Your search keyword '"Le Masson, Gwendal"' showing total 6 results

1. A computational model of motor neuron degeneration.

Author

Le Masson G, Przedborski S, and Abbott LF

Subjects

Adenosine Triphosphate metabolism, Calcium metabolism, Homeostasis physiology, Nerve Degeneration metabolism, Potassium metabolism, Sodium metabolism, Action Potentials physiology, Energy Metabolism, Models, Neurological, Motor Neurons pathology, Nerve Degeneration pathology, Nerve Degeneration physiopathology

Abstract

To explore the link between bioenergetics and motor neuron degeneration, we used a computational model in which detailed morphology and ion conductance are paired with intracellular ATP production and consumption. We found that reduced ATP availability increases the metabolic cost of a single action potential and disrupts K+/Na+ homeostasis, resulting in a chronic depolarization. The magnitude of the ATP shortage at which this ionic instability occurs depends on the morphology and intrinsic conductance characteristic of the neuron. If ATP shortage is confined to the distal part of the axon, the ensuing local ionic instability eventually spreads to the whole neuron and involves fasciculation-like spiking events. A shortage of ATP also causes a rise in intracellular calcium. Our modeling work supports the notion that mitochondrial dysfunction can account for salient features of the paralytic disorder amyotrophic lateral sclerosis, including motor neuron hyperexcitability, fasciculation, and differential vulnerability of motor neuron subpopulations., (Copyright © 2014 Elsevier Inc. All rights reserved.)

Published

2014

2. Multiple firing patterns in deep dorsal horn neurons of the spinal cord: computational analysis of mechanisms and functional implications.

Author

Le Franc Y and Le Masson G

Subjects

Animals, Calcium Signaling physiology, Electric Conductivity, Haplorhini, Software, Spinal Cord cytology, Spinal Cord physiology, alpha-Amino-3-hydroxy-5-methyl-4-isoxazolepropionic Acid pharmacology, Action Potentials physiology, Computational Biology methods, Models, Neurological, Posterior Horn Cells physiology

Abstract

Deep dorsal horn relay neurons (dDHNs) of the spinal cord are known to exhibit multiple firing patterns under the control of local metabotropic neuromodulation: tonic firing, plateau potential, and spontaneous oscillations. This work investigates the role of interactions between voltage-gated channels and the occurrence of different firing patterns and then correlates these two phenomena with their functional role in sensory information processing. We designed a conductance-based model using the NEURON software package, which successfully reproduced the classical features of plateau in dDHNs, including a wind-up of the neuronal response after repetitive stimulation. This modeling approach allowed us to systematically test the impact of conductance interactions on the firing patterns. We found that the expression of multiple firing patterns can be reproduced by changes in the balance between two currents (L-type calcium and potassium inward rectifier conductances). By investigating a possible generalization of the firing state switch, we found that the switch can also occur by varying the balance of any hyperpolarizing and depolarizing conductances. This result extends the control of the firing switch to neuromodulators or to network effects such as synaptic inhibition. We observed that the switch between the different firing patterns occurs as a continuous function in the model, revealing a particular intermediate state called the accelerating mode. To characterize the functional effect of a firing switch on information transfer, we used correlation analysis between a model of peripheral nociceptive afference and the dDHN model. The simulation results indicate that the accelerating mode was the optimal firing state for information transfer.

Published

2010

3. Synaptic background activity controls spike transfer from thalamus to cortex.

Author

Wolfart J, Debay D, Le Masson G, Destexhe A, and Bal T

Subjects

Animals, Artifacts, Calcium Channels, T-Type physiology, Cell Membrane physiology, Electric Stimulation, Feedback physiology, Guinea Pigs, Organ Culture Techniques, Sensory Thresholds physiology, Visual Perception physiology, Action Potentials physiology, Geniculate Bodies physiology, Neurons physiology, Synaptic Transmission physiology, Visual Cortex physiology, Visual Pathways physiology

Abstract

Characterizing the responsiveness of thalamic neurons is crucial to understanding the flow of sensory information. Typically, thalamocortical neurons possess two distinct firing modes. At depolarized membrane potentials, thalamic cells fire single action potentials and faithfully relay synaptic inputs to the cortex. At hyperpolarized potentials, the activation of T-type calcium channels promotes burst firing, and the transfer is less accurate. Our results suggest that this duality no longer holds if synaptic background activity is taken into account. By injecting stochastic conductances into guinea-pig thalamocortical neurons in slices, we show that the transfer function of these neurons is strongly influenced by conductance noise. The combination of synaptic noise with intrinsic properties gives a global responsiveness that is more linear, mixing single-spike and burst responses at all membrane potentials. Because in thalamic neurons, background synaptic input originates mainly from cortex, these results support a determinant role of corticothalamic feedback during sensory information processing.

