nnResting state fMRI scanner instabilities revealed by longitud inal phantom scans in a multi-center study

Authors

Aras Kayvanrad, University of Toronto
Stephen R. Arnott, University of Toronto
Nathan Churchill, Saint Michael's Hospital University of Toronto
Stefanie Hassel, University of Calgary
Aditi Chemparathy, University of Toronto
Fan Dong, Indoc Research
Mojdeh Zamyadi, University of Toronto
Tom Gee, Indoc Research
Robert Bartha, Robarts Research InstituteFollow
Sandra E. Black, Sunnybrook Health Sciences Centre
Jane M. Lawrence-Dewar, Thunder Bay Regional Health Research Institute
Christopher J.M. Scott, Sunnybrook Health Sciences Centre
Sean Symons, Sunnybrook Health Sciences Centre
Andrew D. Davis, University of Toronto
Geoffrey B. Hall, McMaster University
Jacqueline Harris, University of Alberta
Nancy J. Lobaugh, Centre for Addiction and Mental Health
Glenda MacQueen, University of Calgary
Cindy Woo, University of British Columbia, Faculty of Medicine
Stephen Strother, University of Toronto

Document Type

Article

Publication Date

8-15-2021

Journal

NeuroImage

Volume

237

URL with Digital Object Identifier

10.1016/j.neuroimage.2021.118197

Abstract

Quality assurance (QA) is crucial in longitudinal and/or multi-site studies, which involve the collection of data from a group of subjects over time and/or at different locations. It is important to regularly monitor the performance of the scanners over time and at different locations to detect and control for intrinsic differences (e.g., due to manufacturers) and changes in scanner performance (e.g., due to gradual component aging, software and/or hardware upgrades, etc.). As part of the Ontario Neurodegenerative Disease Research Initiative (ONDRI) and the Canadian Biomarker Integration Network in Depression (CAN-BIND), QA phantom scans were conducted approximately monthly for three to four years at 13 sites across Canada with 3T research MRI scanners. QA parameters were calculated for each scan using the functional Biomarker Imaging Research Network's (fBIRN) QA phantom and pipeline to capture between- and within-scanner variability. We also describe a QA protocol to measure the full-width-at-half-maximum (FWHM) of slice-wise point spread functions (PSF), used in conjunction with the fBIRN QA parameters. Variations in image resolution measured by the FWHM are a primary source of variance over time for many sites, as well as between sites and between manufacturers. We also identify an unexpected range of instabilities affecting individual slices in a number of scanners, which may amount to a substantial contribution of unexplained signal variance to their data. Finally, we identify a preliminary preprocessing approach to reduce this variance and/or alleviate the slice anomalies, and in a small human data set show that this change in preprocessing can have a significant impact on seed-based connectivity measurements for some individual subjects. We expect that other fMRI centres will find this approach to identifying and controlling scanner instabilities useful in similar studies.

Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 License.

Citation of this paper:

Aras Kayvanrad, Stephen R. Arnott, Nathan Churchill, Stefanie Hassel, Aditi Chemparathy, Fan Dong, Mojdeh Zamyadi, Tom Gee, Robert Bartha, Sandra E. Black, Jane M. Lawrence-Dewar, Christopher J.M. Scott, Sean Symons, Andrew D. Davis, Geoffrey B. Hall, Jacqueline Harris, Nancy J. Lobaugh, Glenda MacQueen, Cindy Woo, Stephen Strother, Resting state fMRI scanner instabilities revealed by longitudinal phantom scans in a multi-center study, NeuroImage, Volume 237, 2021, 118197, ISSN 1053-8119, https://doi.org/10.1016/j.neuroimage.2021.118197. (https://www.sciencedirect.com/science/article/pii/S1053811921004742)