Your search keyword '"Krishnan, Giri P."' showing total 22 results

1. Satiety Associated with Calorie Restriction and Time-Restricted Feeding: Central Neuroendocrine Integration.

Author

Tacad, Debra KM, Tacad, Debra KM, Tovar, Ashley P, Richardson, Christine E, Horn, William F, Keim, Nancy L, Krishnan, Giri P, Krishnan, Sridevi, Tacad, Debra KM, Tacad, Debra KM, Tovar, Ashley P, Richardson, Christine E, Horn, William F, Keim, Nancy L, Krishnan, Giri P, and Krishnan, Sridevi

Abstract

This review focuses on summarizing current knowledge on how time-restricted feeding (TRF) and continuous caloric restriction (CR) affect central neuroendocrine systems involved in regulating satiety. Several interconnected regions of the hypothalamus, brainstem, and cortical areas of the brain are involved in the regulation of satiety. Following CR and TRF, the increase in hunger and reduction in satiety signals of the melanocortin system [neuropeptide Y (NPY), proopiomelanocortin (POMC), and agouti-related peptide (AgRP)] appear similar between CR and TRF protocols, as do the dopaminergic responses in the mesocorticolimbic circuit. However, ghrelin and leptin signaling via the melanocortin system appears to improve energy balance signals and reduce hyperphagia following TRF, which has not been reported in CR. In addition to satiety systems, CR and TRF also influence circadian rhythms. CR influences the suprachiasmatic nucleus (SCN) or the primary circadian clock as seen by increased clock gene expression. In contrast, TRF appears to affect both the SCN and the peripheral clocks, as seen by phasic changes in the non-SCN (potentially the elusive food entrainable oscillator) and metabolic clocks. The peripheral clocks are influenced by the primary circadian clock but are also entrained by food timing, sleep timing, and other lifestyle parameters, which can supersede the metabolic processes that are regulated by the primary circadian clock. Taken together, TRF influences hunger/satiety, energy balance systems, and circadian rhythms, suggesting a role for adherence to CR in the long run if implemented using the TRF approach. However, these suggestions are based on only a few studies, and future investigations that use standardized protocols for the evaluation of the effect of these diet patterns (time, duration, meal composition, sufficiently powered) are necessary to verify these preliminary observations.

Published

2022

2. Satiety Associated with Calorie Restriction and Time-Restricted Feeding: Peripheral Hormones.

Author

Tacad, Debra KM, Tacad, Debra KM, Tovar, Ashley P, Richardson, Christine E, Horn, William F, Krishnan, Giri P, Keim, Nancy L, Krishnan, Sridevi, Tacad, Debra KM, Tacad, Debra KM, Tovar, Ashley P, Richardson, Christine E, Horn, William F, Krishnan, Giri P, Keim, Nancy L, and Krishnan, Sridevi

Abstract

Calorie restriction (CR) is a common approach to inducing negative energy balance. Recently, time-restricted feeding (TRF), which involves consuming food within specific time windows during a 24-h day, has become popular owing to its relative ease of practice and potential to aid in achieving and maintaining a negative energy balance. TRF can be implemented intentionally with CR, or TRF might induce CR simply because of the time restriction. This review focuses on summarizing our current knowledge on how TRF and continuous CR affect gut peptides that influence satiety. Based on peer-reviewed studies, in response to CR there is an increase in the orexigenic hormone ghrelin and a reduction in fasting leptin and insulin. There is likely a reduction in glucagon-like peptide-1 (GLP-1), peptide YY (PYY), and cholecystokinin (CCK), albeit the evidence for this is weak. After TRF, unlike CR, fasting ghrelin decreased in some TRF studies, whereas it showed no change in several others. Further, a reduction in fasting leptin, insulin, and GLP-1 has been observed. In conclusion, when other determinants of food intake are held equal, the peripheral satiety systems appear to be somewhat similarly affected by CR and TRF with regard to leptin, insulin, and GLP-1. But unlike CR, TRF did not appear to robustly increase ghrelin, suggesting different influences on appetite with a potential decrease of hunger after TRF when compared with CR. However, there are several established and novel gut peptides that have not been measured within the context of CR and TRF, and studies that have evaluated effects of TRF are often short-term, with nonuniform study designs and highly varying temporal eating patterns. More evidence and studies addressing these aspects are needed to draw definitive conclusions.

