Bridging Single Neuron Dynamics to Global Brain States

Goldman, Jennifer S.; Tort-Colet, Núria; Volo, Matteo di; Susin, Eduarda; Bouté, Jules; Dali, Mélissa; Carlu, Mallory; Nghiem, Trang-Anh; Górski, Tomasz; Destexhe, Alain

doi:10.3389/fnsys.2019.00075

Cited by 43 publications

(50 citation statements)

References 105 publications

(147 reference statements)

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“…This model is based on the prediction that neural network signals flow along well-behaved axonal rails and pass the activity baton at synapses. Regardless of whether spiking activity is used for information representation, the "membrane potential dynamics" of neurons is the essence of neuronal information representation (32,33). In this review, we define membrane potential dynamics as the stochastically/deterministically shaped temporal structure of membrane potential (34,35) (Figure 1).…”

Section: Introductionmentioning

confidence: 99%

Light/Clock Influences Membrane Potential Dynamics to Regulate Sleep States

et al. 2021

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The circadian rhythm is a fundamental process that regulates the sleep–wake cycle. This rhythm is regulated by core clock genes that oscillate to create a physiological rhythm of circadian neuronal activity. However, we do not know much about the mechanism by which circadian inputs influence neurons involved in sleep–wake architecture. One possible mechanism involves the photoreceptor cryptochrome (CRY). In Drosophila, CRY is receptive to blue light and resets the circadian rhythm. CRY also influences membrane potential dynamics that regulate neural activity of circadian clock neurons in Drosophila, including the temporal structure in sequences of spikes, by interacting with subunits of the voltage-dependent potassium channel. Moreover, several core clock molecules interact with voltage-dependent/independent channels, channel-binding protein, and subunits of the electrogenic ion pump. These components cooperatively regulate mechanisms that translate circadian photoreception and the timing of clock genes into changes in membrane excitability, such as neural firing activity and polarization sensitivity. In clock neurons expressing CRY, these mechanisms also influence synaptic plasticity. In this review, we propose that membrane potential dynamics created by circadian photoreception and core clock molecules are critical for generating the set point of synaptic plasticity that depend on neural coding. In this way, membrane potential dynamics drive formation of baseline sleep architecture, light-driven arousal, and memory processing. We also discuss the machinery that coordinates membrane excitability in circadian networks found in Drosophila, and we compare this machinery to that found in mammalian systems. Based on this body of work, we propose future studies that can better delineate how neural codes impact molecular/cellular signaling and contribute to sleep, memory processing, and neurological disorders.

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Section: Introductionmentioning

confidence: 99%

Light/Clock Influences Membrane Potential Dynamics to Regulate Sleep States

et al. 2021

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“…Dado que as evidências experimentais indicam que existe correlação entre o grau de sincronia da atividade de disparos de populações de neurônios corticais e o estado de consciência do indivíduo [30,96], modelos de redes de neurônios de disparo como os descritos nesta revisão oferecem uma oportunidade de que se possa começar a entender mecanisticamente [97] a relação entre a dinâmica de neurônios individuais e estados comportamentais complexos.…”

Section: Discussionunclassified

“…Conjectura-se que a atividade assíncrona característica dos estados de vigília reflita a disponibilidade de um repertório maior e mais diversificado de padrões neurais, possibilitando a existência de ricos estados de consciência, enquanto que o repertório reduzido de padrões neurais durante regimes de atividade coletiva síncrona cerceia ou restringe a consciência [28][29][30].…”

Section: Introductionunclassified

Modelos de redes de neurônios para o neocórtex e fenômenos emergentes observados

Shimoura

Pena

Kamiji

et al. 2021

Rev. Bras. Ensino Fís.

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O córtex cerebral apresenta padrões específicos de atividade espontânea produzidos endogenamente. Esses estados são caracterizados com relação ao grau de sincronia da atividade coletiva dos neurônios e ao nível de irregularidade dos disparos de potenciais de ação dos neurônios individuais. Um problema colocado à neurociência teórica é como modelar a emergência de estados espontâneos síncronos e assíncronos a partir de uma mesma rede de neurônios de disparos. Neste artigo, três modelos que oferecem solução para esse problema são revistos. Os modelos utilizam neurônios de disparo da classe conhecida como integra-e-dispara e consideram diferentes estruturas de rede e dinâmicas sinápticas. Mecanismos adotados pelos modelos, como balanço entre excitação e inibição e adaptação dependente dos disparos, são discutidos e contextualizados. Em paralelo, este artigo apresenta alguns conceitos utilizados na modelagem de neurônios e sinapses, oferecendo uma rápida introdução à neurociência teórica.

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“…The introduction of a time dimension projects into the domain of dynamical systems e.g., monitoring (or behavioral) consciousness, in which associations between percepts are replaced by causality rules (Freeman, 1999) that can involve contextual and/or multimodal perceptions. The complexity of the corresponding neural phenomena has so far prevented the definition of models directly relating single neuron dynamics to global brain states (see e.g., Goldman et al, 2019). As an example, whereas neurological measurements (Tomov et al, 2018) have validated a computational Bayesian model positing a dedicated neural mechanism for causal learning (Gershman, 2017), nothing is known about the corresponding basic neuronal processes that could be reproduced in a bio-inspired robot.…”

Section: Introductionmentioning

confidence: 99%

Modeling the Synchronization of Multimodal Perceptions as a Basis for the Emergence of Deterministic Behaviors

Bonzon

2020

Front. Neurorobot.

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Living organisms have either innate or acquired mechanisms for reacting to percepts with an appropriate behavior e.g., by escaping from the source of a perception detected as threat, or conversely by approaching a target perceived as potential food. In the case of artifacts, such capabilities must be built in through either wired connections or software. The problem addressed here is to define a neural basis for such behaviors to be possibly learned by bio-inspired artifacts. Toward this end, a thought experiment involving an autonomous vehicle is first simulated as a random search. The stochastic decision tree that drives this behavior is then transformed into a plastic neuronal circuit. This leads the vehicle to adopt a deterministic behavior by learning and applying a causality rule just as a conscious human driver would do. From there, a principle of using synchronized multimodal perceptions in association with the Hebb principle of wiring together neuronal cells is induced. This overall framework is implemented as a virtual machine i.e., a concept widely used in software engineering. It is argued that such an interface situated at a meso-scale level between abstracted micro-circuits representing synaptic plasticity, on one hand, and that of the emergence of behaviors, on the other, allows for a strict delineation of successive levels of complexity. More specifically, isolating levels allows for simulating yet unknown processes of cognition independently of their underlying neurological grounding.

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Bridging Single Neuron Dynamics to Global Brain States

Cited by 43 publications

References 105 publications

Light/Clock Influences Membrane Potential Dynamics to Regulate Sleep States

Light/Clock Influences Membrane Potential Dynamics to Regulate Sleep States

Modelos de redes de neurônios para o neocórtex e fenômenos emergentes observados

Modeling the Synchronization of Multimodal Perceptions as a Basis for the Emergence of Deterministic Behaviors

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