Your search keyword '"suppression"' showing total 25 results

1. Stimulus Contrast Affects Spatial Integration in the Lateral Geniculate Nucleus of Macaque Monkeys

Author

Archer, Darlene R, Alitto, Henry J, and Usrey, W Martin

Subjects

Biomedical and Clinical Sciences, Neurosciences, Eye Disease and Disorders of Vision, extraclassical, gain control, LGN, parallel pathways, receptive field, suppression, Medical and Health Sciences, Psychology and Cognitive Sciences, Neurology & Neurosurgery

Abstract

Gain-control mechanisms adjust neuronal responses to accommodate the wide range of stimulus conditions in the natural environment. Contrast gain control and extraclassical surround suppression are two manifestations of gain control that govern the responses of neurons in the early visual system. Understanding how these two forms of gain control interact has important implications for the detection and discrimination of stimuli across a range of contrast conditions. Here, we report that stimulus contrast affects spatial integration in the lateral geniculate nucleus of alert macaque monkeys (male and female), whereby neurons exhibit a reduction in the strength of extraclassical surround suppression and an expansion in the preferred stimulus size with low-contrast stimuli compared with high-contrast stimuli. Effects were greater for magnocellular neurons than for parvocellular neurons, indicating stream-specific interactions between stimulus contrast and stimulus size. Within the magnocellular pathway, contrast-dependent effects were comparable for ON-center and OFF-center neurons, despite ON neurons having larger receptive fields, less pronounced surround suppression, and more pronounced contrast gain control than OFF neurons. Together, these findings suggest that the parallel streams delivering visual information from retina to primary visual cortex, serve not only to broaden the range of signals delivered to cortex, but also to provide a substrate for differential interactions between stimulus contrast and stimulus size that may serve to improve stimulus detection and stimulus discrimination under pathway-specific lower and higher contrast conditions, respectively.SIGNIFICANCE STATEMENT Stimulus contrast is a salient feature of visual scenes. Here we examine the influence of stimulus contrast on spatial integration in the lateral geniculate nucleus (LGN). Our results demonstrate that increases in contrast generally increase extraclassical suppression and decrease the size of optimal stimuli, indicating a reduction in the extent of visual space from which LGN neurons integrate signals. Differences between magnocellular and parvocellular neurons are noteworthy and further demonstrate that the feedforward parallel pathways to cortex increase the range of information conveyed for downstream cortical processing, a range broadened by diversity in the ON and OFF pathways. These results have important implications for more complex visual processing that underly the detection and discrimination of stimuli under varying natural conditions.

Published

2021

2. Modulation-frequency-specific adaptation in awake auditory cortex.

Author

Beitel, Ralph, Vollmer, Maike, Heiser, Marc, Schreiner, Christoph, and Malone, Brian

Subjects

auditory, context, monkey, primate, suppression, unanesthetized, Acoustic Stimulation, Adaptation, Physiological, Animals, Auditory Cortex, Auditory Pathways, Female, Linear Models, Neurons, Perceptual Masking, Psychophysics, Reaction Time, Saimiri, Sound, Wakefulness

Abstract

Amplitude modulations are fundamental features of natural signals, including human speech and nonhuman primate vocalizations. Because natural signals frequently occur in the context of other competing signals, we used a forward-masking paradigm to investigate how the modulation context of a prior signal affects cortical responses to subsequent modulated sounds. Psychophysical modulation masking, in which the presentation of a modulated masker signal elevates the threshold for detecting the modulation of a subsequent stimulus, has been interpreted as evidence of a central modulation filterbank and modeled accordingly. Whether cortical modulation tuning is compatible with such models remains unknown. By recording responses to pairs of sinusoidally amplitude modulated (SAM) tones in the auditory cortex of awake squirrel monkeys, we show that the prior presentation of the SAM masker elicited persistent and tuned suppression of the firing rate to subsequent SAM signals. Population averages of these effects are compatible with adaptation in broadly tuned modulation channels. In contrast, modulation context had little effect on the synchrony of the cortical representation of the second SAM stimuli and the tuning of such effects did not match that observed for firing rate. Our results suggest that, although the temporal representation of modulated signals is more robust to changes in stimulus context than representations based on average firing rate, this representation is not fully exploited and psychophysical modulation masking more closely mirrors physiological rate suppression and that rate tuning for a given stimulus feature in a given neurons signal pathway appears sufficient to engender context-sensitive cortical adaptation.

Published

2015

3. Modulation-Frequency-Specific Adaptation in Awake Auditory Cortex

Author

Malone, Brian J, Beitel, Ralph E, Vollmer, Maike, Heiser, Marc A, and Schreiner, Christoph E

Subjects

Biomedical and Clinical Sciences, Clinical Sciences, Basic Behavioral and Social Science, Neurosciences, Behavioral and Social Science, Underpinning research, 1.1 Normal biological development and functioning, Acoustic Stimulation, Adaptation, Physiological, Animals, Auditory Cortex, Auditory Pathways, Female, Linear Models, Neurons, Perceptual Masking, Psychophysics, Reaction Time, Saimiri, Sound, Wakefulness, auditory, context, monkey, primate, suppression, unanesthetized, Medical and Health Sciences, Psychology and Cognitive Sciences, Neurology & Neurosurgery