Published

2022

3. Sleep-like unsupervised replay reduces catastrophic forgetting in artificial neural networks.

Author

Tadros, Timothy, Tadros, Timothy, Krishnan, Giri P, Ramyaa, Ramyaa, Bazhenov, Maxim, Tadros, Timothy, Tadros, Timothy, Krishnan, Giri P, Ramyaa, Ramyaa, and Bazhenov, Maxim

Abstract

Artificial neural networks are known to suffer from catastrophic forgetting: when learning multiple tasks sequentially, they perform well on the most recent task at the expense of previously learned tasks. In the brain, sleep is known to play an important role in incremental learning by replaying recent and old conflicting memory traces. Here we tested the hypothesis that implementing a sleep-like phase in artificial neural networks can protect old memories during new training and alleviate catastrophic forgetting. Sleep was implemented as off-line training with local unsupervised Hebbian plasticity rules and noisy input. In an incremental learning framework, sleep was able to recover old tasks that were otherwise forgotten. Previously learned memories were replayed spontaneously during sleep, forming unique representations for each class of inputs. Representational sparseness and neuronal activity corresponding to the old tasks increased while new task related activity decreased. The study suggests that spontaneous replay simulating sleep-like dynamics can alleviate catastrophic forgetting in artificial neural networks.

Published

2022

4. Replay in Deep Learning: Current Approaches and Missing Biological Elements

Author

Hayes, Tyler L., Krishnan, Giri P., Bazhenov, Maxim, Siegelmann, Hava T., Sejnowski, Terrence J., Kanan, Christopher, Hayes, Tyler L., Krishnan, Giri P., Bazhenov, Maxim, Siegelmann, Hava T., Sejnowski, Terrence J., and Kanan, Christopher

Abstract

Replay is the reactivation of one or more neural patterns, which are similar to the activation patterns experienced during past waking experiences. Replay was first observed in biological neural networks during sleep, and it is now thought to play a critical role in memory formation, retrieval, and consolidation. Replay-like mechanisms have been incorporated into deep artificial neural networks that learn over time to avoid catastrophic forgetting of previous knowledge. Replay algorithms have been successfully used in a wide range of deep learning methods within supervised, unsupervised, and reinforcement learning paradigms. In this paper, we provide the first comprehensive comparison between replay in the mammalian brain and replay in artificial neural networks. We identify multiple aspects of biological replay that are missing in deep learning systems and hypothesize how they could be utilized to improve artificial neural networks., Comment: Accepted for publication in the MIT Press journal of Neural Computation

Published

2021

5. Origin of slow spontaneous resting-state neuronal fluctuations in brain networks.

Author

Krishnan, Giri P, Krishnan, Giri P, González, Oscar C, Bazhenov, Maxim, Krishnan, Giri P, Krishnan, Giri P, González, Oscar C, and Bazhenov, Maxim

Abstract

Resting- or baseline-state low-frequency (0.01-0.2 Hz) brain activity is observed in fMRI, EEG, and local field potential recordings. These fluctuations were found to be correlated across brain regions and are thought to reflect neuronal activity fluctuations between functionally connected areas of the brain. However, the origin of these infra-slow resting-state fluctuations remains unknown. Here, using a detailed computational model of the brain network, we show that spontaneous infra-slow (<0.05 Hz) activity could originate due to the ion concentration dynamics. The computational model implemented dynamics for intra- and extracellular K+ and Na+ and intracellular Cl- ions, Na+/K+ exchange pump, and KCC2 cotransporter. In the network model simulating resting awake-like brain state, we observed infra-slow fluctuations in the extracellular K+ concentration, Na+/K+ pump activation, firing rate of neurons, and local field potentials. Holding K+ concentration constant prevented generation of the infra-slow fluctuations. The amplitude and peak frequency of this activity were modulated by the Na+/K+ pump, AMPA/GABA synaptic currents, and glial properties. Further, in a large-scale network with long-range connections based on CoCoMac connectivity data, the infra-slow fluctuations became synchronized among remote clusters similar to the resting-state activity observed in vivo. Overall, our study proposes that ion concentration dynamics mediated by neuronal and glial activity may contribute to the generation of very slow spontaneous fluctuations of brain activity that are reported as the resting-state fluctuations in fMRI and EEG recordings.

Published

2018

6. Timing between Cortical Slow Oscillations and Heart Rate Bursts during Sleep Predicts Temporal Processing Speed, but Not Offline Consolidation.

