A Frequency-Domain Machine Learning Method for Dual-Calibrated fMRI Mapping of Oxygen Extraction Fraction (OEF) and Cerebral Metabolic Rate of Oxygen Consumption (CMRO2)

A Frequency-Domain Machine Learning Method for Dual-Calibrated fMRI Mapping of Oxygen Extraction Fraction (OEF) and Cerebral Metabolic Rate of Oxygen Consumption (CMRO2)

Magnetic resonance imaging (MRI) offers the possibility to non-invasively map the brain's metabolic oxygen consumption (CMRO2), which is essential for understanding and monitoring neural function in both health and disease. However, in depth study of oxygen metabolism with MRI has so far been h...

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Main Authors: Michael Germuska, Hannah Louise Chandler, Thomas Okell, Fabrizio Fasano, Valentina Tomassini, Kevin Murphy, Richard G. Wise
Format: Article
Language:English
Published: Frontiers Media S.A. 2020-03-01
Series:Frontiers in Artificial Intelligence
Subjects:
calibrated-fMRI
oxygen extraction fraction
CMRO2
OEF
machine learning
Online Access:https://www.frontiersin.org/article/10.3389/frai.2020.00012/full
id doaj-b837f760be23499d88cbc504fb8a6dac
record_format Article
collection DOAJ
language English
format Article
sources DOAJ
author Michael Germuska
Hannah Louise Chandler
Thomas Okell
Fabrizio Fasano
Valentina Tomassini
Valentina Tomassini
Valentina Tomassini
Kevin Murphy
Richard G. Wise
Richard G. Wise
Richard G. Wise
spellingShingle Michael Germuska
Hannah Louise Chandler
Thomas Okell
Fabrizio Fasano
Valentina Tomassini
Valentina Tomassini
Valentina Tomassini
Kevin Murphy
Richard G. Wise
Richard G. Wise
Richard G. Wise
A Frequency-Domain Machine Learning Method for Dual-Calibrated fMRI Mapping of Oxygen Extraction Fraction (OEF) and Cerebral Metabolic Rate of Oxygen Consumption (CMRO2)
Frontiers in Artificial Intelligence
calibrated-fMRI
oxygen extraction fraction
CMRO2
OEF
machine learning
author_facet Michael Germuska
Hannah Louise Chandler
Thomas Okell
Fabrizio Fasano
Valentina Tomassini
Valentina Tomassini
Valentina Tomassini
Kevin Murphy
Richard G. Wise
Richard G. Wise
Richard G. Wise
author_sort Michael Germuska
title A Frequency-Domain Machine Learning Method for Dual-Calibrated fMRI Mapping of Oxygen Extraction Fraction (OEF) and Cerebral Metabolic Rate of Oxygen Consumption (CMRO2)
title_short A Frequency-Domain Machine Learning Method for Dual-Calibrated fMRI Mapping of Oxygen Extraction Fraction (OEF) and Cerebral Metabolic Rate of Oxygen Consumption (CMRO2)
title_full A Frequency-Domain Machine Learning Method for Dual-Calibrated fMRI Mapping of Oxygen Extraction Fraction (OEF) and Cerebral Metabolic Rate of Oxygen Consumption (CMRO2)
title_fullStr A Frequency-Domain Machine Learning Method for Dual-Calibrated fMRI Mapping of Oxygen Extraction Fraction (OEF) and Cerebral Metabolic Rate of Oxygen Consumption (CMRO2)
title_full_unstemmed A Frequency-Domain Machine Learning Method for Dual-Calibrated fMRI Mapping of Oxygen Extraction Fraction (OEF) and Cerebral Metabolic Rate of Oxygen Consumption (CMRO2)
title_sort frequency-domain machine learning method for dual-calibrated fmri mapping of oxygen extraction fraction (oef) and cerebral metabolic rate of oxygen consumption (cmro2)
publisher Frontiers Media S.A.
series Frontiers in Artificial Intelligence
issn 2624-8212
publishDate 2020-03-01
description Magnetic resonance imaging (MRI) offers the possibility to non-invasively map the brain's metabolic oxygen consumption (CMRO2), which is essential for understanding and monitoring neural function in both health and disease. However, in depth study of oxygen metabolism with MRI has so far been hindered by the lack of robust methods. One MRI method of mapping CMRO2 is based on the simultaneous acquisition of cerebral blood flow (CBF) and blood oxygen level dependent (BOLD) weighted images during respiratory modulation of both oxygen and carbon dioxide. Although this dual-calibrated methodology has shown promise in the research setting, current analysis methods are unstable in the presence of noise and/or are computationally demanding. In this paper, we present a machine learning implementation for the multi-parametric assessment of dual-calibrated fMRI data. The proposed method aims to address the issues of stability, accuracy, and computational overhead, removing significant barriers to the investigation of oxygen metabolism with MRI. The method utilizes a time-frequency transformation of the acquired perfusion and BOLD-weighted data, from which appropriate feature vectors are selected for training of machine learning regressors. The implemented machine learning methods are chosen for their robustness to noise and their ability to map complex non-linear relationships (such as those that exist between BOLD signal weighting and blood oxygenation). An extremely randomized trees (ET) regressor is used to estimate resting blood flow and a multi-layer perceptron (MLP) is used to estimate CMRO2 and the oxygen extraction fraction (OEF). Synthetic data with additive noise are used to train the regressors, with data simulated to cover a wide range of physiologically plausible parameters. The performance of the implemented analysis method is compared to published methods both in simulation and with in-vivo data (n = 30). The proposed method is demonstrated to significantly reduce computation time, error, and proportional bias in both CMRO2 and OEF estimates. The introduction of the proposed analysis pipeline has the potential to not only increase the detectability of metabolic difference between groups of subjects, but may also allow for single subject examinations within a clinical context.
