On the nature of three‐dimensional encoding in the cognitive map: Commentary on Hayman, Verriotis, Jovalekic, Fenton, and Jeffery

Taube, Jeffrey S.; Shinder, Michael E.

doi:10.1002/hipo.22074

Cited by 19 publications

(18 citation statements)

References 41 publications

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“…The critical points raised by Taube and Shinder (2013) may also be valid for the neurophysiological interpretation of our findings on anisotropic navigation of dogs in multilevel buildings. Nevertheless, the observation of their weak performance in identifying the right floor when using a staircase is striking and requires further experiments in which the reference frames for horizontal and vertical planes provide equivalent cues.…”

Section: Three-dimensional Navigation Of Ratsmentioning

confidence: 84%

“…The authors hypothesized that rat cognitive maps may be contextually modulated and twodimensional rather than volumetric and three-dimensional. However, Taube and Shinder (2013) argue that the results can be accounted for by considering the reference frame used by the animals in the task and present experimental evidence of the capability of rats for orienting and navigating in the vertical domain.…”

Section: Three-dimensional Navigation Of Ratsmentioning

confidence: 93%

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“Right Door,” wrong floor: A canine deficiency in navigation

Brandt

Dieterich

2013

Hippocampus

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Section: Three-dimensional Navigation Of Ratsmentioning

confidence: 84%

Section: Three-dimensional Navigation Of Ratsmentioning

confidence: 93%

“Right Door,” wrong floor: A canine deficiency in navigation

Brandt

Dieterich

2013

Hippocampus

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“…The importance of referencing the vestibular sensory information externally (to gravity) as opposed to internally (to the head), may not be clearly evident when the animal is moving with their head upright. However, as the animal moves in three dimensions, the difference in how sensory information is referenced defines whether the animal is able to continuously maintain orientation with its environment (Taube and Shinder, 2013). This view, that the cerebellum uses gravity to realign vestibular canal and otolith input in order to extract movement in the horizontal and vertical planes, has not been tested.…”

Section: Vestibular Systemmentioning

confidence: 99%

Resolving the active versus passive conundrum for head direction cells

Shinder

Taube

2014

Neuroscience

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Head direction (HD) cells have been identified in a number of limbic system structures. These cells encode the animal’s perceived directional heading in the horizontal plane and are dependent on an intact vestibular system. Previous studies have reported that the responses of vestibular neuron within the vestibular nuclei are markedly attenuated when an animal makes a volitional head turn compared to passive rotation. This finding presents a conundrum in that if vestibular responses are suppressed during an active head turn how is a vestibular signal propagated forward to drive and update the HD signal? This review identifies and discusses four possible mechanisms that could resolve this problem. These mechanisms are: 1) the ascending vestibular signal is generated by more than just vestibular-only neurons, 2) not all vestibular-only neurons contributing to the HD pathway have firing rates that are attenuated by active head turns, 3) the ascending pathway may be spared from the affects of the attenuation in that the HD system receives information from other vestibular brainstem sites that do not include vestibular-only cells, 4) the ascending signal is affected by the inhibited vestibular signal during an active head turn, but the HD circuit compensates and uses the altered signal to accurately update the current head direction. Future studies will be needed to decipher which of these possibilities is correct.

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“…The tuning curve of these neurons allows us to measure how their activity is related to incoming, highly-processed signals. The most-explored neuron types are the head-direction cells with a one-dimensional tuning curve, and place cells and grid cells with two-dimensional tuning curves (although the three types of neurons are known now to encompass one more dimension, namely the vertical plane (Taube and Shinder, 2013)). The neuronal activity of head-direction cells is represented by a Gaussian curve of the firing rate versus the animal's heading direction over 360 degrees.…”

mentioning

confidence: 99%

Decoding signal processing in thalamo-hippocampal circuitry: implications for theories of memory and spatial processing

Tsanov

O’Mara

2015

Brain Research

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a b s t r a c tA major tool in understanding how information is processed in the brain is the analysis of neuronal output at each hierarchical level through which neurophysiological signals are propagated. Since the experimental brain operation performed on Henry Gustav Molaison (known as patient H.M.) in 1953, the hippocampal formation has gained special attention, resulting in a very large number of studies investigating signals processed by the hippocampal formation. One of the main information streams to the hippocampal formation, vital for episodic memory formation, arises from thalamo-hippocampal projections, as there is extensive connectivity between these structures. This connectivity is sometimes overlooked by theories of memory formation by the brain, in favour of theories with a strong corticohippocampal flavour. In this review, we attempt to address some of the complexity of the signals processed within the thalamo-hippocampal circuitry. To understand the signals encoded by the anterior thalamic nuclei in particular, we review key findings from electrophysiological, anatomical, behavioural and computational studies. We include recent findings elucidating the integration of different signal modalities by single thalamic neurons;we focus in particular on the propagation of two prominent signals: head directionality and theta rhythm. We conclude that thalamo-hippocampal processing provides a centrally important, substantive, and dynamic input modulating and moderating hippocampal spatial and mnemonic processing. This article is part of a Special Issue entitled SI: Brain and Memory.& 2014 Published by Elsevier B.V. IntroductionThe purpose of the present review is to dissect some of the complexity of the signals propagated from anterior thalamus to the hippocampal formation in order to try and understand the importance of this information processing for the coding properties of individual neurons in the hippocampus. "Anterior thalamus" includes the anterodorsal, anteroventral and dorsolateral thalamic nuclei, which form the thalamic component of the limbic system (the 'thalamic

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On the nature of three‐dimensional encoding in the cognitive map: Commentary on Hayman, Verriotis, Jovalekic, Fenton, and Jeffery

Cited by 19 publications

References 41 publications

“Right Door,” wrong floor: A canine deficiency in navigation

“Right Door,” wrong floor: A canine deficiency in navigation

Resolving the active versus passive conundrum for head direction cells

Decoding signal processing in thalamo-hippocampal circuitry: implications for theories of memory and spatial processing

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