Author

Naji, Mohsen, Naji, Mohsen, Krishnan, Giri P, McDevitt, Elizabeth A, Bazhenov, Maxim, Mednick, Sara C, Naji, Mohsen, Naji, Mohsen, Krishnan, Giri P, McDevitt, Elizabeth A, Bazhenov, Maxim, and Mednick, Sara C

Abstract

Central and autonomic nervous system activities are coupled during sleep. Cortical slow oscillations (SOs; <1 Hz) coincide with brief bursts in heart rate (HR), but the functional consequence of this coupling in cognition remains elusive. We measured SO-HR temporal coupling (i.e., the peak-to-peak interval between downstate of SO event and HR burst) during a daytime nap and asked whether this SO-HR timing measure was associated with temporal processing speed and learning on a texture discrimination task by testing participants before and after a nap. The coherence of SO-HR events during sleep strongly correlated with an individual's temporal processing speed in the morning and evening test sessions, but not with their change in performance after the nap (i.e., consolidation). We confirmed this result in two additional experimental visits and also discovered that this association was visit-specific, indicating a state (not trait) marker. Thus, we introduce a novel physiological index that may be a useful marker of state-dependent processing speed of an individual.

Published

2019

7. Timing between Cortical Slow Oscillations and Heart Rate Bursts during Sleep Predicts Temporal Processing Speed, but Not Offline Consolidation.

Author

Naji, Mohsen, Naji, Mohsen, Krishnan, Giri P, McDevitt, Elizabeth A, Bazhenov, Maxim, Mednick, Sara C, Naji, Mohsen, Naji, Mohsen, Krishnan, Giri P, McDevitt, Elizabeth A, Bazhenov, Maxim, and Mednick, Sara C

Abstract

Central and autonomic nervous system activities are coupled during sleep. Cortical slow oscillations (SOs; <1 Hz) coincide with brief bursts in heart rate (HR), but the functional consequence of this coupling in cognition remains elusive. We measured SO-HR temporal coupling (i.e., the peak-to-peak interval between downstate of SO event and HR burst) during a daytime nap and asked whether this SO-HR timing measure was associated with temporal processing speed and learning on a texture discrimination task by testing participants before and after a nap. The coherence of SO-HR events during sleep strongly correlated with an individual's temporal processing speed in the morning and evening test sessions, but not with their change in performance after the nap (i.e., consolidation). We confirmed this result in two additional experimental visits and also discovered that this association was visit-specific, indicating a state (not trait) marker. Thus, we introduce a novel physiological index that may be a useful marker of state-dependent processing speed of an individual.

Published

2019

8. Timing between Cortical Slow Oscillations and Heart Rate Bursts during Sleep Predicts Temporal Processing Speed, but Not Offline Consolidation.

Author

Naji, Mohsen, Naji, Mohsen, Krishnan, Giri P, McDevitt, Elizabeth A, Bazhenov, Maxim, Mednick, Sara C, Naji, Mohsen, Naji, Mohsen, Krishnan, Giri P, McDevitt, Elizabeth A, Bazhenov, Maxim, and Mednick, Sara C

Abstract

Central and autonomic nervous system activities are coupled during sleep. Cortical slow oscillations (SOs; <1 Hz) coincide with brief bursts in heart rate (HR), but the functional consequence of this coupling in cognition remains elusive. We measured SO-HR temporal coupling (i.e., the peak-to-peak interval between downstate of SO event and HR burst) during a daytime nap and asked whether this SO-HR timing measure was associated with temporal processing speed and learning on a texture discrimination task by testing participants before and after a nap. The coherence of SO-HR events during sleep strongly correlated with an individual's temporal processing speed in the morning and evening test sessions, but not with their change in performance after the nap (i.e., consolidation). We confirmed this result in two additional experimental visits and also discovered that this association was visit-specific, indicating a state (not trait) marker. Thus, we introduce a novel physiological index that may be a useful marker of state-dependent processing speed of an individual.

