Thalamic and cortical projections to middle suprasylvian cortex of cats: constancy and variation

 We investigated the constancy and variability in the numbers of thalamic and cortical neurons projecting to cat middle suprasylvian (MS) visual cortex. Retrograde pathway tracers were injected at a single anatomically and physiologically defined locus in MS cortex. Counts of labeled neurons showed that the visual thalamic projections to MS cortex consistently arose from a fixed set of nuclei in relatively constant proportions. In contrast, counts of cortical neurons revealed that transcortical inputs to MS cortex were much more variable. This differential variability may be linked to the developmental program, which affords greater influence of experiential factors on cortical pathway development than on thalamocortical pathway development. These results have implications for the development of models of cerebral connectivity that include measures of pathway variability. Received: 29 March 1996 / Accepted: 3 September 1996     

Visual motion perception from stimulation of the human medial parieto-occipital cortex

Summary Visual phenomena evoked by direct electrical stimulation of extrastriate cortex were observed in 30 epileptic patients as part of a presurgical investigation. An incremental sequence of low-level bipolar stimulation trains was delivered at medial and lateral pairs of contacts of stereotaxically-implanted multilead intracerebral electrodes in parietal, occipital and posterior temporal regions. Diffusion of stimulus afterdischarges was monitored by electrodes in temporal and frontal lobes and by the non-stimulated contacts of the stimulated electrode. Localized stimulations evoked few visual phenomena. The strongest anatomo-perceptual correlation was found for stimulation in the medial parieto-occipital fissure which evoked visual motion phenomena in all three patients stimulated in that region. The evoked motion perceptions were not associated with eye movements or any particular localization of the epileptic focus. These perceptions were only evoked once outside of the medial PO region at the 61 sites examined. The results suggest that the medial parieto-occipital region is closely linked to the human visual motion processing system.     

Searching for the elusive neural substrates of body part terms: A neuropsychological study

Previous neuropsychological studies suggest that, compared to other categories of concrete entities, lexical and conceptual aspects of body part knowledge are frequently spared in brain-damaged patients. To further investigate this issue, we administered a battery of 12 tests assessing lexical and conceptual aspects of body part knowledge to 104 brain-damaged patients with lesions distributed throughout the telencephalon. There were two main outcomes. First, impaired oral naming of body parts, attributable to a disturbance of the mapping between lexical-semantic and lexical-phonological structures, was most reliably and specifically associated with lesions in the left frontal opercular and anterior/inferior parietal opercular cortices and in the white matter underlying these regions (8 patients). Also, 1 patient with body part anomia had a left occipital lesion that included the “extrastriate body area” (EBA). Second, knowledge of the meanings of body part terms was remarkably resistant to impairment, regardless of lesion site; in fact, we did not uncover a single patient who exhibited significantly impaired understanding of the meanings of these terms. In the 9 patients with body part anomia, oral naming of concrete entities was evaluated, and this revealed that 4 patients had disproportionately worse naming of body parts relative to other types of concrete entities. Taken together, these findings extend previous neuropsychological and functional neuroimaging studies of body part knowledge and add to our growing understanding of the nuances of how different linguistic and conceptual categories are operated by left frontal and parietal structures.     

Fast gamma oscillations in areas MT and MST occur during visual stimulation,but not during visually guided manual tracking

We studied the incidence of oscillatory activity in the gamma range (35–110 Hz) in single cell and multi-unit activity recorded from extrastriate areas MT (middle temporal) and MST (superior middle temporal) while rhesus monkeys performed different behavioural tasks. During full field stimulation by coherent motion of random dots, we observed gamma oscillations in approximately 20% of the cells. The average oscillation frequencies differed considerably between both animals (60 Hz vs 100 Hz). In both animals, oscillatory modulation was particularly strong at sites that showed a strong directional bias to visual stimulation. The amount of oscillatory activity was roughly the same whether stimulus movement was presented during fixation or whether the animal had to perform pursuit movements across a stationary visual pattern. If cells were engaged in gamma oscillations during visual stimulation, the amount of oscillatory modulation was dependent on stimulus direction, stimulus velocity and stimulus contrast. During a visually guided manual tracking task no gamma activity was detectable. Cells with clear oscillatory modulation during the full field stimulation failed to show oscillatory activity when the animal was involved in a motor task in which the visual motion information had to be evaluated for the correct movement of the hand. Our results reaffirm the ubiquitous presence of stimulus-induced gamma oscillation in extrastriate areas MT and MST of the awake monkey during various stimulus conditions, but they fail to support the notion that high-frequency gamma oscillations in this area play a specific role during cortical control of a motor response to visual stimulation. Electronic Publication     

Dynamic event-related potentials and rapid source analysis reveals an intermittent short-lasting dysfrontality in schizophrenia