Abstract

Amplitude modulations are fundamental features of natural signals, including human speech and nonhuman primate vocalizations. Because natural signals frequently occur in the context of other competing signals, we used a forward-masking paradigm to investigate how the modulation context of a prior signal affects cortical responses to subsequent modulated sounds. Psychophysical "modulation masking," in which the presentation of a modulated "masker" signal elevates the threshold for detecting the modulation of a subsequent stimulus, has been interpreted as evidence of a central modulation filterbank and modeled accordingly. Whether cortical modulation tuning is compatible with such models remains unknown. By recording responses to pairs of sinusoidally amplitude modulated (SAM) tones in the auditory cortex of awake squirrel monkeys, we show that the prior presentation of the SAM masker elicited persistent and tuned suppression of the firing rate to subsequent SAM signals. Population averages of these effects are compatible with adaptation in broadly tuned modulation channels. In contrast, modulation context had little effect on the synchrony of the cortical representation of the second SAM stimuli and the tuning of such effects did not match that observed for firing rate. Our results suggest that, although the temporal representation of modulated signals is more robust to changes in stimulus context than representations based on average firing rate, this representation is not fully exploited and psychophysical modulation masking more closely mirrors physiological rate suppression and that rate tuning for a given stimulus feature in a given neuron's signal pathway appears sufficient to engender context-sensitive cortical adaptation.

Published

2015

4. Eye Choice for Acquisition of Targets in Alternating Strabismus

Author

Economides, John R, Adams, Daniel L, and Horton, Jonathan C

Subjects

Clinical Research, Brain Disorders, Eye Disease and Disorders of Vision, Neurosciences, Eye, Adolescent, Adult, Child, Choice Behavior, Exotropia, Female, Humans, Male, Middle Aged, Saccades, Vision, Binocular, Visual Fields, Young Adult, diplopia, exotropia, saccade, scan path, anomalous retinal correspondence, suppression, Medical and Health Sciences, Psychology and Cognitive Sciences, Neurology & Neurosurgery

Abstract

In strabismus, potentially either eye can inform the brain about the location of a target so that an accurate saccade can be made. Sixteen human subjects with alternating exotropia were tested dichoptically while viewing stimuli on a tangent screen. Each trial began with a fixation cross visible to only one eye. After the subject fixated the cross, a peripheral target visible to only one eye flashed briefly. The subject's task was to look at it. As a rule, the eye to which the target was presented was the eye that acquired the target. However, when stimuli were presented in the far nasal visual field, subjects occasionally performed a "crossover" saccade by placing the other eye on the target. This strategy avoided the need to make a large adducting saccade. In such cases, information about target location was obtained by one eye and used to program a saccade for the other eye, with a corresponding latency increase. In 10/16 subjects, targets were presented on some trials to both eyes. Binocular sensory maps were also compiled to delineate the portions of the visual scene perceived with each eye. These maps were compared with subjects' pattern of eye choice for target acquisition. There was a correspondence between suppression scotoma maps and the eye used to acquire peripheral targets. In other words, targets were fixated by the eye used to perceive them. These studies reveal how patients with alternating strabismus, despite eye misalignment, manage to localize and capture visual targets in their environment.

Published

2014

5. Spatially Guided Distractor Suppression during Visual Search.

Author

Feldmann-Wüstefeld, Tobias, Weinberger, Marina, and Awh, Edward

Subjects

*VISUAL perception, *GOAL (Psychology), *ELECTROPHYSIOLOGY, *MULTIVARIATE analysis, *ELECTROENCEPHALOGRAPHY

Abstract

Past work has demonstrated that active suppression of salient distractors is a critical part of visual selection. Evidence for goaldriven suppression includes below-baseline visual encoding at the position of salient distractors (Gaspelin and Luck, 2018) and neural signals such as the distractor positivity (Pd) that track how many distractors are presented in a given hemifield (Feldmann-Wüstefeld and Vogel, 2019). One basic question regarding distractor suppression is whether it is inherently spatial or nonspatial in character. Indeed, past work has shown that distractors evoke both spatial (Theeuwes, 1992) and nonspatial forms of interference (Folk and Remington, 1998), motivating a direct examination of whether space is integral to goal-driven distractor suppression. Here, we use behavioral and EEG data from adult humans (male and female) to provide clear evidence for a spatial gradient of suppression surrounding salient singleton distractors. Replicating past work, both reaction time and neural indices of target selection improved monotonically as the distance between target and distractor increased. Importantly, these target selection effects were paralleled by a monotonic decline in the amplitude of the Pd, an electrophysiological index of distractor suppression. Moreover, multivariate analyses revealed spatially selective activity in the h-band that tracked the position of the target and, critically, revealed suppressed activity at spatial channels centered on distractor positions. Thus, goal-driven selection of relevant over irrelevant information benefits from a spatial gradient of suppression surrounding salient distractors. [ABSTRACT FROM AUTHOR]

Published

2021

6. Visual Attention Modulates Glutamate-Glutamine Levels in Vestibular Cortex: Evidence from Magnetic Resonance Spectroscopy.

Author

Frank, Sebastian M., Forster, Lisa, Pawellek, Maja, Malloni, Wilhelm M., Ahn, Sinyeob, Tse, Peter U., and Greenlee, Mark W.