Published

2019

9. Ionic and synaptic mechanisms of seizure generation and epileptogenesis.

Author

González, Oscar C, González, Oscar C, Krishnan, Giri P, Timofeev, Igor, Bazhenov, Maxim, González, Oscar C, González, Oscar C, Krishnan, Giri P, Timofeev, Igor, and Bazhenov, Maxim

Abstract

The biophysical mechanisms underlying epileptogenesis and the generation of seizures remain to be better understood. Among many factors triggering epileptogenesis are traumatic brain injury breaking normal synaptic homeostasis and genetic mutations disrupting ionic concentration homeostasis. Impairments in these mechanisms, as seen in various brain diseases, may push the brain network to a pathological state characterized by increased susceptibility to unprovoked seizures. Here, we review recent computational studies exploring the roles of ionic concentration dynamics in the generation, maintenance, and termination of seizures. We further discuss how ionic and synaptic homeostatic mechanisms may give rise to conditions which prime brain networks to exhibit recurrent spontaneous seizures and epilepsy.

Published

2019

10. Coupling of autonomic and central events during sleep benefits declarative memory consolidation.

Author

Naji, Mohsen, Naji, Mohsen, Krishnan, Giri P, McDevitt, Elizabeth A, Bazhenov, Maxim, Mednick, Sara C, Naji, Mohsen, Naji, Mohsen, Krishnan, Giri P, McDevitt, Elizabeth A, Bazhenov, Maxim, and Mednick, Sara C

Abstract

While anatomical pathways between forebrain cognitive and brainstem autonomic nervous centers are well-defined, autonomic-central interactions during sleep and their contribution to waking performance are not understood. Here, we analyzed simultaneous central activity via electroencephalography (EEG) and autonomic heart beat-to-beat intervals (RR intervals) from electrocardiography (ECG) during wake and daytime sleep. We identified bursts of ECG activity that lasted 4-5 s and predominated in non-rapid-eye-movement sleep (NREM). Using event-based analysis of NREM sleep, we found an increase in delta (0.5-4 Hz) and sigma (12-15 Hz) power and an elevated density of slow oscillations (0.5-1 Hz) about 5 s prior to peak of the heart rate burst, as well as a surge in vagal activity, assessed by high-frequency (HF) component of RR intervals. Using regression framework, we show that these Autonomic/Central Events (ACE) positively predicted post-nap improvement in a declarative memory task after controlling for the effects of spindles and slow oscillations from sleep periods without ACE. No such relation was found between memory performance and a control nap. Additionally, NREM ACE negatively correlated with REM sleep and learning in a non-declarative memory task. These results provide the first evidence that coordinated autonomic and central events play a significant role in declarative memory consolidation.

Published

2019

11. Biologically inspired sleep algorithm for artificial neural networks

Author

Krishnan, Giri P, Tadros, Timothy, Ramyaa, Ramyaa, Bazhenov, Maxim, Krishnan, Giri P, Tadros, Timothy, Ramyaa, Ramyaa, and Bazhenov, Maxim

Abstract

Sleep plays an important role in incremental learning and consolidation of memories in biological systems. Motivated by the processes that are known to be involved in sleep generation in biological networks, we developed an algorithm that implements a sleep-like phase in artificial neural networks (ANNs). After initial training phase, we convert the ANN to a spiking neural network (SNN) and simulate an offline sleep-like phase using spike-timing dependent plasticity rules to modify synaptic weights. The SNN is then converted back to the ANN and evaluated or trained on new inputs. We demonstrate several performance improvements after applying this processing to ANNs trained on MNIST, CUB200 and a motivating toy dataset. First, in an incremental learning framework, sleep is able to recover older tasks that were otherwise forgotten in the ANN without sleep phase due to catastrophic forgetting. Second, sleep results in forward transfer learning of unseen tasks. Finally, sleep improves generalization ability of the ANNs to classify images with various types of noise. We provide a theoretical basis for the beneficial role of the brain-inspired sleep-like phase for the ANNs and present an algorithmic way for future implementations of the various features of sleep in deep learning ANNs. Overall, these results suggest that biological sleep can help mitigate a number of problems ANNs suffer from, such as poor generalization and catastrophic forgetting for incremental learning.

