Space representation for eye movements is more contralateral in monkeys than in humans

Contralateral hemispheric representation of sensory inputs (the right visual hemifield in the left hemisphere and vice versa) is a fundamental feature of primate sensorimotor organization, in particular the visuomotor system. However, many higher-order cognitive functions in humans show an asymmetric hemispheric lateralization—e.g., right brain specialization for spatial processing—necessitating a convergence of information from both hemifields. Electrophysiological studies in monkeys and functional imaging in humans have investigated space and action representations at different stages of visuospatial processing, but the transition from contralateral to unified global spatial encoding and the relationship between these encoding schemes and functional lateralization are not fully understood. Moreover, the integration of data across monkeys and humans and elucidation of interspecies homologies is hindered, because divergent findings may reflect actual species differences or arise from discrepancies in techniques and measured signals (electrophysiology vs. imaging). Here, we directly compared spatial cue and memory representations for action planning in monkeys and humans using event-related functional MRI during a working-memory oculomotor task. In monkeys, cue and memory-delay period activity in the frontal, parietal, and temporal regions was strongly contralateral. In putative human functional homologs, the contralaterality was significantly weaker, and the asymmetry between the hemispheres was stronger. These results suggest an inverse relationship between contralaterality and lateralization and elucidate similarities and differences in human and macaque cortical circuits subserving spatial awareness and oculomotor goal-directed actions

FMRI resting slow fluctuations correlate with the activity of fast cortico-cortical physiological connections

Recording of slow spontaneous fluctuations at rest using functional magnetic resonance imaging (fMRI) allows distinct long-range cortical networks to be identified. The neuronal basis of connectivity as assessed by resting-state fMRI still needs to be fully clarified, considering that these signals are an indirect measure of neuronal activity, reflecting slow local variations in de-oxyhaemoglobin concentration. Here, we combined fMRI with multifocal transcranial magnetic stimulation (TMS), a technique that allows the investigation of the causal neurophysiological interactions occurring in specific cortico-cortical connections. We investigated whether the physiological properties of parieto-frontal circuits mapped with short-latency multifocal TMS at rest may have some relationship with the resting-state fMRI measures of specific resting-state functional networks (RSNs). Results showed that the activity of fast cortico-cortical physiological interactions occurring in the millisecond range correlated selectively with the coupling of fMRI slow oscillations within the same cortical areas that form part of the dorsal attention network, i.e., the attention system believed to be involved in reorientation of attention. We conclude that resting-state fMRI ongoing slow fluctuations likely reflect the interaction of underlying physiological cortico-cortical connections

The Role of Alpha-Band Brain Oscillations as a Sensory Suppression Mechanism during Selective Attention

Evidence has amassed from both animal intracranial recordings and human electrophysiology that neural oscillatory mechanisms play a critical role in a number of cognitive functions such as learning, memory, feature binding and sensory gating. The wide availability of high-density electrical and magnetic recordings (64–256 channels) over the past two decades has allowed for renewed efforts in the characterization and localization of these rhythms. A variety of cognitive effects that are associated with specific brain oscillations have been reported, which range in spectral, temporal, and spatial characteristics depending on the context. Our laboratory has focused on investigating the role of alpha-band oscillatory activity (8–14 Hz) as a potential attentional suppression mechanism, and this particular oscillatory attention mechanism will be the focus of the current review. We discuss findings in the context of intersensory selective attention as well as intrasensory spatial and feature-based attention in the visual, auditory, and tactile domains. The weight of evidence suggests that alpha-band oscillations can be actively invoked within cortical regions across multiple sensory systems, particularly when these regions are involved in processing irrelevant or distracting information. That is, a central role for alpha seems to be as an attentional suppression mechanism when objects or features need to be specifically ignored or selected against

Intrinsic activity in the fly brain gates visual information during behavioral choices

The small insect brain is often described as an input/output system that executes reflex-like behaviors. It can also initiate neural activity and behaviors intrinsically, seen as spontaneous behaviors, different arousal states and sleep. However, less is known about how intrinsic activity in neural circuits affects sensory information processing in the insect brain and variability in behavior. Here, by simultaneously monitoring Drosophila's behavioral choices and brain activity in a flight simulator system, we identify intrinsic activity that is associated with the act of selecting between visual stimuli. We recorded neural output (multiunit action potentials and local field potentials) in the left and right optic lobes of a tethered flying Drosophila, while its attempts to follow visual motion (yaw torque) were measured by a torque meter. We show that when facing competing motion stimuli on its left and right, Drosophila typically generate large torque responses that flip from side to side. The delayed onset (0.1-1 s) and spontaneous switch-like dynamics of these responses, and the fact that the flies sometimes oppose the stimuli by flying straight, make this behavior different from the classic steering reflexes. Drosophila, thus, seem to choose one stimulus at a time and attempt to rotate toward its direction. With this behavior, the neural output of the optic lobes alternates; being augmented on the side chosen for body rotation and suppressed on the opposite side, even though the visual input to the fly eyes stays the same. Thus, the flow of information from the fly eyes is gated intrinsically. Such modulation can be noise-induced or intentional; with one possibility being that the fly brain highlights chosen information while ignoring the irrelevant, similar to what we know to occur in higher animals

