Neurosystems: brain rhythms and cognitive processing

Neuronal rhythms are ubiquitous features of brain dynamics, and are highly correlated with cognitive processing. However, the relationship between the physiological mechanisms producing these rhythms and the functions associated with the rhythms remains mysterious. This article investigates the contributions of rhythms to basic cognitive computations (such as filtering signals by coherence and/or frequency) and to major cognitive functions (such as attention and multi-modal coordination). We offer support to the premise that the physiology underlying brain rhythms plays an essential role in how these rhythms facilitate some cognitive operations.098352 - Wellcome Trust; 5R01NS067199 - NINDS NIH HH

Consciousness CLEARS the Mind

A full understanding of consciouness requires that we identify the brain processes from which conscious experiences emerge. What are these processes, and what is their utility in supporting successful adaptive behaviors? Adaptive Resonance Theory (ART) predicted a functional link between processes of Consciousness, Learning, Expectation, Attention, Resonance, and Synchrony (CLEARS), includes the prediction that "all conscious states are resonant states." This connection clarifies how brain dynamics enable a behaving individual to autonomously adapt in real time to a rapidly changing world. The present article reviews theoretical considerations that predicted these functional links, how they work, and some of the rapidly growing body of behavioral and brain data that have provided support for these predictions. The article also summarizes ART models that predict functional roles for identified cells in laminar thalamocortical circuits, including the six layered neocortical circuits and their interactions with specific primary and higher-order specific thalamic nuclei and nonspecific nuclei. These prediction include explanations of how slow perceptual learning can occur more frequently in superficial cortical layers. ART traces these properties to the existence of intracortical feedback loops, and to reset mechanisms whereby thalamocortical mismatches use circuits such as the one from specific thalamic nuclei to nonspecific thalamic nuclei and then to layer 4 of neocortical areas via layers 1-to-5-to-6-to-4.National Science Foundation (SBE-0354378); Office of Naval Research (N00014-01-1-0624

Prominence of delta oscillatory rhythms in the motor cortex and their relevance for auditory and speech perception

In the motor cortex, beta oscillations (∼12-30 Hz) are generally considered a principal rhythm contributing to movement planning and execution. Beta oscillations cohabit and dynamically interact with slow delta oscillations (0.5-4 Hz), but the role of delta oscillations and the subordinate relationship between these rhythms in the perception-action loop remains unclear. Here, we review evidence that motor delta oscillations shape the dynamics of motor behaviors and sensorimotor processes, in particular during auditory perception. We describe the functional coupling between delta and beta oscillations in the motor cortex during spontaneous and planned motor acts. In an active sensing framework, perception is strongly shaped by motor activity, in particular in the delta band, which imposes temporal constraints on the sampling of sensory information. By encoding temporal contextual information, delta oscillations modulate auditory processing and impact behavioral outcomes. Finally, we consider the contribution of motor delta oscillations in the perceptual analysis of speech signals, providing a contextual temporal frame to optimize the parsing and processing of slow linguistic information

When do Bursts Matter in the Primary Motor Cortex? Investigating Changes in the Intermittencies of Beta Rhythms Associated With Movement States

Brain activity exhibits significant temporal structure that is not well captured in the power spectrum. Recently, attention has shifted to characterising the properties of intermittencies in rhythmic neural activity (i.e. bursts), yet the mechanisms regulating them are unknown. Here, we present evidence from electrocorticography recordings made from the motor cortex to show that the statistics of bursts, such as duration or amplitude, in beta frequency (14-30Hz) rhythms significantly aid the classification of motor states such as rest, movement preparation, execution, and imagery. These features reflect nonlinearities not detectable in the power spectrum, with states increasing in nonlinearity from movement execution to preparation to rest. Further, we show using a computational model of the cortical microcircuit, constrained to account for burst features, that modulations of laminar specific inhibitory interneurons are responsible for temporal organization of activity. Finally, we show that temporal characteristics of spontaneous activity can be used to infer the balance of cortical integration between incoming sensory information and endogenous activity. Critically, we contribute to the understanding of how transient brain rhythms may underwrite cortical processing, which in turn, could inform novel approaches for brain state classification, and modulation with novel brain-computer interfaces