Subjects

*NUCLEAR magnetic resonance spectroscopy, *FUNCTIONAL magnetic resonance imaging

Abstract

Attending to a stimulus enhances the neuronal responses to it, while responses to nonattended stimuli are not enhanced and may even be suppressed. Although the neural mechanisms of response enhancement for attended stimuli have been intensely studied, the neural mechanisms underlying attentional suppression remain largely unknown. It is uncertain whether attention acts to suppress the processing in sensory cortical areas that would otherwise process the nonattended stimulus or the subcortical input to these cortical areas. Moreover, the neurochemical mechanisms inducing a reduction or suppression of neuronal responses to nonattended stimuli are as yet unknown. Here, we investigated how attention directed toward visual processing cross-modally acts to suppress vestibular responses in the human brain. By using functional magnetic resonance spectroscopy in a group of female and male subjects, we find that attention to visual motion downregulates in a load-dependent manner the concentration of excitatory neurotransmitter (glutamate and its precursor glutamine, referred to together as Glx) within the parietoinsular vestibular cortex (PIVC), a core cortical area of the vestibular system, while leaving the concentration of inhibitory neurotransmitter (GABA) in PIVC unchanged. This makes PIVC less responsive to excitatory thalamic vestibular input, as corroborated by functional magnetic resonance imaging. Together, our results suggest that attention acts to suppress the processing of nonattended sensory cues cortically by neurochemically rendering the core cortical area of the nonattended sensory modality less responsive to excitatory thalamic input. [ABSTRACT FROM AUTHOR]

Published

2021

7. Laminar Subnetworks of Response Suppression in Macaque Primary Visual Cortex.

Author

Tian Wang, Yang Li, Guanzhong Yang, Weifeng Dai, Yi Yang, Chuanliang Han, Xingyun Wang, Yange Zhang, and Dajun Xing

Subjects

*VISUAL cortex, *MACAQUES, *GENERATING functions, *INFORMATION processing, *MONKEYS

Abstract

Cortical inhibition plays an important role in information processing in the brain. However, the mechanisms by which inhibition and excitation are coordinated to generate functions in the six layers of the cortex remain unclear. Here, we measured laminar-specific responses to stimulus orientations in primary visual cortex (VI) of awake monkeys (male, Macaca mulatto). We distinguished inhibitory effects (suppression) from excitation, by taking advantage of the separability of excitation and inhibition in the orientation and time domains. We found two distinct types of suppression governing different layers. Fast suppression (FS) was strongest in input layers (4C and 6), and slow suppression (SS) was 3 times stronger in output layers (2/3 and 5). Interestingly, the two types of suppression were correlated with different functional properties measured with drifting gratings. FS was primarily correlated with orientation selectivity in input layers (r = -0.65, p < 10-9), whereas SS was primarily correlated with surround suppression in output layers (r = 0.61, p < 10-4). The earliest SS in layer 1 indicates the origin of cortical feedback for SS, in contrast to the feedforward/recurrent origin of FS. Our results reveal two VI laminar subnetworks with different response suppression that may provide a general framework for laminar processing in other sensory cortices. [ABSTRACT FROM AUTHOR]

Published

2020

8. Alpha Oscillations in the Human Brain Implement Distractor Suppression Independent of Target Selection.

Author

Wostmann, Malte, Alavash, Mohsen, and Obleser, Jonas

Subjects

*ABSOLUTE pitch, *OSCILLATIONS, *SELECTIVITY (Psychology)

Abstract

In principle, selective attention is the net result of target selection and distractor suppression. The way in which both mechanisms are implemented neurally has remained contested. Neural oscillatory power in the alpha frequency band (--10 Hz) has been implicated in the selection of to-be-attended targets, but there is lack of empirical evidence for its involvement in the suppression of to-be-ignored distractors. Here, we use electroencephalography recordings of N = 33 human participants (males and females) to test the preregistered hypothesis that alpha power directly relates to distractor suppression and thus operates independently from target selection. In an auditory spatial pitch discrimination task, we modulated the location (left vs right) of either a target or a distractor tone sequence, while fixing the other in the front. When the distractor was fixed in the front, alpha power relatively decreased contralaterally to the target and increased ipsilaterally. Most importantly, when the target was fixed in the front, alpha lateralization reversed in direction for the suppression of distractors on the left versus right. These data show that target-selection-independent alpha power modulation is involved in distractor suppression. Although both lateralized alpha responses for selection and for suppression proved reliable, they were uncorrelated and distractor-related alpha power emerged from more anterior, frontal cortical regions. Lending functional significance to suppression-related alpha oscillations, alpha lateralization at the individual, single-trial level was predictive of behavioral accuracy. These results fuel a renewed look at neurobiological accounts of selection-independent suppressive filtering in attention. [ABSTRACT FROM AUTHOR]

Published

2019

9. Aversive Training Induces Both Presynaptic and Postsynaptic Suppression in Drosophila.

Author

Xiaofan Zhang, Noyes, Nathaniel C., Jianzhi Zeng, Yulong Li, and Davis, Ronald L.