Neuroimaging studies have identified regional brain dysfunctions in schizophrenia, but their dynamic consequences remain unclear. This study reports electrophysiological evaluation of medicated schizophrenic patients during performance of the Wisconsin Card Sorting Test. Using event-related potentials (ERPs), averaged after passing through several band pass filters, and source analysis with variable-resolution brain electrical tomography, cerebral sources were visualized at every latency point of the evoked potential. ERPs which differed from the control group were elicited principally in frontal, central, and parietal regions, within the delta and theta frequency ranges. Significant differences emerged at three different latencies (S1, S2, S3) in frontal/midline areas and at the anterior temporal electrode site T3 for slow potentials. The left occipitoparietal region showed significant differences within the alpha and beta 2 ranges, respectively. Medial fronto-orbital area and anterior cingulate cortex contributed to the development of the frontal ERPs and the lateral inferior frontal area to the temporal (T(3)) evoked-potential, while the precuneus/medial region generated the posterior activity recorded on the scalp. The significant intervals S1 and S3 were synchronous between the medial frontal and lateral inferior frontal region, while in the S2 interval the medial frontal areas were parallel with the precuneus/medial occipitotemporal region. A simultaneous functional imbalance between frontal subregions and posterior areas was uncovered. Here, we show for the first time an intermittent functional deficiency of specific brain areas during task-directed mentation in schizophrenia, which by its brevity is not accessible by neuroimaging methods measuring hemodynamic activity.     

Stimulus specific adaptation in excited but not in inhibited cells in inferotemporal cortex of Macaque

Many cells in inferotemporal cortex respond more actively to a novel presentation than to a subsequent re-presentation of the same image, exhibiting stimulus specific adaptation (SSA). Previously, analysis of this adaptation was limited to visually excited cells, excluding visually inhibited cells. In the present experiment we studied 654 cells in four macaques performing visual tasks. Strong SSA (P < 0.0001) was observed in those cells which were excited by visual stimuli. This adaptation was also seen in the subset of such cells which, though excited by visual stimuli, failed to show visual specificity in their responses. Interestingly, no SSA (P > 0.1) was observed in the group of cells inhibited by visual stimuli. Furthermore, most inhibited cells failed to show visual specificity. This lack of visual specificity and SSA suggest that the visually inhibited cells have a limited role in the detailed information processing of visual perception and memory activated by the tasks used in the present experiments.     

Area V1 in macaque monkeys projects to multiple histochemically defined subdivisions of the inferior pulvinar complex

To investigate how visuotopic connections relate to chemoarchitecture of the inferior pulvinar (PI) complex in macaques, neuroanatomical tracers were placed into known portions of the visual representation in V1. Separate foci of label associated with both the upper and lower visual quadrants occupied neurochemically defined medial, central, lateral, and lateral-shell subdivisions, PI_M, PI_C, PI_L, and PI_L-S. Visuotopic connection patterns thus supported the concept of a larger PI that includes portions of three classically defined ‘nuclei' [C. Gutierrez, A. Yaun and C.G. Cusick, Neurochemical subdivisions of the inferior pulvinar in macaque monkeys, J. Comp. Neurol., 363 (1995) 545–562.], and corresponds to the topographically organized V1 projection zone.     

Perception of visual motion coherence by rats and mice

The coherence thresholds to discriminate the direction of motion in random-dot kinematograms were measured in rats and mice. Performance was best in the rats when dot displacement from frame-to-frame was about 2 degrees, and frame duration was less than 100 ms. Mice had coherence thresholds similar to those of rats when tested at the same step size and frame duration. Although the lowest thresholds in the rats and mice occasionally reached human levels, average rodent values ( approximately 25%) were 2-3 times higher than those of humans. These data indicate that the rodent and primate visual systems are similar in that both have local motion detectors and a system for extracting global motion from a noisy signal.     

Spatiotemporal dynamics and connectivity pattern differences between centrally and peripherally presented faces

Most neuroimaging studies on face processing used centrally presented images with a relatively large visual field. Images presented in this way activate widespread striate and extrastriate areas and make it difficult to study spatiotemporal dynamics and connectivity pattern differences from various parts of the visual field. Here we studied magnetoencephalographic responses in humans to centrally and peripherally presented faces for testing the hypothesis that processing of visual stimuli with facial expressions of emotions depends on where the stimuli are presented in the visual field. Using our tomographic and statistical parametric mapping analyses, we identified occipitotemporal areas activated by face stimuli more than by control conditions. V1/V2 activity was significantly stronger for lower than central and upper visual field presentation. Fusiform activity, however, was significantly stronger for central than for peripheral presentation. Both the V1/V2 and fusiform areas activated earlier for peripheral than for central presentation. Fast responses in the fusiform were found at 70-80 ms after image onset, as well as a response at 130-160 ms. For peripheral presentation, contralateral V1/V2 and fusiform activated earlier (10 ms and 23 ms, respectively) and significantly stronger than their ipsilateral counterparts. Mutual information analysis further showed linked activity from bilateral V1/V2 to fusiform for central presentation and from contralateral V1/V2 to fusiform for lower visual field presentation. In the upper visual field, the linkage was from fusiform to V1/V2. Our results showed that face stimuli are processed predominantly in the hemisphere contralateral to the stimulation and demonstrated for the first time early fusiform activation leading V1/V2 activation for upper visual field stimulation.