Increased mesiotemporal delta activity characterizes virtual navigation in humans

Clemens, Zsófia; Borbély, Csaba; Weiss, Béla; Erőss, Lóránd; Szücs, Anna; Kelemen, Anna; Fabó, Dániel; Rásonyi, György; Jánszky, J.; Halász, Péter

doi:10.1016/j.neures.2013.03.004

Cited by 17 publications

(22 citation statements)

References 48 publications

(54 reference statements)

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“…This in turn could explain why oscillatory frequency may show an inverse relationship with brain size across species (Robinson, 1980, Herculano-Houzel, 2009). We note, though, that both non-invasive and semi-invasive recording approaches have also identified oscillations in the delta-theta band emanating from the MTL (de Araujo et al, 2002, Cornwell et al, 2008, Cornwell et al, 2012, Kaplan et al, 2012, Clemens et al, 2013). If greater number of phase cancelling sources alone is responsible for the difference in low-frequency oscillations between rats and primates, the presence of oscillations as far away as the scalp seems to weigh against this argument.…”

Section: Why Have Behavior-related Low-frequency Oscillations Been Elmentioning

confidence: 80%

“…Because MEG source localization to areas such as the MTL likely has an accuracy on the order of centimeters (Barnes et al, 2004), these methods cannot unambiguously pinpoint activity to specific sub-areas of the MTL. Human semi-invasive recordings that involve placing electrodes via entrance through the foramen ovale also suggest the presence of low-frequency movement-related oscillations emanating from the MTL during VR navigation (Clemens et al, 2013). A non-human primate study also demonstrated theta oscillations and spike/phase coupling in the MTL (entorhinal cortex) when monkeys looked at objects (Killian et al, 2012), which the authors related to movement-related changes.…”

Section: Hippocampal Low-frequency Oscillations In Primatesmentioning

confidence: 99%

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Multifaceted roles for low-frequency oscillations in bottom-up and top-down processing during navigation and memory

Ekstrom

Watrous

2014

NeuroImage

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A prominent and replicated finding is the correlation between running speed and increases in low-frequency oscillatory activity in the hippocampal local field potential. A more recent finding concerns low-frequency oscillations that increase in coherence between the hippocampus and neocortical brain areas such as prefrontal cortex during memory-related behaviors (i.e., remembering the correct arm to explore). In this review, we tie together movement-related and memory-related low-frequency oscillations in the rodent with similar findings in humans. We argue that although movement-related low-frequency oscillations, in particular, may have slightly different characteristics in humans than rodents, placing important constraints on our thinking about this issue, both phenomena have similar functional foundations. We review four prominent theoretical models that provide partially conflicting accounts of movement-related low-frequency oscillations. We attempt to tie together these theoretical proposals, and existing data in rodents and humans, with memory-related low-frequency oscillations. We propose that movement-related low-frequency oscillations and memory-related low-frequency oscillatory activity, both of which show significant coherence with oscillations in other brain regions, represent different facets of “spectral fingerprints,” or different resonant frequencies within the same brain networks underlying different cognitive processes. Together, movement-related and memory-related low-frequency oscillatory coupling may be linked by their distinct contributions to bottom-up, sensorimotor driven processing and top-down, controlled processing characterizing aspects of memory encoding and retrieval.

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Section: Why Have Behavior-related Low-frequency Oscillations Been Elmentioning

confidence: 80%

Section: Hippocampal Low-frequency Oscillations In Primatesmentioning

confidence: 99%

Multifaceted roles for low-frequency oscillations in bottom-up and top-down processing during navigation and memory

Ekstrom

Watrous

2014

NeuroImage

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“…B 369: 20130304 behaviours (figure 3b). Oscillations at 1-4 Hz most often increased in amplitude during periods of virtual movement compared with stillness ( [54], see also [57]). Follow-up work showed that, such as theta in rodents [30], the amplitude of these 1-4 Hz oscillations positively correlated with the speed of movement [55].…”

Section: Hippocampal Theta Oscillations In Humansmentioning

confidence: 99%

Hippocampal theta oscillations are slower in humans than in rodents: implications for models of spatial navigation and memory

Jacobs

2014

Phil. Trans. R. Soc. B

231

233

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ReviewCite this article: Jacobs J. 2014 Hippocampal theta oscillations are slower in humans than in rodents: implications for models of spatial navigation and memory. The theta oscillation is a neuroscience enigma. When a rat runs through an environment, large-amplitude theta oscillations (4-10 Hz) reliably appear in the hippocampus's electrical activity. The consistency of this pattern led to theta playing a central role in theories on the neural basis of mammalian spatial navigation and memory. However, in fact, hippocampal oscillations at 4-10 Hz are rare in humans and in some other species. This presents a challenge for theories proposing theta as an essential component of the mammalian brain, including models of place and grid cells. Here, I examine this issue by reviewing recent research on human hippocampal oscillations using direct brain recordings from neurosurgical patients. This work indicates that the human hippocampus does indeed exhibit rhythms that are functionally similar to theta oscillations found in rodents, but that these signals have a slower frequency of approximately 1-4 Hz. I argue that oscillatory models of navigation and memory derived from rodent data are relevant for humans, but that they should be modified to account for the slower frequency of the human theta rhythm.

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“…Indeed, growing evidence indicates that slow theta activity (peaking at 3 Hz) in the human hippocampus may be the functional equivalent to the hippocampal theta rhythm of rodents (Jacobs, 2014;Watrous et al, 2013). For example, when previous findings in rats (Vanderwolf, 1969) were replicated in neurosurgical patients with depth recordings in hip pocampus, it was observed that activity in slower frequencies (1 4 Hz) increased with movement in virtual navigation (Clemens et al, 2013;Ekstrom et al, 2005;Watrous et al, 2011). In addition, MEG studies have shown that better navigation performance is related to increased hippocampal activity at slow theta frequencies (Cornwell et al, 2008;Kaplan et al, 2012).…”

Section: Introductionmentioning

confidence: 98%

Slow-theta power decreases during item-place encoding predict spatial accuracy of subsequent context recall

et al. 2016

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a b s t r a c tHuman hippocampal theta oscillations play a key role in accurate spatial coding. Associative encoding involves similar hippocampal networks but, paradoxically, is also characterized by theta power decreases. Here, we inves tigated how theta activity relates to associative encoding of place contexts resulting in accurate navigation. Using MEG, we found that slow theta (2 5 Hz) power negatively correlated with subsequent spatial accuracy for vir tual contextual locations in posterior hippocampus and other cortical structures involved in spatial cognition. A rare opportunity to simultaneously record MEG and intracranial EEG in an epilepsy patient provided crucial in sights: during power decreases, slow theta in right anterior hippocampus and left inferior frontal gyrus phase led the left temporal cortex and predicted spatial accuracy. Our findings indicate that decreased slow theta activ ity reflects local and long range neural mechanisms that encode accurate spatial contexts, and strengthens the view that local suppression of low frequency activity is essential for more efficient processing of detailed information.

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Increased mesiotemporal delta activity characterizes virtual navigation in humans

Cited by 17 publications

References 48 publications

Multifaceted roles for low-frequency oscillations in bottom-up and top-down processing during navigation and memory

Multifaceted roles for low-frequency oscillations in bottom-up and top-down processing during navigation and memory

Hippocampal theta oscillations are slower in humans than in rodents: implications for models of spatial navigation and memory

Slow-theta power decreases during item-place encoding predict spatial accuracy of subsequent context recall

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