Subjects

*DROSOPHILA, *GABAERGIC neurons, *SMELL, *APPROACH behavior, *AVOIDANCE conditioning

Abstract

The α′β′ subtype of Drosophila mushroom body neurons (MBn) is required for memory acquisition, consolidation and early memory retrieval after aversive olfactory conditioning. However, in vivo functional imaging studies have failed to detect an early forming memory trace in these neurons as reflected by an enhanced G-CaMP signal in response to presentation of the learned odor. Moreover, whether cellular memory traces form early after conditioning in the mushroom body output neurons (MBOn) downstream of the α′β′ MBn remains unknown. Here, we show that aversive olfactory conditioning suppresses the calcium responses to the learned odor in both α′3 and α′2 axon segments of α′β′ MBn and in the dendrites of α′3 MBOn immediately after conditioning using female flies. Notably, the cellular memory traces in both α′3 MBn and α′3 MBOn are short-lived and persist for <30 min. The suppressed response in α′3 MBn is accompanied by a reduction of acetylcholine (ACh) release, suggesting that the memory trace in postsynaptic α′3 MBOn may simply reflect the suppression in presynaptic α′3 MBn. Furthermore, we show that the α′3 MBn memory trace does not occur from the inhibition of GABAergic neurons via GABAA receptor activation. Because activation of the α′3 MBOn drives approach behavior of adult flies, our results demonstrate that aversive conditioning promotes avoidance behavior through suppression of the α′3 MBn–MBOn circuit. [ABSTRACT FROM AUTHOR]

Published

2019

10. Neural Correlate of Visual Familiarity in Macaque Area V2.

Author

Huang, Ge, Ramachandran, Suchitra, Lee, Tai Sing, and Olson, Carl R.

Subjects

*MACAQUES, *EXPONENTIAL functions, *MONKEYS, *NEURONS

Abstract

Neurons in macaque inferotemporal cortex (ITC) respond less strongly to familiar than to novel images. It is commonly assumed that this effect arises within ITC because its neurons respond selectively to complex images and thus encode in an explicit form information sufficient for identifying a particular image as familiar. However, no prior study has examined whether neurons in low-order visual areas selective for local features also exhibit familiarity suppression. To address this issue, we recorded from neurons in macaque area V2 with semichronic microelectrode arrays while monkeys repeatedly viewed a set of large complex natural images. We report here that V2 neurons exhibit familiarity suppression. The effect develops over several days with a trajectory well fitted by an exponential function with a rate constant of ~ 100 exposures. Suppression occurs in V2 at a latency following image onset shorter than its reported latency in ITC. [ABSTRACT FROM AUTHOR]

Published

2018

11. Mechanisms of Saccadic Suppression in Primate Cortical Area V4.

Author

Zanos, Theodoros P., Mineault, Patrick J., Guitton, Daniel, and Pack, Christopher C.

Subjects

*SACCADIC eye movements, *VISUAL perception, *STIMULUS & response (Biology), *NEURONS, *NEURAL circuitry

Abstract

Psychophysical studies have shown that subjects are often unaware of visual stimuli presented around the time of an eye movement. This saccadic suppression is thought to be a mechanism for maintaining perceptual stability. The brain might accomplish saccadic suppression by reducing the gain of visual responses to specific stimuli or by simply suppressing firing uniformly for all stimuli. Moreover, the suppression might be identical across the visual field or concentrated at specific points. To evaluate these possibilities, we recorded from individual neurons in cortical area V4 of nonhuman primates trained to execute saccadic eye movements. We found that both modes of suppression were evident in the visual responses of these neurons and that the two modes showed different spatial and temporal profiles: while gain changes started earlier and were more widely distributed across visual space, nonspecific suppression was found more often in the peripheral visual field, after the completion of the saccade. Peripheral suppression was also associated with increased noise correlations and stronger local field potential oscillations in the α frequency band. This pattern of results suggests that saccadic suppression shares some of the circuitry responsible for allocating voluntary attention. [ABSTRACT FROM AUTHOR]

Published

2016

12. On the Role of Suppression in Spatial Attention: Evidence from Negative BOLD in Human Subcortical and Cortical Structures.

Author

Gouws, André D., Alvarez, Ivan, Watson, David M., Uesaki, Maiko, Rogers, Jessica, and Morland, Antony B.

Subjects

*NEURONS, *VISUAL perception, *CEREBRAL cortex, *GENICULATE bodies, *VISUAL cortex, *MAGNETIC resonance imaging

Abstract

There is clear evidence that spatial attention increases neural responses to attended stimuli in extrastriate visual areas and, to a lesser degree, in earlier visual areas. Other evidence shows that neurons representing unattended locations can also be suppressed. However, the extent to which enhancement and suppression is observed, their stimulus dependence, and the stages of the visual system at which they are expressed remains poorly understood. Using fMRI we set out to characterize both the task and stimulus dependence of neural responses in the lateral geniculate nucleus (LGN), primary visual cortex (V1), and visual motion area (V5) in humans to determine where suppressive and facilitatory effects of spatial attention are expressed. Subjects viewed a lateralized drifting grating stimulus, presented at multiple stimulus contrasts, and performed one of three tasks designed to alter the spatial location of their attention. In retinotopic representations of the stimulus location, we observed increasing attention-dependent facilitation and decreasing dependence on stimulus contrast moving up the visual hierarchy from theLGNto V5. However, in the representations of unattended locations of theLGNand V1, we observed suppression, which was not significantly dependent on the attended stimulus contrast. These suppressive effects were also found in the pulvinar, which has been frequently associated with attention. We provide evidence, therefore, for a spatially selective suppressive mechanism that acts at a subcortical level. [ABSTRACT FROM AUTHOR]

Published

2014

13. Suppression of Salient Objects Prevents Distraction in Visual Search.

Author

Gaspar, John M. and McDonald, John J.

