Quantification of Task-Specific Glucose Metabolism with Constant Infusion of<sup>18</sup>F-FDG

Hahn, Andreas; Gryglewski, Gregor; Nics, Lukas; Hienert, Marius; Rischka, Lucas; Vraka, Chrysoula; Sigurdardottir, Helen; Vanicek, Thomas; James, G.M.; Seiger, René; Kautzky, Alexander; Silberbauer, Leo; Wadsak, Wolfgang; Mitterhauser, Markus; Hacker, Marcus; Kasper, Siegfried; Lanzenberger, Rupert

doi:10.2967/jnumed.116.176156

Cited by 73 publications

(104 citation statements)

References 39 publications

(68 reference statements)

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“…Given that the BOLD-fMRI signal indexes recent neural activity with a temporal resolution of 0.5-3 s, there is a significant temporal confound when comparing simultaneously acquired FDG-PET and BOLD-fMRI activation maps. Comparable results were recently obtained by (Hahn et al, 2016) in the motor cortex. One procedure is to dynamically track FDG uptake by slowly infusing FDG over the course of the scan.…”

Section: Simultaneous Bold-fmri/fdg-pet Imagingsupporting

confidence: 83%

“…In a proof-of-concept study, Villien et al (2014) demonstrated that a slow continuous infusion technique yields sufficient FDG-PET signal in the occipital cortex during a checkerboard stimulation to be able to identify activation in the primary visual cortex. Comparable results were recently obtained by (Hahn et al, 2016) in the motor cortex.…”

Section: Simultaneous Bold-fmri/fdg-pet Imagingsupporting

confidence: 83%

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From simultaneous to synergistic MR‐PET brain imaging: A review of hybrid MR‐PET imaging methodologies

Chen

Jamadar

et al. 2018

Human Brain Mapping

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Simultaneous Magnetic Resonance Imaging (MRI) and Positron Emission Tomography (PET) scanning is a recent major development in biomedical imaging. The full integration of the PET detector ring and electronics within the MR system has been a technologically challenging design to develop but provides capacity for simultaneous imaging and the potential for new diagnostic and research capability. This article reviews state-of-the-art MR-PET hardware and software, and discusses future developments focusing on neuroimaging methodologies for MR-PET scanning. We particularly focus on the methodologies that lead to an improved synergy between MRI and PET, including optimal data acquisition, PET attenuation and motion correction, and joint image reconstruction and processing methods based on the underlying complementary and mutual information. We further review the current and potential future applications of simultaneous MR-PET in both systems neuroscience and clinical neuroimaging research. We demonstrate a simultaneous data acquisition protocol to highlight new applications of MR-PET neuroimaging research studies.

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Section: Simultaneous Bold-fmri/fdg-pet Imagingsupporting

confidence: 83%

Section: Simultaneous Bold-fmri/fdg-pet Imagingsupporting

confidence: 83%

From simultaneous to synergistic MR‐PET brain imaging: A review of hybrid MR‐PET imaging methodologies

Chen

Jamadar

et al. 2018

Human Brain Mapping

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“…Using GLM, the FDG time activity signal can be modelled as a linear combination of a baseline metabolic signal and a task induced activation signal. The baseline represents a glucose measure that is independent of any task stimulation, and the activation signal is defined as the task induced FDG activity changes (Hahn et al 2016;Villien et al 2014 , which includes head motion, physiological noise and other noise terms. These design matrices incorporate a priori knowledge to parameterize the linear model.…”

Section: Glm Of Fpet Datasetsmentioning

confidence: 99%

“…The aim of the fPET approach is to maintain a continuous plasma supply of FDG to provide improved sensitivity of brain-state changes, and better temporal dynamics than bolus PET to track dynamic change of glucose uptake over time. Several studies have demonstrated that fPET can isolate task related changes in glucose uptake (Hahn et al 2016;Hahn et al 2018;Rischka et al 2018;Villien et al 2014;Jamadar, Ward, Carey, et al 2019).…”

Section: Introductionmentioning

confidence: 99%

“…The estimated parameters are then submitted to parametric statistical tests to generate brain activation maps (Friston 2007). The GLM model-based approach has been widely used in the analysis of functional MRI (fMRI), EEG and recently in fPET (Hahn et al 2016;Villien et al 2014;Jamadar, Ward, Carey, et al 2019). In the fPET GLM analysis, the time activity signal is represented by the combination of the task regressors, baseline regressor, and other nuisance regressors accounting for motion and physiological noises (Hahn et al 2016;Villien et al 2014).…”

Section: Introductionmentioning

confidence: 99%

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Analysis of continuous infusion functional PET (fPET) in the human brain

Jamadar

Ward

et al. 2019

Preprint

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Functional positron emission tomography (fPET) is a neuroimaging method involving continuous infusion of 18-F-fluorodeoxyglucose (FDG) radiotracer during the course of the PET examination. Compared with the conventional bolus administered static FDG PET which provides only a snapshot of the averaged glucose uptake into the brain in a limited dynamic time window, fPET offers a significantly wider time window to study the dynamics of glucose uptake. Several earlier studies have applied fPET to investigate brain FDG uptake and study its relationship with functional magnetic resonance imaging (fMRI). However, due to the unique characteristics of fPET signals, modelling of the fPET signal is a complex task and poses challenges for accurate interpretation of the results. This study applies independent component analysis (ICA) to analyze resting state fPET data, and to compare the performance of ICA and general linear modelling (GLM) for estimation of brain activation in response to tasks. The fPET signal characteristics were compared using GLM and ICA methods to model the fPET visual activation data. Our aim was to evaluate GLM and ICA methods for analyzing task fPET datasets and present ICA method in the analysis of resting state fPET datasets. Using both simulation and in-vivo experimental datasets, we show that both methods can successfully identify task related brain activation. We report fPET metabolic resting state brain networks analyzed using the fPET ICA method in a cohort of healthy subjects. Functional PET provides a unique method to map dynamic changes of glucose uptake in the resting human brain and in response to extrinsic stimulation.

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MR‐PET head motion correction based on co‐registration of multicontrast MR images

Chen

Sforazzini

Baran

et al. 2019

Human Brain Mapping

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Quantification of Task-Specific Glucose Metabolism with Constant Infusion of¹⁸F-FDG

Cited by 73 publications

References 39 publications

From simultaneous to synergistic MR‐PET brain imaging: A review of hybrid MR‐PET imaging methodologies

From simultaneous to synergistic MR‐PET brain imaging: A review of hybrid MR‐PET imaging methodologies

Analysis of continuous infusion functional PET (fPET) in the human brain

MR‐PET head motion correction based on co‐registration of multicontrast MR images

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Quantification of Task-Specific Glucose Metabolism with Constant Infusion of18F-FDG

Cited by 73 publications

References 39 publications

From simultaneous to synergistic MR‐PET brain imaging: A review of hybrid MR‐PET imaging methodologies

From simultaneous to synergistic MR‐PET brain imaging: A review of hybrid MR‐PET imaging methodologies

Analysis of continuous infusion functional PET (fPET) in the human brain

MR‐PET head motion correction based on co‐registration of multicontrast MR images

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Product

Resources

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Quantification of Task-Specific Glucose Metabolism with Constant Infusion of¹⁸F-FDG