1630 The distribution of calbindin immunoreactive pyramidal neurons in cortical areas of the ventral visual pathway

AbstractResearch on retinopathy of prematurity (ROP) focuses mainly on the abnormal vascularization patterns that are directly visible for ophthalmologists. However, recent findings indicate that children born prematurely also exhibit changes in the retinal cellular architecture and along the dorsal visual stream, such as structural changes between and within cortical areas. Moreover, perinatal sustained systemic inflammation (SSI) is associated with an increased risk for ROP and the visual deficits that follow. In this paper, we propose that ROP might just be the tip of an iceberg we call visuopathy of prematurity (VOP). The VOP paradigm comprises abnormal vascularization of the retina, alterations in retinal cellular architecture, choroidal degeneration, and abnormalities in the visual pathway, including cortical areas. Furthermore, VOP itself might influence the developmental trajectories of cerebral structures and functions deemed responsible for visual processing, thereby explaining visual deficits among children born preterm.

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View-tuned and view-invariant face encoding in IT cortex is explained by selected natural image fragments

Scientific Reports ◽

10.1038/s41598-021-86842-7 ◽

2021 ◽

Vol 11 (1) ◽

Author(s):

Yunjun Nam ◽

Takayuki Sato ◽

Go Uchida ◽

Ekaterina Malakhova ◽

Shimon Ullman ◽

...

Keyword(s):

Face Recognition ◽

Visual Pathway ◽

Visual Features ◽

Natural Image ◽

Face Representation ◽

Low Level ◽

Ventral Visual Pathway ◽

Neural Substrate ◽

The Face

AbstractHumans recognize individual faces regardless of variation in the facial view. The view-tuned face neurons in the inferior temporal (IT) cortex are regarded as the neural substrate for view-invariant face recognition. This study approximated visual features encoded by these neurons as combinations of local orientations and colors, originated from natural image fragments. The resultant features reproduced the preference of these neurons to particular facial views. We also found that faces of one identity were separable from the faces of other identities in a space where each axis represented one of these features. These results suggested that view-invariant face representation was established by combining view sensitive visual features. The face representation with these features suggested that, with respect to view-invariant face representation, the seemingly complex and deeply layered ventral visual pathway can be approximated via a shallow network, comprised of layers of low-level processing for local orientations and colors (V1/V2-level) and the layers which detect particular sets of low-level elements derived from natural image fragments (IT-level).

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Temporal Dynamics of Shape Processing Differentiate Contributions of Dorsal and Ventral Visual Pathways

Journal of Cognitive Neuroscience ◽

10.1162/jocn_a_01391 ◽

2019 ◽

Vol 31 (6) ◽

pp. 821-836 ◽

Cited By ~ 2

Author(s):

Elliot Collins ◽

Erez Freud ◽

Jana M. Kainerstorfer ◽

Jiaming Cao ◽

Marlene Behrmann

Keyword(s):

Visual Information ◽

Temporal Dynamics ◽

Object Perception ◽

Visual Pathway ◽

Shape Sensitivity ◽

Shape Information ◽

Dorsal Pathway ◽

Ventral Visual Pathway ◽

Shape Processing ◽

Ventral Pathway

Although shape perception is primarily considered a function of the ventral visual pathway, previous research has shown that both dorsal and ventral pathways represent shape information. Here, we examine whether the shape-selective electrophysiological signals observed in dorsal cortex are a product of the connectivity to ventral cortex or are independently computed. We conducted multiple EEG studies in which we manipulated the input parameters of the stimuli so as to bias processing to either the dorsal or ventral visual pathway. Participants viewed displays of common objects with shape information parametrically degraded across five levels. We measured shape sensitivity by regressing the amplitude of the evoked signal against the degree of stimulus scrambling. Experiment 1, which included grayscale versions of the stimuli, served as a benchmark establishing the temporal pattern of shape processing during typical object perception. These stimuli evoked broad and sustained patterns of shape sensitivity beginning as early as 50 msec after stimulus onset. In Experiments 2 and 3, we calibrated the stimuli such that visual information was delivered primarily through parvocellular inputs, which mainly project to the ventral pathway, or through koniocellular inputs, which mainly project to the dorsal pathway. In the second and third experiments, shape sensitivity was observed, but in distinct spatio-temporal configurations from each other and from that elicited by grayscale inputs. Of particular interest, in the koniocellular condition, shape selectivity emerged earlier than in the parvocellular condition. These findings support the conclusion of distinct dorsal pathway computations of object shape, independent from the ventral pathway.