Subjects

*VISUAL environment, *BRAIN imaging, *FRONTAL lobe, *NEUROPHYSIOLOGY, *SHORT-term memory, *ELECTROENCEPHALOGRAPHY

Abstract

To find objects of interest in a cluttered and continually changing visual environment, humans must often ignore salient stimuli that are not currently relevant to the task at hand. Recent neuroimaging results indicate that the ability to prevent salience-driven distraction depends on the current level of attentional control activity in frontal cortex, but the specific mechanism by which this control activity prevents salience-driven distraction is still poorly understood. Here, we asked whether salience-driven distraction is prevented by suppressing salient distractors or by preferentially up-weighting the relevant visual dimension. We found that salient distractors were suppressed even when they resided in the same feature dimension as the target (that is, when dimensional weighting was not a viable selection strategy). Our neurophysiological measure of suppression--the PD component of the event-related potential--was associated with variations in the amount of time it took to perform the search task: distractors triggered the PD on fast-response trials, but on slow-response trials they triggered activity associated with working memory representation instead. These results demonstrate that during search salience-driven distraction is mitigated by a suppressive mechanism that reduces the salience of potentially distracting visual objects. [ABSTRACT FROM AUTHOR]

Published

2014

14. Wide-Dynamic-Range Forward Suppression in Marmoset Inferior Colliculus Neurons Is Generated Centrally and Accounts for Perceptual Masking.

Author

Nelson, Paul C., Smith, Zachary M., and Young, Eric D.

Subjects

*NEURONS, *SENSORIMOTOR integration, *AVERSIVE stimuli, *INFERIOR colliculus, *ACOUSTIC nerve

Abstract

An organism's ability to detect and discriminate sensory inputs depends on the recent stimulus history. For example, perceptual detection thresholds for a brief tone can be elevated by as much as 50 dB when following a masking stimulus. Previous work suggests that such forward masking is not a direct result of peripheral neural adaptation; the central pathway apparently modifies the representation in a way that further attenuates the input's response to short probe signals. Here, we show that much of this transformation is complete by the level of the inferior colliculus (IC). Single-neuron extracellular responses were recorded in the central nucleus of the awake marmoset IC. The threshold for a 20ms probe tone presented at best frequency was determined for various masker-probe delays, over a range of masker sound pressure levels (SPLs) and frequencies. The most striking aspect of the data was the increased potency of forward maskers as their SPL was increased, despite the fact that the excitatory response to the masker was often saturating or nonmonotonic over the same range of levels. This led to probe thresholds at high masker levels that were almost always higher than those observed in the auditory nerve. Probe threshold shifts were not usually caused by a persistent excitatory response to the masker; instead we propose a wide-dynamicrange inhibitory mechanism locked to sound offset as an explanation for several key aspects of the data. These findings further delineate the role of subcortical auditory processing in the generation of a context-dependent representation of ongoing acoustic scenes. [ABSTRACT FROM AUTHOR]

Published

2009

15. Attention Enhances the Neural Processing of Relevant Features and Suppresses the Processing of Irrelevant Features in Humans: A Functional Magnetic Resonance Imaging Study of the Stroop Task.

Author

Polk, Thad A., Drake, Robert M., Jonides, John J., Smith, Mason R., and Smith, Edward E.

Subjects

*NEURAL transmission, *COLORS, *READING, *TASK performance, *ATTENTION, *MAGNETIC resonance imaging

Abstract

We present a functional MRI experiment investigating the neural basis of feature-based attention in humans using the Stroop task. Cortical areas specifically involved in color processing and word reading were first identified in individual participants using independent tests. These areas were then probed during the Stroop task (in which participants must selectively attend to the font color of a word while ignoring the word itself). We found that activation in functionally defined color areas increased during the task relative to a neutral color-naming task while activation in functionally defined word areas decreased. These results are consistent with a biased competition model of feature-based attention in which the processing of attended features is enhanced and the processing of ignored features is suppressed. [ABSTRACT FROM AUTHOR]

Published

2008

16. Anticipatory Suppression of Nonattended Locations in Visual Cortex Marks Target Location and Predicts Perception.

Author

Sylvester, Chad M., Jack, Anthony I., Corbetta, Maurizio, and Shulman, Gordon L.

