A novel method for quantifying scanner instability in fMRI

Douglas N. Greve; Bryon A. Mueller; Thomas Liu; Jessica A. Turner; James Voyvodic; Elizabeth Yetter; Michele Diaz; Gregory McCarthy; Stuart Wallace; Brian J. Roach; Judy M. Ford; Daniel H. Mathalon; Vince D. Calhoun; Cynthia G. Wible; Gregory G. Brown; Steven G. Potkin; Gary Glover

doi:10.1002/mrm.22691

A novel method for quantifying scanner instability in fMRI

Douglas N. Greve
, Bryon A. Mueller
, Thomas Liu
, Jessica A. Turner
, James Voyvodic
, Elizabeth Yetter
, Michele Diaz
, Gregory McCarthy
, Stuart Wallace
, Brian J. Roach
, Judy M. Ford
, Daniel H. Mathalon
, Vince D. Calhoun
, Cynthia G. Wible
, Gregory G. Brown
, Steven G. Potkin
, Gary Glover

Research output: Contribution to journal › Article › peer-review

46 Scopus citations

Abstract

A method was developed to quantify the effect of scanner instability on functional MRI data by comparing the instability noise to endogenous noise present when scanning a human. The instability noise was computed from agar phantom data collected with two flip angles, allowing for a separation of the instability from the background noise. This method was used on human data collected at four 3 T scanners, allowing the physiological noise level to be extracted from the data. In a "well-operating" scanner, the instability noise is generally less than 10% of physiological noise in white matter and only about 2% of physiological noise in cortex. This indicates that instability in a well-operating scanner adds very little noise to functional MRI results. This new method allows researchers to make informed decisions about the maximum instability level a scanner can have before it is taken off line for maintenance or rejected from a multisite consortium. This method also provides information about the background noise, which is generally larger in magnitude than the instability noise.

Original language	English (US)
Pages (from-to)	1053-1061
Number of pages	9
Journal	Magnetic Resonance in Medicine
Volume	65
Issue number	4
DOIs	https://doi.org/10.1002/mrm.22691
State	Published - Apr 2011

All Science Journal Classification (ASJC) codes

Radiology Nuclear Medicine and imaging

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10.1002/mrm.22691

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Greve, D. N., Mueller, B. A., Liu, T., Turner, J. A., Voyvodic, J., Yetter, E., Diaz, M., McCarthy, G., Wallace, S., Roach, B. J., Ford, J. M., Mathalon, D. H., Calhoun, V. D., Wible, C. G., Brown, G. G., Potkin, S. G., & Glover, G. (2011). A novel method for quantifying scanner instability in fMRI. Magnetic Resonance in Medicine, 65(4), 1053-1061. https://doi.org/10.1002/mrm.22691

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title = "A novel method for quantifying scanner instability in fMRI",

abstract = "A method was developed to quantify the effect of scanner instability on functional MRI data by comparing the instability noise to endogenous noise present when scanning a human. The instability noise was computed from agar phantom data collected with two flip angles, allowing for a separation of the instability from the background noise. This method was used on human data collected at four 3 T scanners, allowing the physiological noise level to be extracted from the data. In a {"}well-operating{"} scanner, the instability noise is generally less than 10\% of physiological noise in white matter and only about 2\% of physiological noise in cortex. This indicates that instability in a well-operating scanner adds very little noise to functional MRI results. This new method allows researchers to make informed decisions about the maximum instability level a scanner can have before it is taken off line for maintenance or rejected from a multisite consortium. This method also provides information about the background noise, which is generally larger in magnitude than the instability noise.",

author = "Greve, \{Douglas N.\} and Mueller, \{Bryon A.\} and Thomas Liu and Turner, \{Jessica A.\} and James Voyvodic and Elizabeth Yetter and Michele Diaz and Gregory McCarthy and Stuart Wallace and Roach, \{Brian J.\} and Ford, \{Judy M.\} and Mathalon, \{Daniel H.\} and Calhoun, \{Vince D.\} and Wible, \{Cynthia G.\} and Brown, \{Gregory G.\} and Potkin, \{Steven G.\} and Gary Glover",

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AU - Yetter, Elizabeth

AU - Diaz, Michele

AU - McCarthy, Gregory

AU - Wallace, Stuart

AU - Roach, Brian J.

AU - Ford, Judy M.

AU - Mathalon, Daniel H.

AU - Calhoun, Vince D.

AU - Wible, Cynthia G.

AU - Brown, Gregory G.

AU - Potkin, Steven G.

AU - Glover, Gary

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A novel method for quantifying scanner instability in fMRI

Abstract

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