Published

2019

12. Cellular and neurochemical basis of sleep stages in the thalamocortical network.

Author

Krishnan, Giri P, Krishnan, Giri P, Chauvette, Sylvain, Shamie, Isaac, Soltani, Sara, Timofeev, Igor, Cash, Sydney S, Halgren, Eric, Bazhenov, Maxim, Krishnan, Giri P, Krishnan, Giri P, Chauvette, Sylvain, Shamie, Isaac, Soltani, Sara, Timofeev, Igor, Cash, Sydney S, Halgren, Eric, and Bazhenov, Maxim

Abstract

The link between the combined action of neuromodulators in the brain and global brain states remains a mystery. In this study, using biophysically realistic models of the thalamocortical network, we identified the critical intrinsic and synaptic mechanisms, associated with the putative action of acetylcholine (ACh), GABA and monoamines, which lead to transitions between primary brain vigilance states (waking, non-rapid eye movement sleep [NREM] and REM sleep) within an ultradian cycle. Using ECoG recordings from humans and LFP recordings from cats and mice, we found that during NREM sleep the power of spindle and delta oscillations is negatively correlated in humans and positively correlated in animal recordings. We explained this discrepancy by the differences in the relative level of ACh. Overall, our study revealed the critical intrinsic and synaptic mechanisms through which different neuromodulators acting in combination result in characteristic brain EEG rhythms and transitions between sleep stages.

Published

2016

13. Cellular and neurochemical basis of sleep stages in the thalamocortical network.

Author

Krishnan, Giri P, Krishnan, Giri P, Chauvette, Sylvain, Shamie, Isaac, Soltani, Sara, Timofeev, Igor, Cash, Sydney S, Halgren, Eric, Bazhenov, Maxim, Krishnan, Giri P, Krishnan, Giri P, Chauvette, Sylvain, Shamie, Isaac, Soltani, Sara, Timofeev, Igor, Cash, Sydney S, Halgren, Eric, and Bazhenov, Maxim

Abstract

The link between the combined action of neuromodulators in the brain and global brain states remains a mystery. In this study, using biophysically realistic models of the thalamocortical network, we identified the critical intrinsic and synaptic mechanisms, associated with the putative action of acetylcholine (ACh), GABA and monoamines, which lead to transitions between primary brain vigilance states (waking, non-rapid eye movement sleep [NREM] and REM sleep) within an ultradian cycle. Using ECoG recordings from humans and LFP recordings from cats and mice, we found that during NREM sleep the power of spindle and delta oscillations is negatively correlated in humans and positively correlated in animal recordings. We explained this discrepancy by the differences in the relative level of ACh. Overall, our study revealed the critical intrinsic and synaptic mechanisms through which different neuromodulators acting in combination result in characteristic brain EEG rhythms and transitions between sleep stages.

Published

2016

14. Computational model of brain-stem circuit for state-dependent control of hypoglossal motoneurons.

Author

Naji, Mohsen, Naji, Mohsen, Komarov, Maxim, Krishnan, Giri P, Malhotra, Atul, Powell, Frank L, Rukhadze, Irma, Fenik, Victor B, Bazhenov, Maxim, Naji, Mohsen, Naji, Mohsen, Komarov, Maxim, Krishnan, Giri P, Malhotra, Atul, Powell, Frank L, Rukhadze, Irma, Fenik, Victor B, and Bazhenov, Maxim

Abstract

In patients with obstructive sleep apnea (OSA), the pharyngeal muscles become relaxed during sleep, which leads to a partial or complete closure of upper airway. Experimental studies suggest that withdrawal of noradrenergic and serotonergic drives importantly contributes to depression of hypoglossal motoneurons and, therefore, may contribute to OSA pathophysiology; however, specific cellular and synaptic mechanisms remain unknown. In this new study, we developed a biophysical network model to test the hypothesis that, to explain experimental observations, the neuronal network for monoaminergic control of excitability of hypoglossal motoneurons needs to include excitatory and inhibitory perihypoglossal interneurons that mediate noradrenergic and serotonergic drives to hypoglossal motoneurons. In the model, the state-dependent activation of the hypoglossal motoneurons was in qualitative agreement with in vivo data during simulated rapid eye movement (REM) and non-REM sleep. The model was applied to test the mechanisms of action of noradrenergic and serotonergic drugs during REM sleep as observed in vivo. We conclude that the proposed minimal neuronal circuit is sufficient to explain in vivo data and supports the hypothesis that perihypoglossal interneurons may mediate state-dependent monoaminergic drive to hypoglossal motoneurons. The population of the hypothesized perihypoglossal interneurons may serve as novel targets for pharmacological treatment of OSA. NEW & NOTEWORTHY In vivo studies suggest that during rapid eye movement sleep, withdrawal of noradrenergic and serotonergic drives critically contributes to depression of hypoglossal motoneurons (HMs), which innervate the tongue muscles. By means of a biophysical model, which is consistent with a broad range of empirical data, we demonstrate that the neuronal network controlling the excitability of HMs needs to include excitatory and inhibitory interneurons that mediate noradrenergic and serotonergic drives to