Subjects

*VISUAL cortex, *OXYGENATORS, *FRONTAL lobe, *BLOOD circulation disorders, *BRAIN blood-vessels

Abstract

Spatial attention is associated with modulations in prestimulus, anticipatory blood oxygen level-dependent (BOLD) activity across the brain. It is unclear, however, if these anticipatory modulations depend on the computational demands of the upcoming task. Here, we show that anticipation of low-contrast stimuli, relative to high-contrast stimuli, is associated with increased prestimulus BOLD activity in the frontal eye field (FEF) and the posterior inferior frontal sulcus (IFS) but not in the intraparietal sulcus (IPS). In visual cortex, anticipation of low-contrast stimuli is associated with increased suppression of activity corresponding to unattended (but not attended) locations, and this suppression predicts whether subjects will accurately perceive low-contrast stimuli. These results suggest that when a stimulus will be difficult to distinguish from the background, top-down signals from FEF and IFS can facilitate perception by marking its location through the suppression of unattended locations in visual cortex. [ABSTRACT FROM AUTHOR]

Published

2008

17. Spatial Summation Can Explain the Attentional Modulation of Neuronal Responses to Multiple Stimuli in Area V4.

Author

Ghose, Geoffrey M. and Maunsell, John H. R.

Subjects

*SPATIAL behavior, *SPACE perception, *CONDITIONED response, *NEURONS, *ATTENTION

Abstract

Although many studies have shown that the activity of individual neurons in a variety of visual areas is modulated by attention, a fundamental question remains unresolved: can attention alter the visual representations of individual neurons? One set of studies, primarily relying on the attentional modulations observed when a single stimulus is presented within the receptive field of a neuron, suggests that neuronal selectivities, such as orientation or direction tuning, are not fundamentally altered by attention (Salinas and Abbott, 1997; McAdams and Maunsell, 1999; Treue and Martinez Trujillo, 1999). Another set of studies, relying on modulations observed when multiple stimuli are presented within a receptive field, suggests that attention can alter the weighting of sensory inputs (Moran and Desimone, 1985; Luck et al., 1997; Reynolds et al., 1999; Chelazzi et al., 2001). In these studies, when preferred and nonpreferred stimuli are simultaneously presented, responses are much stronger when attention is directed to the preferred stimulus than when it is directed to the nonpreferred stimulus. In this study, we recorded neuronal responses from individual neurons in visual cortical area V4 to both single and paired stimuli with a variety of attentional allocations and stimulus combinations. For each neuron studied, we constructed a quantitative model of input summation and then tested various models of attention. In many neurons, we are able to explain neuronal responses across the entire range of stimuli and attentional allocations tested. Specifically, we are able to reconcile seemingly inconsistent observations of single and paired stimuli attentional modulation with a new model in which attention can facilitate or suppress specific inputs to a neuron but does not fundamentally alter the integration of these inputs. [ABSTRACT FROM AUTHOR]

Published

2008

18. Wide-Dynamic-Range Forward Suppression in Marmoset Inferior Colliculus Neurons Is Generated Centrally and Accounts for Perceptual Masking.

Author

Nelson, Paul C., Smith, Zachary M., and Young, Eric D.

Subjects

*MARMOSETS, *INFERIOR colliculus, *AUDITORY cortex, *NEUROPLASTICITY, *MEDICAL research

Abstract

An organism's ability to detect and discriminate sensory inputs depends on the recent stimulus history. For example, perceptual detection thresholds for a brief tone can be elevated by as much as 50 dB when following a masking stimulus. Previous work suggests that such forward masking is not a direct result of peripheral neural adaptation; the central pathway apparently modifies the representation in a way that further attenuates the input's response to short probe signals. Here, we show that much of this transformation is complete by the level of the inferior colliculus (IC). Single-neuron extracellular responses were recorded in the central nucleus of the awake marmoset IC. The threshold for a 20ms probe tone presented at best frequency was determined for various masker-probe delays, over a range of masker sound pressure levels (SPLs) and frequencies. The most striking aspect of the data was the increased potency of forward maskers as their SPL was increased, despite the fact that the excitatory response to the masker was often saturating or nonmonotonic over the same range of levels. This led to probe thresholds at high masker levels that were almost always higher than those observed in the auditory nerve. Probe threshold shifts were not usually caused by a persistent excitatory response to the masker; instead we propose a wide-dynamic range inhibitory mechanism locked to sound offset as an explanation for several key aspects of the data. These findings further delineate the role of subcortical auditory processing in the generation of a context-dependent representation of ongoing acoustic scenes. [ABSTRACT FROM AUTHOR]

Published

2008

19. Seizure Suppression by top1 Mutations in Drosophila.

Author

Song, Juan, Hu, Joyce, and Tanouye, Mark

Subjects

*SPASMS, *DROSOPHILA, *DNA topoisomerase I, *CAMPTOTHECIN, *EPILEPSY

Abstract

DNA topoisomerase I is an essential nuclear enzyme involved in resolving the torsional stress associated with DNA replication, transcription, and chromatin condensation. Here we report the discovery of a seizure-suppressor mutant, top1JS, which suppresses seizures in a Drosophila model of human epilepsy. A P-element mutagenesis screen using easily shocked seizure-sensitive mutant as a genetic background identified top1JS, which plays a novel role in regulating nervous system excitability. Plasmid rescue, excision, complementation, and sequencing analyses verified that top1JS results from a P-element insertion in the 5′ untranslated region. Quantitative reverse transcription analysis on wild-type and mutant fly heads showed that the top1JS mutation causes reduced transcription level in the CNS, suggesting a partial loss-of-function mutation. Electrophysiological experiments revealed normal seizure thresholds in top1JS mutants, which are different from other seizure suppressors identified previously, suggesting a novel mechanism underlying seizure suppression by top1JS. The pharmacological camptothecin feeding experiment and cell death analysis suggested that the seizure suppression by top1JS may occur via increased neuronal apoptosis. Furthermore, overexpression of the DIAP1 (Drosophila inhibitor of apoptosis 1) gene rescues top1JS suppression, providing additional support for a neural apoptosis suppression mechanism. The top1JS mutation is the first viable partial loss-of-function mutation identified in higher eukaryotes, and the results presented here point to a novel function for topo I in construction and/or maintenance of circuits required for seizure propagation in vivo. [ABSTRACT FROM AUTHOR]

Published

2007

20. The Dynamics of Spatiotemporal Response Integration in the Somatosensory Cortex of the Vibrissa System.

Author

Boloori, Ali-Reza and Stanley, Garrett B.

