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Frequency drift in MR spectroscopy at 3T

Hui, Steve C.N.; Mikkelsen, Mark; Zöllner, Helge J.; Ahluwalia, Vishwadeep; Alcauter, Sarael; Baltusis, Laima; Barany, Deborah A.; Barlow, Laura R.; Becker, Robert; Berman, Jeffrey I.; Berrington, Adam; Bhattacharyya, Pallab K.; Blicher, Jakob Udby; Bogner, Wolfgang; Brown, Mark S.; Calhoun, Vince D.; Castillo, Ryan; Cecil, Kim M.; Choi, Yeo Bi; Chu, Winnie C.W.; Clarke, William T.; Craven, Alexander R.; Cuypers, Koen; Dacko, Michael; de la Fuente-Sandoval, Camilo; Desmond, Patricia; Domagalik, Aleksandra; Dumont, Julien; Duncan, Niall W.; Dydak, Ulrike; Dyke, Katherine; Edmondson, David A.; Ende, Gabriele; Ersland, Lars; Evans, C. John; Fermin, Alan S.R.; Ferretti, Antonio; Fillmer, Ariane; Gong, Tao; Greenhouse, Ian; Grist, James T.; Gu, Meng; Harris, Ashley D.; Hat, Katarzyna; Heba, Stefanie; Heckova, Eva; Hegarty, John P.; Heise, Kirstin-Friederike; Honda, Shiori; Jacobson, Aaron; Jansen, Jacobus F.A.; Jenkins, Christopher W.; Johnston, Stephen J.; Juchem, Christoph; Kangarlu, Alay...