Published

2018

15. Computational model of brain-stem circuit for state-dependent control of hypoglossal motoneurons.

Author

Naji, Mohsen, Naji, Mohsen, Komarov, Maxim, Krishnan, Giri P, Malhotra, Atul, Powell, Frank L, Rukhadze, Irma, Fenik, Victor B, Bazhenov, Maxim, Naji, Mohsen, Naji, Mohsen, Komarov, Maxim, Krishnan, Giri P, Malhotra, Atul, Powell, Frank L, Rukhadze, Irma, Fenik, Victor B, and Bazhenov, Maxim

Abstract

In patients with obstructive sleep apnea (OSA), the pharyngeal muscles become relaxed during sleep, which leads to a partial or complete closure of upper airway. Experimental studies suggest that withdrawal of noradrenergic and serotonergic drives importantly contributes to depression of hypoglossal motoneurons and, therefore, may contribute to OSA pathophysiology; however, specific cellular and synaptic mechanisms remain unknown. In this new study, we developed a biophysical network model to test the hypothesis that, to explain experimental observations, the neuronal network for monoaminergic control of excitability of hypoglossal motoneurons needs to include excitatory and inhibitory perihypoglossal interneurons that mediate noradrenergic and serotonergic drives to hypoglossal motoneurons. In the model, the state-dependent activation of the hypoglossal motoneurons was in qualitative agreement with in vivo data during simulated rapid eye movement (REM) and non-REM sleep. The model was applied to test the mechanisms of action of noradrenergic and serotonergic drugs during REM sleep as observed in vivo. We conclude that the proposed minimal neuronal circuit is sufficient to explain in vivo data and supports the hypothesis that perihypoglossal interneurons may mediate state-dependent monoaminergic drive to hypoglossal motoneurons. The population of the hypothesized perihypoglossal interneurons may serve as novel targets for pharmacological treatment of OSA. NEW & NOTEWORTHY In vivo studies suggest that during rapid eye movement sleep, withdrawal of noradrenergic and serotonergic drives critically contributes to depression of hypoglossal motoneurons (HMs), which innervate the tongue muscles. By means of a biophysical model, which is consistent with a broad range of empirical data, we demonstrate that the neuronal network controlling the excitability of HMs needs to include excitatory and inhibitory interneurons that mediate noradrenergic and serotonergic drives to

Published

2018

16. Role of KCC2-dependent potassium efflux in 4-Aminopyridine-induced Epileptiform synchronization.

Author

González, Oscar C, González, Oscar C, Shiri, Zahra, Krishnan, Giri P, Myers, Timothy L, Williams, Sylvain, Avoli, Massimo, Bazhenov, Maxim, González, Oscar C, González, Oscar C, Shiri, Zahra, Krishnan, Giri P, Myers, Timothy L, Williams, Sylvain, Avoli, Massimo, and Bazhenov, Maxim

Abstract

A balance between excitation and inhibition is necessary to maintain stable brain network dynamics. Traditionally, seizure activity is believed to arise from the breakdown of this delicate balance in favor of excitation with loss of inhibition. Surprisingly, recent experimental evidence suggests that this conventional view may be limited, and that inhibition plays a prominent role in the development of epileptiform synchronization. Here, we explored the role of the KCC2 co-transporter in the onset of inhibitory network-induced seizures. Our experiments in acute mouse brain slices, of either sex, revealed that optogenetic stimulation of either parvalbumin- or somatostatin-expressing interneurons induced ictal discharges in rodent entorhinal cortex during 4-aminopyridine application. These data point to a proconvulsive role of GABAA receptor signaling that is independent of the inhibitory input location (i.e., dendritic vs. somatic). We developed a biophysically realistic network model implementing dynamics of ion concentrations to explore the mechanisms leading to inhibitory network-induced seizures. In agreement with experimental results, we found that stimulation of the inhibitory interneurons induced seizure-like activity in a network with reduced potassium A-current. Our model predicts that interneuron stimulation triggered an increase of interneuron firing, which was accompanied by an increase in the intracellular chloride concentration and a subsequent KCC2-dependent gradual accumulation of the extracellular potassium promoting epileptiform ictal activity. When the KCC2 activity was reduced, stimulation of the interneurons was no longer able to induce ictal events. Overall, our study provides evidence for a proconvulsive role of GABAA receptor signaling that depends on the involvement of the KCC2 co-transporter.