Subjects

*WHISKERS, *NEURONS, *CEREBRAL cortex, *TOUCH, *RATS, *SENSES

Abstract

Spatiotemporal response integration across the neural receptive field (RF) is a general feature of sensory coding and has an important role in shaping responses to naturalistic stimuli. In the primary somatosensory cortex of the rat vibrissa pathway, such integration across the vibrissa array strongly shapes the coding of spatiotemporally distributed deflections. Using a spatiotemporal paired-pulse paradigm, this study revealed that fundamentally different types of pairwise interactions have similar qualitative behavior but that the magnitude, latency, and precision of the neural responses depend on the specific RF components being engaged. In all cases, however, increase in the suppression of response magnitude accompanied a lengthening of latency and a decrease in response precision. Furthermore, nonlinear interactions evoked by stimulation of multiple RF subregions strongly influence both response magnitude and timing to more complex sequences. Despite their complexity, such response interactions are highly predictable from elementary pairwise interactions. To understand the functional role of spatiotemporal interactions in coding, we developed a response model that incorporated the experimentally measured modulations in response magnitude, latency, and precision induced by cross-vibrissa interactions. Simulations of a simplified textural discrimination task indicate that spatiotemporal interactions enhance discrimination under certain stimulus time scales. This improvement follows from a nonlinear response property that acts to restore the neural response in the face of suppression. Together, the present findings highlight the role of response integration in shaping single-cell responses and provide predictions about how changes in response parameters influence coding accuracy. [ABSTRACT FROM AUTHOR]

Published

2006

21. Two Distinct Mechanisms of Suppression in Human Vision.

Author

Petrov, Yury, Carandini, Matteo, and McKee, Suzanne

Subjects

*VISION, *NEURONS, *HIGHER nervous activity, *VISUAL acuity, *SPATIAL ability

Abstract

Cortical visual neurons in the cat and monkey are inhibited by stimuli surrounding their receptive fields (surround suppression) or presented within their receptive fields (cross-orientation or overlay suppression). We show that human contrast sensitivity is similarly affected by two distinct suppression mechanisms. In agreement with the animal studies, human surround suppression is tightly tuned to the orientation and spatial frequency of the test, unlike overlay suppression. Using a double-masking paradigm, we also show that in humans, overlay suppression precedes surround suppression in the processing sequence. Surprisingly, we find that, unlike overlay suppression, surround suppression is only strong in the periphery (>1° eccentricity). This result argues for a new functional distinction between foveal and peripheral operations. [ABSTRACT FROM AUTHOR]

Published

2005

22. Nonlinear Response Properties of Combination-Sensitive Electrosensory Neurons in the Midbrain of Gymnarchus niloticus.

Author

Carlson, Bruce A. and Kawasaki, Masashi

Subjects

*JAMMING avoidance response (Electrophysiology), *ELECTROLOCATION (Physiology), *ELECTRIC fishes, *GYMNARCHUS niloticus, *ELECTRIC organs in fishes, *ELECTRIC discharges

Abstract

The jamming avoidance response of the weakly electric fish Gymnarchus niloticus relies on determining the sign of the frequency difference (Df) between the fish's own electric organ discharge (EOD) and that of a neighbor, which is achieved by comparing modulations in amplitude (AM) and phase (PM) that result from the summation of their EODs. These two stimulus features are processed in separate pathways that converge in the torus semicircularis on combination-sensitive neurons, many of which are selective for the sign of Df. We recorded extracellular single-unit responses to independent stimulation with AM and PM and combined AM-PM stimulation to determine how sign selectivity is established. Responses to AM and PM frequently summated nonlinearly, leading to sign-selective responses as a result of facilitation to the preferred sign of Df and/or suppression to the nonpreferred sign of Df. Facilitation typically occurred when responses to AM and PM were aligned, whereas suppression typically occurred when they were offset. By experimentally manipulating the degree of alignment between these two responses, we found that the summed response was dependent on their relative timing. In addition, we found a unique class of units that were sensitive to differences in amplitude between two body surfaces. This sensitivity rendered such units immune to the problem of orientation ambiguity, in which the sign selectivity of a single neuron reverses with changes in stimulus orientation. We discuss potential synaptic mechanisms for driving nonlinear responses in these and other combination-sensitive neurons. [ABSTRACT FROM AUTHOR]

Published

2004

23. Dominant-Negative Calcium Channel Suppression by Truncated Constructs Involves a Kinase Implicated in the Unfolded Protein Response.

