Literature DB >> 20456889

Quantitative analysis of arterial spin labeling FMRI data using a general linear model.

Luis Hernandez-Garcia1, Hesamoddin Jahanian, Daniel B Rowe.   

Abstract

Arterial spin labeling techniques can yield quantitative measures of perfusion by fitting a kinetic model to difference images (tagged-control). Because of the noisy nature of the difference images investigators typically average a large number of tagged versus control difference measurements over long periods of time. This averaging requires that the perfusion signal be at a steady state and not at the transitions between active and baseline states in order to quantitatively estimate activation induced perfusion. This can be an impediment for functional magnetic resonance imaging task experiments. In this work, we introduce a general linear model (GLM) that specifies Blood Oxygenation Level Dependent (BOLD) effects and arterial spin labeling modulation effects and translate them into meaningful, quantitative measures of perfusion by using standard tracer kinetic models. We show that there is a strong association between the perfusion values using our GLM method and the traditional subtraction method, but that our GLM method is more robust to noise.

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Year:  2010        PMID: 20456889      PMCID: PMC2918707          DOI: 10.1016/j.mri.2010.03.035

Source DB:  PubMed          Journal:  Magn Reson Imaging        ISSN: 0730-725X            Impact factor:   2.546


  21 in total

1.  Nonlinear temporal dynamics of the cerebral blood flow response.

Authors:  K L Miller; W M Luh; T T Liu; A Martinez; T Obata; E C Wong; L R Frank; R B Buxton
Journal:  Hum Brain Mapp       Date:  2001-05       Impact factor: 5.038

2.  Analysis and design of perfusion-based event-related fMRI experiments.

Authors:  Thomas T Liu; Eric C Wong; Lawrence R Frank; Richard B Buxton
Journal:  Neuroimage       Date:  2002-05       Impact factor: 6.556

3.  Comparison of quantitative perfusion imaging using arterial spin labeling at 1.5 and 4.0 Tesla.

Authors:  Jiongjiong Wang; David C Alsop; Lin Li; John Listerud; Julio B Gonzalez-At; Mitchell D Schnall; John A Detre
Journal:  Magn Reson Med       Date:  2002-08       Impact factor: 4.668

4.  Determining the longitudinal relaxation time (T1) of blood at 3.0 Tesla.

Authors:  Hanzhang Lu; Chekesha Clingman; Xavier Golay; Peter C M van Zijl
Journal:  Magn Reson Med       Date:  2004-09       Impact factor: 4.668

5.  Fast, pseudo-continuous arterial spin labeling for functional imaging using a two-coil system.

Authors:  Luis Hernandez-Garcia; Gregory R Lee; Alberto L Vazquez; Douglas C Noll
Journal:  Magn Reson Med       Date:  2004-03       Impact factor: 4.668

6.  A signal processing model for arterial spin labeling functional MRI.

Authors:  Thomas T Liu; Eric C Wong
Journal:  Neuroimage       Date:  2005-01-01       Impact factor: 6.556

7.  T1, T2 relaxation and magnetization transfer in tissue at 3T.

Authors:  Greg J Stanisz; Ewa E Odrobina; Joseph Pun; Michael Escaravage; Simon J Graham; Michael J Bronskill; R Mark Henkelman
Journal:  Magn Reson Med       Date:  2005-09       Impact factor: 4.668

8.  Magnetic resonance imaging of perfusion using spin inversion of arterial water.

Authors:  D S Williams; J A Detre; J S Leigh; A P Koretsky
Journal:  Proc Natl Acad Sci U S A       Date:  1992-01-01       Impact factor: 11.205

Review 9.  Arterial spin-labeled perfusion MRI in basic and clinical neuroscience.

Authors:  John A Detre; Jiongjiong Wang; Ze Wang; Hengyi Rao
Journal:  Curr Opin Neurol       Date:  2009-08       Impact factor: 5.710

10.  Reduced transit-time sensitivity in noninvasive magnetic resonance imaging of human cerebral blood flow.

Authors:  D C Alsop; J A Detre
Journal:  J Cereb Blood Flow Metab       Date:  1996-11       Impact factor: 6.200
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  7 in total

1.  Support vector machine learning-based cerebral blood flow quantification for arterial spin labeling MRI.

Authors:  Ze Wang
Journal:  Hum Brain Mapp       Date:  2014-01-17       Impact factor: 5.038

2.  ASL-MRICloud: An online tool for the processing of ASL MRI data.

Authors:  Yang Li; Peiying Liu; Yue Li; Hongli Fan; Pan Su; Shin-Lei Peng; Denise C Park; Karen M Rodrigue; Hangyi Jiang; Andreia V Faria; Can Ceritoglu; Michael Miller; Susumu Mori; Hanzhang Lu
Journal:  NMR Biomed       Date:  2018-12-26       Impact factor: 4.044

3.  Improving cerebral blood flow quantification for arterial spin labeled perfusion MRI by removing residual motion artifacts and global signal fluctuations.

Authors:  Ze Wang
Journal:  Magn Reson Imaging       Date:  2012-07-11       Impact factor: 2.546

4.  Cerebral volumetric changes induced by prolonged hypoxic exposure and whole-body exercise.

Authors:  Thomas Rupp; Marc Jubeau; Laurent Lamalle; Jan M Warnking; Guillaume Y Millet; Bernard Wuyam; François Esteve; Patrick Levy; Alexandre Krainik; Samuel Verges
Journal:  J Cereb Blood Flow Metab       Date:  2014-08-27       Impact factor: 6.200

5.  Neural effects of short-term training on working memory.

Authors:  Martin Buschkuehl; Luis Hernandez-Garcia; Susanne M Jaeggi; Jessica A Bernard; John Jonides
Journal:  Cogn Affect Behav Neurosci       Date:  2014-03       Impact factor: 3.282

6.  Tonotopic maps in human auditory cortex using arterial spin labeling.

Authors:  Anna Gardumi; Dimo Ivanov; Martin Havlicek; Elia Formisano; Kâmil Uludağ
Journal:  Hum Brain Mapp       Date:  2016-10-28       Impact factor: 5.038

7.  Cardiorespiratory fitness mediates the effects of aging on cerebral blood flow.

Authors:  Benjamin Zimmerman; Bradley P Sutton; Kathy A Low; Mark A Fletcher; Chin Hong Tan; Nils Schneider-Garces; Yanfen Li; Cheng Ouyang; Edward L Maclin; Gabriele Gratton; Monica Fabiani
Journal:  Front Aging Neurosci       Date:  2014-04-07       Impact factor: 5.750
  7 in total

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