Neurophysiology of the BOLD fMRI Signal in Awake Monkeys

Goense, Jozien; Logothetis, Nikos K.

doi:10.1016/j.cub.2008.03.054

Cited by 523 publications

(466 citation statements)

References 54 publications

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“…Neuroimaging of spontaneous infraslow activity has been the focus of tremendous research interest, but has typically relied upon imaging modalities that indirectly reflect neuronal activity [45][46][47][48] and have thus raised questions about the underlying nature and interpretation of these data 22,36 . Innovative efforts to directly assess the neurophysiological basis of fMRI BOLD signal fluctuations have revealed much about the best electrophysiological correlates of these signals, but these approaches require specialized recording equipment and technical analysis to remove electrical artifacts and are limited in their spatial coverage.…”

Section: Discussionmentioning

confidence: 99%

Mesoscale infraslow spontaneous membrane potential fluctuations recapitulate high-frequency activity cortical motifs

et al. 2015

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Neuroimaging of spontaneous, resting-state infraslow (o0.1 Hz) brain activity has been used to reveal the regional functional organization of the brain and may lead to the identification of novel biomarkers of neurological disease. However, these imaging studies generally rely on indirect measures of neuronal activity and the nature of the neuronal activity correlate remains unclear. Here we show, using wide-field, voltage-sensitive dye imaging, the mesoscale spatiotemporal structure and pharmacological dependence of spontaneous, infraslow cortical activity in anaesthetized and awake mice. Spontaneous infraslow activity is regionally distinct, correlates with electroencephalography and local field potential recordings, and shows bilateral symmetry between cortical hemispheres. Infraslow activity is attenuated and its functional structure abolished after treatment with voltage-gated sodium channel and glutamate receptor antagonists. Correlation analysis reveals patterns of infraslow regional connectivity that are analogous to cortical motifs observed from higher-frequency spontaneous activity and reflect the underlying framework of intracortical axonal projections.

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Section: Discussionmentioning

confidence: 99%

Mesoscale infraslow spontaneous membrane potential fluctuations recapitulate high-frequency activity cortical motifs

et al. 2015

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“…An additional hypothetical mechanism can be associated with the different amplitude of fMRI response in human and monkey experiments. BOLD fMRI responses and neural activity is smaller during anesthesia then in the alert condition (Goense and Logothetis, 2008;Martin et al, 2006). Dependent on the extent of the stimulus (e.g.…”

Section: Hypothetical Mechanism Underlying Negative Bold Contrastmentioning

confidence: 96%

Investigation of the neurovascular coupling in positive and negative BOLD responses in human brain at 7T

et al. 2014

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“…This calculation is in general agreement with experiments based upon simultaneous recording of electrophysiology and BOLD. Combined electrophysiology and fMRI is relatively popular to explore the coupling between the neuronal activity and haemodynamic response, although most literature is limited to the study of experimental animals (Logothetis et al, 2001, Shmuel et al, 2006, Goense and Logothetis, 2008, Goloshevsky et al, 2008. Multiple studies have demonstrated that the BOLD response is more closely coupled to LFP rather than MUA (Logothetis et al, 2001, Niessing et al, 2005, Shmuel et al, 2006, Goense and Logothetis, 2008.…”

Section: Boldmentioning

confidence: 99%

The relationship between MEG and fMRI

et al. 2014

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In recent years functional neuroimaging techniques such as fMRI, MEG, EEG and PET have provided researchers with a wealth of information on human brain function. However none of these modalities can measure directly either the neuro-electrical or neuro-chemical processes that mediate brain function. This means that metrics directly reflecting brain 'activity' must be inferred from other metrics (e.g. magnetic fields (MEG) or haemodynamics (fMRI)). To overcome this limitation, many studies seek to combine multiple complementary modalities and an excellent example of this is the combination of MEG (which has high temporal resolution) with fMRI (which has high spatial resolution). However, the full potential of multi-modal approaches can only be truly realised in cases where the relationship between metrics is known. In this paper, we explore the relationship between measurements made using fMRI and MEG. We describe the origins of the two signals as well as their relationship to electrophysiology. We review multiple studies that have attempted to characterise the spatial relationship between fMRI and MEG, and we also describe studies that exploit the rich information content of MEG to explore differing relationships between MEG and fMRI across neural oscillatory frequency bands. Monitoring the brain at "rest" has become of significant recent interest to the neuroimaging community and we review recent evidence comparing MEG and fMRI metrics of functional connectivity. A brief discussion of the use of magnetic resonance spectroscopy (MRS) to probe the relationship between MEG/fMRI and neurochemistry is also given. Finally, we highlight future areas of interest and offer some recommendations for the parallel use of fMRI and MEG.

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Neurophysiology of the BOLD fMRI Signal in Awake Monkeys

Cited by 523 publications

References 54 publications

Mesoscale infraslow spontaneous membrane potential fluctuations recapitulate high-frequency activity cortical motifs

Mesoscale infraslow spontaneous membrane potential fluctuations recapitulate high-frequency activity cortical motifs

Investigation of the neurovascular coupling in positive and negative BOLD responses in human brain at 7T

The relationship between MEG and fMRI

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