higher field strengths. The practical challenges of working with a relatively unique system are also discussed.

KW - Ultra-high field

KW - 9

KW - 4 T

KW - fMRI

KW - pTx

KW - POSTMORTEM HUMAN BRAINS

KW - RF PULSES

KW - FUNCTIONAL MRI

KW - GRADIENT-ECHO

KW - FMRI

KW - FIELD

KW - DESIGN

KW - EXCITATION

KW - SHIFT

KW - ARRAY

U2 - 10.1007/s10334-023-01080-4

DO - 10.1007/s10334-023-01080-4

M3 - (Systematic) Review article

C2 - 37081247

SN - 1352-8661

VL - 36

SP - 159

EP - 173

JO - Magnetic Resonance Materials in Physics, Biology and Medicine

JF - Magnetic Resonance Materials in Physics, Biology and Medicine

IS - 2

ER -