topic calibrated-fMRI
oxygen extraction fraction
CMRO2
OEF
machine learning
url https://www.frontiersin.org/article/10.3389/frai.2020.00012/full
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spelling doaj-b837f760be23499d88cbc504fb8a6dac2020-11-25T02:25:37ZengFrontiers Media S.A.Frontiers in Artificial Intelligence2624-82122020-03-01310.3389/frai.2020.00012475718A Frequency-Domain Machine Learning Method for Dual-Calibrated fMRI Mapping of Oxygen Extraction Fraction (OEF) and Cerebral Metabolic Rate of Oxygen Consumption (CMRO2)Michael Germuska0Hannah Louise Chandler1Thomas Okell2Fabrizio Fasano3Valentina Tomassini4Valentina Tomassini5Valentina Tomassini6Kevin Murphy7Richard G. Wise8Richard G. Wise9Richard G. Wise10Cardiff University Brain Research Imaging Centre (CUBRIC), Department of Psychology, Cardiff University, Cardiff, United KingdomCardiff University Brain Research Imaging Centre (CUBRIC), Department of Psychology, Cardiff University, Cardiff, United KingdomFMRIB, Nuffield Department of Clinical Neurosciences, Wellcome Centre for Integrative Neuroimaging, University of Oxford, Oxford, United KingdomSiemens Healthcare Ltd., Camberley, United KingdomCardiff University Brain Research Imaging Centre (CUBRIC), Department of Psychology, Cardiff University, Cardiff, United KingdomDivision of Psychological Medicine and Clinical Neurosciences, Cardiff University School of Medicine, Cardiff, United KingdomDepartment of Neuroscience, Imaging and Clinical Sciences, “G. D'Annunzio University” of Chieti-Pescara, Chieti, ItalyCardiff University Brain Research Imaging Centre (CUBRIC), Department of Psychology, Cardiff University, Cardiff, United KingdomCardiff University Brain Research Imaging Centre (CUBRIC), Department of Psychology, Cardiff University, Cardiff, United KingdomDepartment of Neuroscience, Imaging and Clinical Sciences, “G. D'Annunzio University” of Chieti-Pescara, Chieti, ItalyInstitute for Advanced Biomedical Technologies, “G. D'Annunzio University” of Chieti-Pescara, Chieti, ItalyMagnetic resonance imaging (MRI) offers the possibility to non-invasively map the brain's metabolic oxygen consumption (CMRO2), which is essential for understanding and monitoring neural function in both health and disease. However, in depth study of oxygen metabolism with MRI has so far been hindered by the lack of robust methods. One MRI method of mapping CMRO2 is based on the simultaneous acquisition of cerebral blood flow (CBF) and blood oxygen level dependent (BOLD) weighted images during respiratory modulation of both oxygen and carbon dioxide. Although this dual-calibrated methodology has shown promise in the research setting, current analysis methods are unstable in the presence of noise and/or are computationally demanding. In this paper, we present a machine learning implementation for the multi-parametric assessment of dual-calibrated fMRI data. The proposed method aims to address the issues of stability, accuracy, and computational overhead, removing significant barriers to the investigation of oxygen metabolism with MRI. The method utilizes a time-frequency transformation of the acquired perfusion and BOLD-weighted data, from which appropriate feature vectors are selected for training of machine learning regressors. The implemented machine learning methods are chosen for their robustness to noise and their ability to map complex non-linear relationships (such as those that exist between BOLD signal weighting and blood oxygenation). An extremely randomized trees (ET) regressor is used to estimate resting blood flow and a multi-layer perceptron (MLP) is used to estimate CMRO2 and the oxygen extraction fraction (OEF). Synthetic data with additive noise are used to train the regressors, with data simulated to cover a wide range of physiologically plausible parameters. The performance of the implemented analysis method is compared to published methods both in simulation and with in-vivo data (n = 30). The proposed method is demonstrated to significantly reduce computation time, error, and proportional bias in both CMRO2 and OEF estimates. The introduction of the proposed analysis pipeline has the potential to not only increase the detectability of metabolic difference between groups of subjects, but may also allow for single subject examinations within a clinical context.https://www.frontiersin.org/article/10.3389/frai.2020.00012/fullcalibrated-fMRIoxygen extraction fractionCMRO2OEFmachine learning

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