The role of human motion processing complex, MT+, during sustained perception and attention

Thesis advisor: Scott D. SlotnickThe overarching aim of this dissertation is to examine the role of human motion processing complex, MT+ during sustained perception and attention. MT+ is comprised of sub-region MT, which processes motion in the contralateral visual field (i.e., left hemisphere MT processes motion in the right visual field and vice versa), and sub-region MST, which processes motion in both the contralateral and ipsilateral visual fields. Whereas previous transcranial magnetic stimulation (TMS) research has provided compelling evidence that region MT+ is necessary for low-level motion processing, Chapter 1 describes an experiment testing whether the sub-region MT is necessary for contralateral low-level motion processing. Chapter 2 describes an experiment that dissociates low-level sensory attentional modulation in MT+ from high-level attentional control processing in the parietal cortex (i.e., during sustained attention). Chapter 3 describes an experiment investigating the role of MT+ during aesthetic processing when viewing visual art. Importantly, this experiment tests whether the aesthetic is tied to not only low-level motion processing in MT+ but also high-level processing in frontal regions. Taken together, the results across the three experiments provide novel evidence for the role of MT+ during low-level motion processing during sustained perception and attention. Moreover, these low-level motion processing effects together with the observed high-level processes in frontal-parietal regions provide neural mechanisms for the cognitive processes of sustained perception and attention.Thesis (PhD) — Boston College, 2012.Submitted to: Boston College. Graduate School of Arts and Sciences.Discipline: Psychology

Population-scale organization of cerebellar granule neuron signaling during a visuomotor behavior.

Granule cells at the input layer of the cerebellum comprise over half the neurons in the human brain and are thought to be critical for learning. However, little is known about granule neuron signaling at the population scale during behavior. We used calcium imaging in awake zebrafish during optokinetic behavior to record transgenically identified granule neurons throughout a cerebellar population. A significant fraction of the population was responsive at any given time. In contrast to core precerebellar populations, granule neuron responses were relatively heterogeneous, with variation in the degree of rectification and the balance of positive versus negative changes in activity. Functional correlations were strongest for nearby cells, with weak spatial gradients in the degree of rectification and the average sign of response. These data open a new window upon cerebellar function and suggest granule layer signals represent elementary building blocks under-represented in core sensorimotor pathways, thereby enabling the construction of novel patterns of activity for learning

Funzioni di alto livello nella corteccia somatosensoriale secondaria (SII)