Author

Page, Karen M., Heblich, Fay, Davies, Anthony, Butcher, Adrian J., Leroy, Jerôme, Bertaso, Federica, Pratt, Wendy S., and Dolphin, Annette C.

Subjects

*CALCIUM channels, *ENDOPLASMIC reticulum, *PROTEIN kinases, *ATAXIA, *NEUROPHYSIOLOGY

Abstract

Expression of the calcium channel Cav2.2 is markedly suppressed by coexpression with truncated constructs of Cav2.2. Furthermore, a two-domain construct of Cav2.1 mimicking an episodic ataxia-2 mutation strongly inhibited Cav2.1 currents. We have now determined the specificity of this effect, identified a potential mechanism, and have shown that such constructs also inhibit endogenous calcium currents when transfected into neuronal cell lines. Suppression of calcium channel expression requires interaction between truncated and full-length channels, because there is inter-subfamily specificity. Although there is marked cross-suppression within the Cav2 calcium channel family, there is no cross-suppression between Cav2 and Cav3 channels. The mechanism involves activation of a component of the unfolded protein response, the endoplasmic reticulum resident RNA-dependent kinase (PERK), because it is inhibited by expression of dominant-negative constructs of this kinase. Activation of PERK has been shown previously to cause translational arrest, which has the potential to result in a generalized effect on protein synthesis. In agreement with this, coexpression of the truncated domain I of Cav2.2, together with full-length Cav2.2, reduced the level not only of Cav2.2 protein but also the coexpressed α2δ-2. Thapsigargin, which globally activates the unfolded protein response, very markedly suppressed Cav2.2 currents and also reduced the expression level of both Cav2.2 and α2δ-2 protein. We propose that voltage-gated calcium channels represent a class of difficult-to-fold transmembrane proteins, in this case misfolding is induced by interaction with a truncated cognate Cav channel. This may represent a mechanism of pathology in episodic ataxia-2. [ABSTRACT FROM AUTHOR]

Published

2004

24. The Impact of Suppressive Surrounds on Chromatic Properties of Cortical Neurons.

Author

Solomon, Samuel G., Peirce, Jonathan W., and Lennie, Peter

Subjects

*NEURONS, *SURROUND-sound systems, *NERVOUS system, *SENSORY ganglia, *DIMENSIONS

Abstract

Stimulation of the suppressive surround of a cortical neuron affects the responsivity and tuning of the classical receptive field (CRF) on several stimulus dimensions. In V1 and V2 of macaques prepared for acute electrophysiological experiments, we explored the chromatic sensitivity of the surround and its influence on the chromatic tuning of the CRF. We studied receptive fields of single neurons with patches of drifting grating of optimal spatial frequency and orientation and variable size, modulated along achromatic or isoluminant color directions. The responses of most neurons declined as the patch was enlarged beyond the optimal size (surround suppression). In V1 the suppression evoked by isoluminant gratings was less than one-half that evoked by achromatic gratings. Consequently, many cells were most sensitive to achromatic modulation when patches just covered the CRF but were most sensitive to isoluminant modulation when patches were enlarged to cover the suppressive surround. Non-oriented neurons that were strongly chromatically opponent generally lacked suppressive surrounds. In V2 most neurons showed equal surround suppression from isoluminant gratings and achromatic gratings. This makes the relative sensitivity of V2 neurons to achromatic and isoluminant gratings mainly independent of the size of the grating. We also measured the chromatic properties of the CRF in the presence of differently colored surrounds. In neither V1 nor V2 did the surround alter the chromatic tuning of the CRF. Cortical mechanisms sensitive to chromatic contrast seem to provide little input to the suppressive surrounds of V1 neurons but substantial input to those of V2 neurons. [ABSTRACT FROM AUTHOR]

Published

2004

25. Nonlinear Integration of Sensory Responses in the Rat Barrel Cortex: An Intracellular Study In Vivo.

Author

Higley, Michael J. and Contreras, Diego

Subjects

*NEURONS, *CELLS, *NERVOUS system, *CEREBRAL cortex, *NEUROPLASTICITY

Abstract

To study integration of converging sensory inputs on single cortical neurons, we performed intracellular recordings in vivo in the barrel cortex of the barbiturate-anesthetized rat. We deflected the principal whisker (PW) for each cell either alone or preceded (at 20, 50, and 100 msec) by the deflection of a small number of remote whiskers (RWs) far from the PW. The synaptic responses to both the PW and the RW were similar qualitatively and consisted of excitation followed by inhibition that comprised an early and a late component. The RW response was of smaller amplitude and more often subthreshold for action potential generation. The main effect of the RW deflection was a suppression of the subsequent response to the PW that was most pronounced at the 20 msec interval and decreased progressively at the 50 and 100 msec intervals. Suppression of the spike output of the cell was not caused by hyperpolarization (subtractive inhibition) but by a reduction in the EPSP amplitude (divisive inhibition), resulting in a highly sublinear summation of the two responses. The small decrease in input resistance caused by the RW responses is not consistent with synaptic shunting as the main cause of the reduction of the EPSP amplitude. Instead, our results suggest that suppression results from a decrease in the amount of synaptic input triggered by the PW, particularly the early excitation. We suggest that this process involves a reduction in reverberant granular cell excitation that is induced by PW deflection. [ABSTRACT FROM AUTHOR]

Published

2003