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Authors

Steve C.N. Hui

Mark Mikkelsen

Helge J. Zöllner

Vishwadeep Ahluwalia

Sarael Alcauter

Laima Baltusis

Deborah A. Barany

Laura R. Barlow

Robert Becker

Jeffrey I. Berman

Adam Berrington

Pallab K. Bhattacharyya

Jakob Udby Blicher

Wolfgang Bogner

Mark S. Brown

Vince D. Calhoun

Ryan Castillo

Kim M. Cecil

Yeo Bi Choi

Winnie C.W. Chu

William T. Clarke

Alexander R. Craven

Koen Cuypers

Michael Dacko

Camilo de la Fuente-Sandoval

Patricia Desmond

Aleksandra Domagalik

Julien Dumont

Niall W. Duncan

Ulrike Dydak

David A. Edmondson

Gabriele Ende

Lars Ersland

C. John Evans

Alan S.R. Fermin

Antonio Ferretti

Ariane Fillmer

Tao Gong

Ian Greenhouse

James T. Grist

Meng Gu

Ashley D. Harris

Katarzyna Hat

Stefanie Heba

Eva Heckova

John P. Hegarty

Kirstin-Friederike Heise

Shiori Honda

Aaron Jacobson

Jacobus F.A. Jansen

Christopher W. Jenkins

Stephen J. Johnston

Christoph Juchem

Alayar Kangarlu

Adam B. Kerr

Karl Landheer

Thomas Lange

Phil Lee

Swati Rane Levendovszky

Catherine Limperopoulos

Feng Liu

William Lloyd

David J. Lythgoe

Maro G. Machizawa

Erin L. MacMillan

Richard J. Maddock

Andrei V. Manzhurtsev

María L. Martinez-Gudino

Jack J. Miller

Heline Mirzakhanian

Marta Moreno-Ortega

Paul G. Mullins

Shinichiro Nakajima

Jamie Near

Ralph Noeske

Wibeke Nordhøy

Georg Oeltzschner

Raul Osorio-Duran

Maria C.G. Otaduy

Erick H. Pasaye

Ronald Peeters

Scott J. Peltier

Ulrich Pilatus

Nenad Polomac

Eric C. Porges

Subechhya Pradhan

James Joseph Prisciandaro

Nicolaas A Puts

Caroline D. Rae

Francisco Reyes-Madrigal

Timothy P.L. Roberts

Caroline E. Robertson

Jens T. Rosenberg

Diana-Georgiana Rotaru

Ruth L O'Gorman Tuura

Muhammad G. Saleh

Kristian Sandberg

Ryan Sangill

Keith Schembri

Anouk Schrantee

Natalia A. Semenova

Debra Singel

Rouslan Sitnikov

Jolinda Smith

Yulu Song

Craig Stark

Diederick Stoffers

Stephan P. Swinnen

Rongwen Tain

Costin Tanase

Sofie Tapper

Martin Tegenthoff

Thomas Thiel

Marc Thioux

Peter Truong

Pim van Dijk

Nolan Vella

Rishma Vidyasagar

Andrej Vovk

Guangbin Wang

Lars T. Westlye

Timothy K. Wilbur

William R. Willoughby

Martin Wilson

Hans-Jörg Wittsack

Adam J. Woods

Yen-Chien Wu

Junqian Xu

Maria Yanez Lopez

David K.W. Yeung

Qun Zhao

Xiaopeng Zhou

Gasper Zupan

Richard A.E. Edden



Abstract

Purpose: Heating of gradient coils and passive shim components is a common cause of instability in the B0 field, especially when gradient intensive sequences are used. The aim of the study was to set a benchmark for typical drift encountered during MR spectroscopy (MRS) to assess the need for real-time field-frequency locking on MRI scanners by comparing field drift data from a large number of sites. Method: A standardized protocol was developed for 80 participating sites using 99 3T MR scanners from 3 major vendors. Phantom water signals were acquired before and after an EPI sequence. The protocol consisted of: minimal preparatory imaging; a short pre-fMRI PRESS; a ten-minute fMRI acquisition; and a long post-fMRI PRESS acquisition. Both pre- and post-fMRI PRESS were non-water suppressed. Real-time frequency stabilization/adjustment was switched off when appropriate. Sixty scanners repeated the protocol for a second dataset. In addition, a three-hour post-fMRI MRS acquisition was performed at one site to observe change of gradient temperature and drift rate. Spectral analysis was performed using MATLAB. Frequency drift in pre-fMRI PRESS data were compared with the first 5:20 minutes and the full 30:00 minutes of data after fMRI. Median (interquartile range) drifts were measured and showed in violin plot. Paired t-tests were performed to compare frequency drift pre- and post-fMRI. A simulated in vivo spectrum was generated using FID-A to visualize the effect of the observed frequency drifts. The simulated spectrum was convolved with the frequency trace for the most extreme cases. Impacts of frequency drifts on NAA and GABA were also simulated as a function of linear drift. Data from the repeated protocol were compared with the corresponding first dataset using Pearson's and intraclass correlation coefficients (ICC). Results: Of the data collected from 99 scanners, 4 were excluded due to various reasons. Thus, data from 95 scanners were ultimately analyzed. For the first 5:20 min (64 transients), median (interquartile range) drift was 0.44 (1.29) Hz before fMRI and 0.83 (1.29) Hz after. This increased to 3.15 (4.02) Hz for the full 30 min (360 transients) run. Average drift rates were 0.29 Hz/min before fMRI and 0.43 Hz/min after. Paired t-tests indicated that drift increased after fMRI, as expected (p < 0.05). Simulated spectra convolved with the frequency drift showed that the intensity of the NAA singlet was reduced by up to 26%, 44 % and 18% for GE, Philips and Siemens scanners after fMRI, respectively. ICCs indicated good agreement between datasets acquired on separate days. The single site long acquisition showed drift rate was reduced to 0.03 Hz/min approximately three hours after fMRI. Discussion: This study analyzed frequency drift data from 95 3T MRI scanners. Median levels of drift were relatively low (5-min average under 1 Hz), but the most extreme cases suffered from higher levels of drift. The extent of drift varied across scanners which both linear and nonlinear drifts were observed.

Citation

Hui, S. C., Mikkelsen, M., Zöllner, H. J., Ahluwalia, V., Alcauter, S., Baltusis, L., Barany, D. A., Barlow, L. R., Becker, R., Berman, J. I., Berrington, A., Bhattacharyya, P. K., Blicher, J. U., Bogner, W., Brown, M. S., Calhoun, V. D., Castillo, R., Cecil, K. M., Choi, Y. B., Chu, W. C., …Edden, R. A. (2021). Frequency drift in MR spectroscopy at 3T. NeuroImage, 241, Article 118430. https://doi.org/10.1016/j.neuroimage.2021.118430

Journal Article Type Article
Acceptance Date Jul 22, 2021
Online Publication Date Jul 24, 2021
Publication Date 2021-11
Deposit Date Mar 28, 2025
Publicly Available Date Apr 2, 2025
Journal NeuroImage
Print ISSN 1053-8119
Electronic ISSN 1095-9572
Publisher Elsevier
Peer Reviewed Peer Reviewed
Volume 241
Article Number 118430
DOI https://doi.org/10.1016/j.neuroimage.2021.118430
Public URL https://nottingham-repository.worktribe.com/output/47005782
Publisher URL https://www.sciencedirect.com/science/article/pii/S1053811921007059?via%3Dihub

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