Generating brain waves, the power of astrocytes

Synchronization of neuronal activity in the brain underlies the emergence of neuronal oscillations termed “brain waves”, which serve various physiological functions and correlate with different behavioral states. It has been postulated that at least ten distinct mechanisms are involved in the formulation of these brain waves, including variations in the concentration of extracellular neurotransmitters and ions, as well as changes in cellular excitability. In this mini review we highlight the contribution of astrocytes, a subtype of glia, in the formation and modulation of brain waves mainly due to their close association with synapses that allows their bidirectional interaction with neurons, and their syncytium-like activity via gap junctions that facilitate communication to distal brain regions through Ca2+ waves. These capabilities allow astrocytes to regulate neuronal excitability via glutamate uptake, gliotransmission and tight control of the extracellular K+ levels via a process termed K+ clearance. Spatio-temporal synchrony of activity across neuronal and astrocytic networks, both locally and distributed across cortical regions, underpins brain states and thereby behavioral states, and it is becoming apparent that astrocytes play an important role in the development and maintenance of neural activity underlying these complex behavioral states

Cholinergic modulation of auditory and prefrontal cortical interactions

Much of the previous work investigating the influence of cholinergic tone on cortical circuits has emphasized global states of arousal and local circuit dynamics; however the cholinergic system is well-suited to coordinate large-scale cortical interactions due to its diffuse cortically projecting arborization and diverse influence on the various cell types within the cortical microcircuit. In this thesis I examined the function of cortical cholinergic tone in supporting long-range cortical interactions, feed-forward sensory signaling, and active processing of behaviorally relevant stimuli. I utilized optogenetic stimulation and silencing of the cholinergic nucleus basalis while recording from the auditory-prefrontal cortical circuit as well as performing local drug infusions in awake mice. I demonstrate that prefrontal cortex actively responds to cortico-cortical sensory input in animals passively presented with acoustic stimuli and that muscarinic receptor binding within auditory cortex is essential for feedforward pathways from auditory cortex to transmit sensory related neural signals. Specifically, muscarinic antagonists applied to the auditory cortex disrupt sensory signaling within auditory cortex as well as bottom up signaling to prefrontal cortex. Furthermore, muscarinic antagonists attenuated the influence of cortical cholinergic release on recording channels closest to drug infusion, confirming the efficacy of muscarinic antagonism, and demonstrating that aspects of cholinergic modulation are locally generated within cortical circuits, while others are globally generated in large networks. In task performing animals, I observed that optogenetic silencing of cholinergic nucleus basalis neurons attenuates the magnitude of prefrontal cortex alpha power following correct behavioral choice and that alpha in prefrontal and auditory cortical local field potentials are actively involved in behavioral learning during extinction, suggesting that cholinergic tone is involved in maintaining and updating the value of stimuli across behavioral trials. In summary, my thesis supports a model where endogenous cholinergic signaling is an essential component of normal auditory processing during low attentive states, contributes to circuit activation through local and large network mechanisms, and supports essential cortical dynamics that contribute to active behavioral processing of stimuli

Acetylcholine neuromodulation in normal and abnormal learning and memory: vigilance control in waking, sleep, autism, amnesia, and Alzheimer's disease

This article provides a unified mechanistic neural explanation of how learning, recognition, and cognition break down during Alzheimer's disease, medial temporal amnesia, and autism. It also clarifies whey there are often sleep disturbances during these disorders. A key mechanism is how acetylcholine modules vigilance control in cortical layer

Brain State Dependent Activity in the Lateral Geniculate Nucleus

Brain state dependent thalamocortical (TC) activity plays and important role in sensory coding, oscillations and cognition. The lateral geniculate nucleus (LGN) relays visual information to the cortex, but the state dependent spontaneous and visually evoked activity of LGN neurons in awake behaving animals remains controversial. In awake head-restrained mice, using a combination of pupillometry, extracellular and intracellular recordings from morphologically and physiologically identified LGN neurons we show that TC neurons and putative local interneurons are inversely related to arousal forming two complementary coalitions with TC cells being positively correlates with wakefulness, while local interneuron activity is negatively correlated. Additionally, the orientation tuning of visually evoked thalamic cell responses is altered during various brain states. Intracellular recordings indicated that the membrane potential of LGN TC neurons was tightly correlated to fluctuations in pupil size. Inactivating the corticothalamic feedback by GABAA agonist muscimol applied on the dural surface significantly diminishes the correlation between brain states and thalamic neuronal activity. Additional investigations show that by photostimulating GABAergic axons (expressing Channelrhodopsin-2 in a Cre-dependent manner) that project from the lateral hypothalamus (LH) to the dorsal raphe nucleus (DRN), neurons in the DRN increase their action potential output, presumably through disinhibition. Taken together our results show that LGN neuronal membrane potential and action potential output are dynamically linked to arousal dependent brain states in awake mice and this fact might have important functional implications