Le proprietà della corteccia somato-sensoriale secondaria (SII) sono state largamente discusse in molteplici studi sia nella scimmia, sia nell’uomo, suggerendo che quest’area assolva funzioni di alto livello nel processamento dello stimolo tattile, quali, ad esempio, l’apprendimento o la memoria. Recentemente, alcuni studi su scimmia hanno evidenziato che, oltre agli stimoli somato-sensoriali, SII risponde anche alla stimolazione dello spazio peri-personale, all’esecuzione di azioni, alla vista di oggetti in movimento ed all’osservazione di azioni, candidando SII ad essere un’area complessa, non limitata a sole funzioni somato-sensoriali. Partendo dallo studio delle risposte di SII agli stimoli tattili, lo scopo di questa tesi è di investigare la risposta di quest’area a stimoli complessi, con particolare attenzione a task di integrazione visuo-tattile e all’osservazione di azioni nell’uomo. Con queste finalità, gli esperimenti presentati sono stati condotti mediante elettroencefalografia stereotassica (stereo-EEG) su pazienti epilettici farmaco-resistenti, impiantati come parte della loro valutazione pre-chirurgica. In una prima fase, sono stati studiati la distribuzione spaziale ed il profilo temporale delle risposte intra-corticali alla stimolazione del nervo mediano controlaterale ed ipsilaterale. I risultati ottenuti indicano che mentre la corteccia somato-sensoriale primaria (SI), il giro precentrale ed il solco intra-parietale rispondono solo alla stimolazione controlaterale, la corteccia somato-sensoriale secondaria e l’insula posteriore sono attivate bilateralmente. Inoltre, queste ultime sono caratterizzate da una risposta tonica e duratura nel tempo. Questa potrebbe rappresentare un meccanismo di ritenzione temporale dell’informazione tattile ed essere l’espressione di funzioni di alto livello quali appunto la memoria e l’apprendimento degli stimoli. Nella seconda sezione della tesi, per testare il possibile coinvolgimento dell’opercolo parietale nell’integrazione visuo-tattile, la stimolazione del nervo mediano controlaterale è stata somministrata congiuntamente ad una stimolazione visiva (i.e. flash). I risultati ottenuti evidenziano un aumento in ampiezza della componente tonica, se comparato alla sola stimolazione tattile, localizzato nell’insula posteriore e nelle porzioni più rostrali dell’opercolo parietale mentre SII mostra un comportamento del tutto inalterato. Tuttavia, tenendo in considerazione che studi su primati non umani riportano risposte visiva in SII a stimoli biologici, sono necessarie ulteriori indagini per comprendere quale tipologia di stimolazione determina l’attivazione di quest’area. Infine, la terza parte della tesi mostra le risposte intra-corticali di SI e SII ad un task motorio che include compiti di afferramento e manipolazione di oggetti, e all’osservazione delle stesse azioni eseguite da un altro individuo. I risultati evidenziano un’attivazione bilaterale di SII, sia durante l’esecuzione sia durante l’osservazione di azioni, con un profilo temporale sincrono. Al contrario SI è attiva solo durante l’esecuzione: l’input a SI durante l’osservazione non ha dunque una natura somato-sensoriale ma piuttosto deve essere sostenuto da un circuito visuo-motorio capace di operare in maniera simultanea. In conclusione, questa tesi dimostra il ruolo cruciale di SII non solo nel processamento degli stimoli tattili ma anche nell’integrazione di stimoli visuo-motori.The somatosensory properties of the second somatosensory cortex (SII) have been largely described by many studies in both monkeys and humans, suggesting for this area a high-order role in tactile stimulation processing with functions including tactile learning and memory. More interestingly, recent studies on monkeys showed that beyond somatosensory stimuli, SII responds to a wider number of stimuli including peripersonal space stimulation, active movements, observation of objects displacement and action observation. Taking into account these results, SII is a candidate to be more than just a somatosensory area. Starting from its somatosensory properties, this thesis aims to disentangle the role of SII in more complex tasks with particular attention to visuo-tactile integration and action observation in humans. To this purpose, the experiments presented in this thesis are carried with stereotactic electroencephalography (stereo-EEG) on drug-resistant epileptic patients to take advantage of its high temporal and spatial resolution. Firstly, I investigated the spatial distribution and the temporal profile of the intracortical responses to both contralateral and ipsilateral median nerve stimulation. Results indicated that while the primary somatosensory area, precentral gyrus and intra-parietal sulcus respond only to the contralateral stimulation, the secondary somatosensory cortex and posterior insula are activated bilaterally. Furthermore, these regions exhibit a tonic long-lasting temporal profile, which might represent a mechanism of temporal retention of the tactile information, and thus be the signature of high-level somatosensory functions such as tactile memory and awareness. In a second stage of the thesis, to test the possible involvement of parietal operculum in visuo-tactile integration, we administered to patients contralateral median nerve stimulation jointly with visual stimulation (i.e. flash) to about 100 drug-resistant epileptic patients. Results underline an enhancement of the tonic components relative to tactile stimulation only, limited to posterior insula and to the rostral areas of parietal operculum, with SII maintaining an unaltered behavior. Considering previous findings in non-human primates, which reported visual responses in SII in response to biological stimuli, further researches are needed to understand which threshold in the stimulus might determine the eventual activation of this area. With this aim, the third part of this thesis presents the intracortical responses of both SI and SII to a motor task requiring reaching, grasping and manipulation, as well as to the observation of the same actions performed by another individual. The results obtained highlighted that SII activates bilaterally, both during the execution and the observation of actions, with a synchronous temporal profile. Conversely, SI activates only during the execution, leading to the conclusion that the input to SII during the observation condition has not a somatosensory nature, but rather that it is sustained by visuo-motor circuits operating simultaneously. Taking together all the evidence, this thesis demonstrates the pivotal role of SII not only in somatosensory functions, as largely reported in literature, but also in the integration of visuo-motor stimuli

Neuromodulatory control of localized dendritic spiking in critical period cortex.

Sensory experience in early postnatal life, during so-called critical periods, restructures neural circuitry to enhance information processing1. Why the cortex is susceptible to sensory instruction in early life and why this susceptibility wanes with age are unclear. Here we define a developmentally restricted engagement of inhibitory circuitry that shapes localized dendritic activity and is needed for vision to drive the emergence of binocular visual responses in the mouse primary visual cortex. We find that at the peak of the critical period for binocular plasticity, acetylcholine released from the basal forebrain during periods of heightened arousal directly excites somatostatin (SST)-expressing interneurons. Their inhibition of pyramidal cell dendrites and of fast-spiking, parvalbumin-expressing interneurons enhances branch-specific dendritic responses and somatic spike rates within pyramidal cells. By adulthood, this cholinergic sensitivity is lost, and compartmentalized dendritic responses are absent but can be re-instated by optogenetic activation of SST cells. Conversely, suppressing SST cell activity during the critical period prevents the normal development of binocular receptive fields by impairing the maturation of ipsilateral eye inputs. This transient cholinergic modulation of SST cells, therefore, seems to orchestrate two features of neural plasticity-somatic disinhibition and compartmentalized dendritic spiking. Loss of this modulation may contribute to critical period closure