Published

2018

17. Cellular and neurochemical basis of sleep stages in the thalamocortical network

Author

Krishnan, Giri P., Soltani, Sara, Timofeev, Igor, Shamie, Issac, Chauvette, Sylvain, Cash, Sydney S., Halgren, Eric, Bazhenov, Maxim, Krishnan, Giri P., Soltani, Sara, Timofeev, Igor, Shamie, Issac, Chauvette, Sylvain, Cash, Sydney S., Halgren, Eric, and Bazhenov, Maxim

Abstract

The link between the combined action of neuromodulators in the brain and global brain states remains a mystery. In this study, using biophysically realistic models of the thalamocortical network, we identified the critical intrinsic and synaptic mechanisms, associated with the putative action of acetylcholine (ACh), GABA and monoamines, which lead to transitions between primary brain vigilance states (waking, non-rapid eye movement sleep [NREM] and REM sleep) within an ultradian cycle. Using ECoG recordings from humans and LFP recordings from cats and mice, we found that during NREM sleep the power of spindle and delta oscillations is negatively correlated in humans and positively correlated in animal recordings. We explained this discrepancy by the differences in the relative level of ACh. Overall, our study revealed the critical intrinsic and synaptic mechanisms through which different neuromodulators acting in combination result in characteristic brain EEG rhythms and transitions between sleep stages

Published

2017

18. Modeling of age-dependent epileptogenesis by differential homeostatic synaptic scaling

Author

González, Oscar C., Timofeev, Igor, Krishnan, Giri P., Chauvette, Sylvain, Sejnowski, Terrence J., Bazhenov, Maxim, González, Oscar C., Timofeev, Igor, Krishnan, Giri P., Chauvette, Sylvain, Sejnowski, Terrence J., and Bazhenov, Maxim

Abstract

Homeostatic synaptic plasticity (HSP) has been implicated in the development of hyperexcitability and epileptic seizures following traumatic brain injury (TBI). Our in vivo experimental studies in cats revealed that the severity of TBI-mediated epileptogenesis depends on the age of the animal. To characterize mechanisms of these differences, we studied the properties of the TBI-induced epileptogenesis in a biophysically realistic cortical network model with dynamic ion concentrations. After deafferentation, which was induced by dissection of the afferent inputs, there was a reduction of the network activity and upregulation of excitatory connections leading to spontaneous spike-and-wave type seizures. When axonal sprouting was implemented, the seizure threshold increased in the model of young but not the older animals, which had slower or unidirectional homeostatic processes. Our study suggests that age-related changes in the HSP mechanisms are sufficient to explain the difference in the likelihood of seizure onset in young versus older animals. Significance statement: Traumatic brain injury (TBI) is one of the leading causes of intractable epilepsy. Likelihood of developing epilepsy and seizures following severe brain trauma has been shown to increase with age. Specific mechanisms of TBI-related epileptogenesis and how these mechanisms are affected by age remain to be understood. We test a hypothesis that the failure of homeostatic synaptic regulation, a slow negative feedback mechanism that maintains neural activity within a physiological range through activity-dependent modulation of synaptic strength, in older animals may augment TBI-induced epileptogenesis. Our results provide new insight into understanding this debilitating disorder and may lead to novel avenues for the development of effective treatments of TBI-induced epilepsy.

Published

2017

19. Cellular and neurochemical basis of sleep stages in the thalamocortical network

Author

Krishnan, Giri P., Chauvette, Sylvain, Shamie, Issac, Soltani, Sara, Timofeev, Igor, Cash, Sydney S., Halgren, Eric, Bazhenov, Maxim, Krishnan, Giri P., Chauvette, Sylvain, Shamie, Issac, Soltani, Sara, Timofeev, Igor, Cash, Sydney S., Halgren, Eric, and Bazhenov, Maxim