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Visualization of hypermetabolism in the ventral visual pathway by FDG-PET in the Charles Bonnet syndrome

Clinical Neurology and Neurosurgery ◽

10.1016/j.clineuro.2021.106832 ◽

2021 ◽

pp. 106832

Author(s):

Hanako Sasaki ◽

Yasunori Fujimoto ◽

Hiroyuki Ima ◽

Yu Kageyama

Keyword(s):

Fdg Pet ◽

Visual Pathway ◽

Charles Bonnet Syndrome ◽

Ventral Visual Pathway

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Emergence of a compositional neural code for written words: Recycling of a convolutional neural network for reading

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.2104779118 ◽

2021 ◽

Vol 118 (46) ◽

pp. e2104779118

Author(s):

T. Hannagan ◽

A. Agrawal ◽

L. Cohen ◽

S. Dehaene

Keyword(s):

Neural Network ◽

Convolutional Neural Network ◽

Language Processing ◽

Visual Pathway ◽

Neural Code ◽

Letter Recognition ◽

Invariant Representation ◽

Spoken Language Processing ◽

Visual Word Form Area ◽

Ventral Visual Pathway

The visual word form area (VWFA) is a region of human inferotemporal cortex that emerges at a fixed location in the occipitotemporal cortex during reading acquisition and systematically responds to written words in literate individuals. According to the neuronal recycling hypothesis, this region arises through the repurposing, for letter recognition, of a subpart of the ventral visual pathway initially involved in face and object recognition. Furthermore, according to the biased connectivity hypothesis, its reproducible localization is due to preexisting connections from this subregion to areas involved in spoken-language processing. Here, we evaluate those hypotheses in an explicit computational model. We trained a deep convolutional neural network of the ventral visual pathway, first to categorize pictures and then to recognize written words invariantly for case, font, and size. We show that the model can account for many properties of the VWFA, particularly when a subset of units possesses a biased connectivity to word output units. The network develops a sparse, invariant representation of written words, based on a restricted set of reading-selective units. Their activation mimics several properties of the VWFA, and their lesioning causes a reading-specific deficit. The model predicts that, in literate brains, written words are encoded by a compositional neural code with neurons tuned either to individual letters and their ordinal position relative to word start or word ending or to pairs of letters (bigrams).

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Heterogeneity of Phasic Cholinergic Signaling in Neocortical Neurons

Journal of Neurophysiology ◽

10.1152/jn.00493.2006 ◽

2007 ◽

Vol 97 (3) ◽

pp. 2215-2229 ◽

Cited By ~ 118

Author(s):

Allan T. Gulledge ◽

Susanna B. Park ◽

Yasuo Kawaguchi ◽

Greg J. Stuart

Keyword(s):