Published

2005

4. Exploring spike transfer through the thalamus using hybrid artificial-biological neuronal networks.

Author

Debay D, Wolfart J, Le Franc Y, Le Masson G, and Bal T

Subjects

Animals, Biofeedback, Psychology physiology, Cerebral Cortex physiology, Chromosome Pairing physiology, Computer Simulation, Ferrets, Guinea Pigs, Models, Neurological, Neurotransmitter Agents physiology, Norepinephrine pharmacology, Retinal Ganglion Cells physiology, Signal Transduction physiology, Sleep physiology, Synaptic Transmission drug effects, Time Factors, Visual Pathways physiology, Wakefulness physiology, Action Potentials physiology, Nerve Net physiology, Neural Networks, Computer, Neurons, Afferent physiology, Synaptic Transmission physiology, Thalamus physiology

Abstract

We use dynamic clamp to construct "hybrid" thalamic circuits by connecting a biological neuron in situ to silicon- or software-generated "neurons" through artificial synapses. The purpose is to explore cellular sensory gating mechanisms that regulate the transfer efficiency of signals during different sleep-wake states. Hybrid technology is applied in vitro to different paradigms such as: (1) simulating interactions between biological thalamocortical neurons, artificial reticular thalamic inhibitory interneurons and a simulated sensory input, (2) grafting an artificial sensory input to a wholly biological thalamic network that generates spontaneous sleep-like oscillations, (3) injecting in thalamocortical neurons a background synaptic bombardment mimicking the activity of corticothalamic inputs. We show that the graded control of the strength of intrathalamic inhibition, combined with the membrane polarization and the fluctuating synaptic noise in thalamocortical neurons, is able to govern functional shifts between different input/output transmission states of the thalamic gate.

Published

2004

5. Glutamatergic input governs periodicity and synchronization of bursting activity in oxytocin neurons in hypothalamic organotypic cultures.

Author

Israel JM, Le Masson G, Theodosis DT, and Poulain DA

Subjects

6-Cyano-7-nitroquinoxaline-2,3-dione pharmacology, Anesthetics, Inhalation pharmacology, Animals, Animals, Newborn, Bicuculline pharmacology, Biotin metabolism, Calcium pharmacology, Dose-Response Relationship, Drug, Drug Interactions, Electric Stimulation, Excitatory Amino Acid Antagonists pharmacology, Excitatory Postsynaptic Potentials, GABA Antagonists pharmacology, Halothane pharmacology, Lysine metabolism, Neurophysins metabolism, Organ Culture Techniques, Propionates pharmacology, Rats, Rats, Wistar, Vasopressins metabolism, Action Potentials physiology, Biotin analogs & derivatives, Glutamic Acid physiology, Hypothalamus physiology, Lysine analogs & derivatives, Neurons physiology, Oxytocin physiology, Periodicity

Abstract

During suckling, oxytocin (OT) neurons display a bursting electrical activity, consisting of a brief burst of action potentials which is synchronized throughout the OT neuron population and which periodically occurs just before each milk ejection in the lactating rat. To investigate the basis of such synchronization, we performed simultaneous intracellular recordings from pairs of OT neurons identified retrospectively by intracellular fluorescent labelling and immunocytochemistry in organotypic slice cultures derived from postnatal rat hypothalamus. A spontaneous bursting activity was recorded in 65% of OT neurons; the remaining showed only a slow, irregular activity. Application of OT triggered bursts in nonbursting neurons and accelerated bursting activity in spontaneously bursting cells. These cultures included rare vasopressinergic neurons showing no bursting activity and no reaction to OT. Bursts occurred simultaneously in all pairs of bursting OT neurons but, as in vivo, there were differences in burst onset, amplitude and duration. Coordination of firing was not due to electrotonic coupling because depolarizing one neuron in a pair had no effect on the membrane potential of its partner and halothane and proprionate did not desynchronize activity. On the other hand, bursting activity was superimposed on volleys of excitatory postsynaptic potentials (EPSPs) which occurred simultaneously in pairs of neurons. EPSPs, and consequently action potentials, were reversibly blocked by the non-NMDA glutamatergic receptor antagonist CNQX. Taken together, these data, obtained from organotypic cultures, strongly suggest that a local hypothalamic network governs synchronization of bursting firing in OT neurons through synchronous afferent volleys of EPSPs originating from intrahypothalamic glutamatergic inputs.

Published

2003

6. Feedback inhibition controls spike transfer in hybrid thalamic circuits.

Author

Le Masson G, Renaud-Le Masson S, Debay D, and Bal T

Subjects

Animals, Arousal drug effects, Cerebral Cortex cytology, Cerebral Cortex drug effects, Feedback, Physiological drug effects, Guinea Pigs, Neurons drug effects, Neurons physiology, Norepinephrine pharmacology, Photic Stimulation, Retina cytology, Retina drug effects, Retina physiology, Sleep drug effects, Sleep physiology, Synapses drug effects, Synapses physiology, Thalamus cytology, Thalamus drug effects, Visual Pathways drug effects, Wakefulness drug effects, Wakefulness physiology, gamma-Aminobutyric Acid pharmacology, Action Potentials drug effects, Arousal physiology, Cerebral Cortex physiology, Thalamus physiology, Visual Pathways physiology

Abstract

Sensory information reaches the cerebral cortex through the thalamus, which differentially relays this input depending on the state of arousal. Such 'gating' involves inhibition of the thalamocortical relay neurons by the reticular nucleus of the thalamus, but the underlying mechanisms are poorly understood. We reconstructed the thalamocortical circuit as an artificial and biological hybrid network in vitro. With visual input simulated as retinal cell activity, we show here that when the gain in the thalamic inhibitory feedback loop is greater than a critical value, the circuit tends towards oscillations -- and thus imposes a temporal decorrelation of retinal cell input and thalamic relay output. This results in the functional disconnection of the cortex from the sensory drive, a feature typical of sleep states. Conversely, low gain in the feedback inhibition and the action of noradrenaline, a known modulator of arousal, converge to increase input output correlation in relay neurons. Combining gain control of feedback inhibition and modulation of membrane excitability thus enables thalamic circuits to finely tune the gating of spike transmission from sensory organs to the cortex.

Published

2002