Abstract

The link between the combined action of neuromodulators in the brain and global brain states remains a mystery. In this study, using biophysically realistic models of the thalamocortical network, we identified the critical intrinsic and synaptic mechanisms, associated with the putative action of acetylcholine (ACh), GABA and monoamines, which lead to transitions between primary brain vigilance states (waking, non-rapid eye movement sleep [NREM] and REM sleep) within an ultradian cycle. Using ECoG recordings from humans and LFP recordings from cats and mice, we found that during NREM sleep the power of spindle and delta oscillations is negatively correlated in humans and positively correlated in animal recordings. We explained this discrepancy by the differences in the relative level of ACh. Overall, our study revealed the critical intrinsic and synaptic mechanisms through which different neuromodulators acting in combination result in characteristic brain EEG rhythms and transitions between sleep stages

Published

2016

20. Coupling of Thalamocortical Sleep Oscillations Are Important for Memory Consolidation in Humans.

Author

Niknazar, Mohammad, Niknazar, Mohammad, Krishnan, Giri P, Bazhenov, Maxim, Mednick, Sara C, Niknazar, Mohammad, Niknazar, Mohammad, Krishnan, Giri P, Bazhenov, Maxim, and Mednick, Sara C

Abstract

Sleep, specifically non-rapid eye movement (NREM) sleep, is thought to play a critical role in the consolidation of recent memories. Two main oscillatory activities observed during NREM, cortical slow oscillations (SO, 0.5-1.0 Hz) and thalamic spindles (12-15 Hz), have been shown to independently correlate with memory improvement. Yet, it is not known how these thalamocortical events interact, or the significance of this interaction, during the consolidation process. Here, we found that systemic administration of the GABAergic drug (zolpidem) increased both the phase-amplitude coupling between SO and spindles, and verbal memory improvement in humans. These results suggest that thalamic spindles that occur during transitions to the cortical SO Up state are optimal for memory consolidation. Our study predicts that the timely interactions between cortical and thalamic events during consolidation, contribute to memory improvement and is mediated by the level of inhibitory neurotransmission.

Published

2015

21. Modeling of age-dependent epileptogenesis by differential homeostatic synaptic scaling

Author

González, Oscar C., Krishnan, Giri P., Chauvette, Sylvain, Timofeev, Igor, Sejnowski, Terrence J., Bazhenov, Maxim, González, Oscar C., Krishnan, Giri P., Chauvette, Sylvain, Timofeev, Igor, Sejnowski, Terrence J., and Bazhenov, Maxim

Abstract

Homeostatic synaptic plasticity (HSP) has been implicated in the development of hyperexcitability and epileptic seizures following traumatic brain injury (TBI). Our in vivo experimental studies in cats revealed that the severity of TBI-mediated epileptogenesis depends on the age of the animal. To characterize mechanisms of these differences, we studied the properties of the TBI-induced epileptogenesis in a biophysically realistic cortical network model with dynamic ion concentrations. After deafferentation, which was induced by dissection of the afferent inputs, there was a reduction of the network activity and upregulation of excitatory connections leading to spontaneous spike-and-wave type seizures. When axonal sprouting was implemented, the seizure threshold increased in the model of young but not the older animals, which had slower or unidirectional homeostatic processes. Our study suggests that age-related changes in the HSP mechanisms are sufficient to explain the difference in the likelihood of seizure onset in young versus older animals.

Published

2015

22. Coupling of Thalamocortical Sleep Oscillations Are Important for Memory Consolidation in Humans.

Author

Niknazar, Mohammad, Vyazovskiy, Vladyslav1, Niknazar, Mohammad, Krishnan, Giri P, Bazhenov, Maxim, Mednick, Sara C, Niknazar, Mohammad, Vyazovskiy, Vladyslav1, Niknazar, Mohammad, Krishnan, Giri P, Bazhenov, Maxim, and Mednick, Sara C

Abstract

Sleep, specifically non-rapid eye movement (NREM) sleep, is thought to play a critical role in the consolidation of recent memories. Two main oscillatory activities observed during NREM, cortical slow oscillations (SO, 0.5-1.0 Hz) and thalamic spindles (12-15 Hz), have been shown to independently correlate with memory improvement. Yet, it is not known how these thalamocortical events interact, or the significance of this interaction, during the consolidation process. Here, we found that systemic administration of the GABAergic drug (zolpidem) increased both the phase-amplitude coupling between SO and spindles, and verbal memory improvement in humans. These results suggest that thalamic spindles that occur during transitions to the cortical SO Up state are optimal for memory consolidation. Our study predicts that the timely interactions between cortical and thalamic events during consolidation, contribute to memory improvement and is mediated by the level of inhibitory neurotransmission.

Published

2015