Visual Cortex ◽

Calcium Release ◽

Pyramidal Neurons ◽

Potassium Conductance ◽

Projection Neurons ◽

Sk Channels ◽

Cortical Areas ◽

Neocortical Neurons ◽

Cholinergic Signaling ◽

Nonpyramidal Neurons

Acetylcholine (ACh) is a neurotransmitter critical for normal cognition. Here we demonstrate heterogeneity of cholinergic signaling in neocortical neurons in the rat prefrontal, somatosensory, and visual cortex. Focal ACh application (100 μM) inhibited layer 5 pyramidal neurons in all cortical areas via activation of an apamin-sensitive SK-type calcium-activated potassium conductance. Cholinergic inhibition was most robust in prefrontal layer 5 neurons, where it relies on the same signal transduction mechanism (M1-like receptors, IP3-dependent calcium release, and SK-channels) as exists in somatosensory pyramidal neurons. Pyramidal neurons in layer 2/3 were less responsive to ACh, but substantial apamin-sensitive inhibitory responses occurred in deep layer 3 neurons of the visual cortex. ACh was only inhibitory when presented near the somata of layer 5 pyramidal neurons, where repetitive ACh applications generated discrete inhibitory events at frequencies of up to ∼0.5 Hz. Fast-spiking (FS) nonpyramidal neurons in all cortical areas were unresponsive to ACh. When applied to non-FS interneurons in layers 2/3 and 5, ACh generated mecamylamine-sensitive nicotinic responses (38% of cells), apamin-insensitive hyperpolarizing responses, with or without initial nicotinic depolarization (7% of neurons), or no response at all (55% of cells). Responses in interneurons were similar across cortical layers and regions but were correlated with cellular physiology and the expression of biochemical markers associated with different classes of nonpyramidal neurons. Finally, ACh generated nicotinic responses in all layer 1 neurons tested. These data demonstrate that phasic cholinergic input can directly inhibit projection neurons throughout the cortex while sculpting intracortical processing, especially in superficial layers.

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Reconstructing feedback representations in ventral visual pathway with a generative adversarial autoencoder

10.1101/2020.07.23.218859 ◽

2020 ◽

Author(s):

Haider Al-Tahan ◽

Yalda Mohsenzadeh

Keyword(s):

Neural Network ◽

Visual Information ◽

Visual Pathway ◽

Functional Magnetic Resonance ◽

Low Level ◽

Ventral Visual Pathway ◽

High Level ◽

Feedback Connections ◽

The Brain ◽

Insight Into

AbstractWhile vision evokes a dense network of feedforward and feedback neural processes in the brain, visual processes are primarily modeled with feedforward hierarchical neural networks, leaving the computational role of feedback processes poorly understood. Here, we developed a generative autoencoder neural network model and adversarially trained it on a categorically diverse data set of images. We hypothesized that the feedback processes in the ventral visual pathway can be represented by reconstruction of the visual information performed by the generative model. We compared representational similarity of the activity patterns in the proposed model with temporal (magnetoencephalography) and spatial (functional magnetic resonance imaging) visual brain responses. The proposed generative model identified two segregated neural dynamics in the visual brain. A temporal hierarchy of processes transforming low level visual information into high level semantics in the feedforward sweep, and a temporally later dynamics of inverse processes reconstructing low level visual information from a high level latent representation in the feedback sweep. Our results append to previous studies on neural feedback processes by presenting a new insight into the algorithmic function and the information carried by the feedback processes in the ventral visual pathway.Author summaryIt has been shown that the ventral visual cortex consists of a dense network of regions with feedforward and feedback connections. The feedforward path processes visual inputs along a hierarchy of cortical areas that starts in early visual cortex (an area tuned to low level features e.g. edges/corners) and ends in inferior temporal cortex (an area that responds to higher level categorical contents e.g. faces/objects). Alternatively, the feedback connections modulate neuronal responses in this hierarchy by broadcasting information from higher to lower areas. In recent years, deep neural network models which are trained on object recognition tasks achieved human-level performance and showed similar activation patterns to the visual brain. In this work, we developed a generative neural network model that consists of encoding and decoding sub-networks. By comparing this computational model with the human brain temporal (magnetoencephalography) and spatial (functional magnetic resonance imaging) response patterns, we found that the encoder processes resemble the brain feedforward processing dynamics and the decoder shares similarity with the brain feedback processing dynamics. These results provide an algorithmic insight into the spatiotemporal dynamics of feedforward and feedback processes in biological vision.

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The role of body partonomics and biological class in the representation of animacy in the ventral visual pathway

Journal of Vision ◽

10.1167/19.10.114 ◽

2019 ◽

Vol 19 (10) ◽

pp. 114

Author(s):

J.Brendan W Ritchie ◽

Joyce Bosmans ◽

Shuo Sun ◽

Kirsten Verhaegen ◽

Astrid Zeman ◽

...

Keyword(s):

Visual Pathway ◽

Ventral Visual Pathway

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