A predictive model of the cat cortical connectome based on cytoarchitecture and distance

Information processing in the brain is strongly constrained by anatomical connectivity. However, the principles governing the organization of corticocortical connections remain elusive. Here, we tested three models of relationships between the organization of cortical structure and features of connections linking 49 areas of the cat cerebral cortex. Factors taken into account were relative cytoarchitectonic differentiation (‘structural model’), relative spatial position (‘distance model’), or relative hierarchical position (‘hierarchical model’) of the areas. Cytoarchitectonic differentiation and spatial distance (themselves uncorrelated) correlated strongly with the existence of inter-areal connections, whereas no correlation was found with relative hierarchical position. Moreover, a strong correlation was observed between patterns of laminar projection origin or termination and cytoarchitectonic differentiation. Additionally, cytoarchitectonic differentiation correlated with the absolute number of corticocortical connections formed by areas, and varied characteristically between different cortical subnetworks, including a ‘richclub’ module of hub areas. Thus, connections between areas of the cat cerebral cortex can, to a large part, be explained by the two independent factors of relative cytoarchitectonic differentiation and spatial distance of brain regions. As both the structural and distance model were originally formulated in the macaque monkey, their applicability in another mammalian species suggests a general principle of global cortical organization

Cortex, countercurrent context, and dimensional integration of lifetime memory

The correlation between relative neocortex size and longevity in mammals encourages a search for a cortical function specifically related to the life-span. A candidate in the domain of permanent and cumulative memory storage is proposed and explored in relation to basic aspects of cortical organization. The pattern of cortico-cortical connectivity between functionally specialized areas and the laminar organization of that connectivity converges on a globally coherent representational space in which contextual embedding of information emerges as an obligatory feature of cortical function. This brings a powerful mode of inductive knowledge within reach of mammalian adaptations, a mode which combines item specificity with classificatory generality. Its neural implementation is proposed to depend on an obligatory interaction between the oppositely directed feedforward and feedback currents of cortical activity, in countercurrent fashion. Direct interaction of the two streams along their cortex-wide local interface supports a scheme of "contextual capture" for information storage responsible for the lifelong cumulative growth of a uniquely cortical form of memory termed "personal history." This approach to cortical function helps elucidate key features of cortical organization as well as cognitive aspects of mammalian life history strategies

Anatomical analysis of the feedback projections from extrastriate cortex to area 18 in ferret visual cortex

The purpose of this thesis is to characterize the cortical inputs to area 18 of ferret visual cerebral cortex. Contrary to feedforward connections, feedback connections are presumed to have a modulatory influence on the responses of lower order neurons providing information already processed. Input from feedback connections can supposedly elicit changes in the response to stimuli within the receptive field and may be involved in the role of discriminating objects relative to the background. The aim of our set of experiments was to fully analyze and compare the anatomical characteristics of feedback connections to area 18 from extrastriate areas as opposed to the feedback connections to area 17 in visual cortex. In our analysis, we focus on the overall pattern of retrogradely labeled cells, the proportion of feedback label to area 18, the laminar distribution of these cells, their density and clustering tendencies, and their cortical extent. With this solid base of information we can then make further hypotheses regarding the influence and role extrastriate areas 19, 21, and Suprasylvian cortex provide in modulation. The mean proportion of total cortical input from area 17 is 19.9%, from area 18 (39.5%), from area 19 (27.5%), from area 21 (4%), and from Ssy area (17.1%), from cells undefined in the border covering area 17 and area 18 (3.6%), border cells between area 18 and area 19 (1.5%). The overall feedback proportions when data is pooled for area 19 is 57.2%, for area 21 (8.75%), Ssy area (26.1%), area 18/19 border (6.6%) and area 19/21 border (1.4%). Within each area, there is a significantly larger proportion of feedback connections arising from the infragranular layers (means range between 70 and 88%) than from the supragranular layers (means range between 8% and 25%). After pooling all of our cases together, we measure the grand median of the nearest neighbor distance for each cortical area providing connections to area 18 including area 17 (34.14μm), area 18 (39.48μm), area 19 upper layers (45.61μm), area 19 lower layers (39.55μm), area 21 lower layers (62.48μm), Ssy area upper layers (57.8μm), Ssy area lower layers (44.28μm), borders of area 17/18 (34.58μm), borders of area 18/19 (55.4μm), borders of area 19/21 (41.58μm), and lateral temporal areas (57.74μm). We find the characterization of inputs to area 18 in comparison to the feedback projections to area 17 vary in proportion, anatomical location and cortical extent, which suggest different retinotopic representation in the visual fields

Perception-related modulations of local field potential power and coherence in primary visual cortex of awake monkey during binocular rivalry

Cortical synchronization at γ-frequencies (35–90 Hz) has been proposed to define the connectedness among the local parts of a perceived visual object. This hypothesis is still under debate. We tested it under conditions of binocular rivalry (BR), where a monkey perceived alternations among conflicting gratings presented singly to each eye at orthogonal orientations. We made multi-channel microelectrode recordings of multi-unit activity (MUA) and local field potentials (LFP) from striate cortex (V1) during BR while the monkey indicated his perception by pushing a lever. We analyzed spectral power and coherence of MUA and LFP over 4–90 Hz. As in previous work, coherence of γ-signals in most pairs of recording locations strongly depended on grating orientation when stimuli were presented congruently in both eyes. With incongruent (rivalrous) stimulation LFP power was often consistently modulated in consonance with the perceptual state. This was not visible in MUA. These perception-related modulations of LFP occurred at low and medium frequencies (<30 Hz), but not at γ-frequencies. Perception-related modulations of LFP coherence were also restricted to the low–medium range. In conclusion, our results do not support the expectation that γ-synchronization in V1 is related to the perceptual state during BR, but instead suggest a perception-related role of synchrony at low and medium frequencies

Mixed spatial and movement representations in the primate posterior parietal cortex

The posterior parietal cortex (PPC) of humans and non-human primates plays a key role in the sensory and motor transformations required to guide motor actions to objects of interest in the environment. Despite decades of research, the anatomical and functional organization of this region is still a matter of contention. It is generally accepted that specialized parietal subregions and their functional counterparts in the frontal cortex participate in distinct segregated networks related to eye, arm and hand movements. However, experimental evidence obtained primarily from single neuron recording studies in non-human primates has demonstrated a rich mixing of signals processed by parietal neurons, calling into question ideas for a strict functional specialization. Here, we present a brief account of this line of research together with the basic trends in the anatomical connectivity patterns of the parietal subregions. We review, the evidence related to the functional communication between subregions of the PPC and describe progress towards using parietal neuron activity in neuroprosthetic applications. Recent literature suggests a role for the PPC not as a constellation of specialized functional subdomains, but as a dynamic network of sensorimotor loci that combine multiple signals and work in concert to guide motor behavior