Currents carried by sodium and potassium ions through the membrane of the giant axon of <i>Loligo</i>

Hodgkin, A. L.; Huxley, Andrew

doi:10.1113/jphysiol.1952.sp004717

Cited by 2,197 publications

(992 citation statements)

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“…Each spike is an impulse of about one millisecond duration with a stereotyped shape [HH52]. Thus, we can characterize the activity of a neuron by its spike train, the set of time points {t 1 , t 2 , ..., t n } at which the spikes occur.…”

Section: Point Process Models For Spike Trainsmentioning

confidence: 99%

Information transmission in oscillatory neural activity

Koepsell¹,

Sommer²

2008

Biol Cybern

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Periodic neural activity not locked to the stimulus or to motor responses is usually ignored. Here, we present new tools for modeling and quantifying the information transmission based on periodic neural activity that occurs with quasirandom phase relative to the stimulus. We propose a model to reproduce characteristic features of oscillatory spike trains, such as histograms of inter-spike intervals and phase locking of spikes to an oscillatory influence. The proposed model is based on an inhomogeneous Gamma process governed by a density function that is a product of the usual stimulus-dependent rate and a quasi-periodic function. Further, we present an analysis method generalizing the direct method [RWvSB99, BSK + 00] to assess the information content in such data. We demonstrate these tools on recordings from relay cells in the lateral geniculate nucleus of the cat.

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Section: Point Process Models For Spike Trainsmentioning

confidence: 99%

Information transmission in oscillatory neural activity

Koepsell¹,

Sommer²

2008

Biol Cybern

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“…The number of experimental studies is also limited. 40,63 Given the importance of ion dynamics in the vicinity of membranes in many biological phenomena, starting from action potentials in nerve cells 64,65 and ranging from cell energetics 66 to ion-mediated signaling between active membrane proteins, [67][68][69] the lack of computational studies on ion dynamics is rather surprising.…”

Section: Introductionmentioning

confidence: 99%

Ion Dynamics in Cationic Lipid Bilayer Systems in Saline Solutions

et al. 2009

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Positively charged lipid bilayer systems are a promising class of nonviral vectors for safe and efficient gene and drug delivery. Detailed understanding of these systems is therefore not only of fundamental but also of practical biomedical interest. Here, we study bilayers comprising a binary mixture of cationic dimyristoyltrimethylammoniumpropane (DMTAP) and zwitterionic (neutral) dimyristoylphosphatidylcholine (DMPC) lipids. Using atomistic molecular dynamics simulations, we address the effects of bilayer composition (cationic to zwitterionic lipid fraction) and of NaCl electrolyte concentration on the dynamical properties of these cationic lipid bilayer systems. We find that, despite the fact that DMPCs form complexes via Na + ions that bind to the lipid carbonyl oxygens, NaCl concentration has a rather minute effect on lipid diffusion. We also find the dynamics of Cl -and Na + ions at the water-membrane interface to differ qualitatively. Cl -ions have well-defined characteristic residence times of nanosecond scale. In contrast, the binding of Na + ions to the carbonyl region appears to lack a characteristic time scale, as the residence time distributions displayed power-law features. As to lateral dynamics, the diffusion of Na + ions within the water-membrane interface consists of two qualitatively different modes of motion: very slow diffusion when ions are bound to DMPC, punctuated by fast rapid jumps when detached from the lipids. Overall, the prolonged dynamics of the Na + ions are concluded to be interesting for the physics of the whole membrane, especially considering its interaction dynamics with charged macromolecular surfaces.

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“…Neurons respond to stimuli by changes in their membrane potential. If there is a depolarization of the membrane potential that reaches threshold, 'spikes' or action potentials (sharp peaks of voltage of the same height) are triggered (Hodgkin and Huxley, 1952). Basically all the information that travels without decay along neuronal axons and is transmitted between neurons, does it in the form of individual spikes or trains of spikes.…”

Section: Introductionmentioning

confidence: 99%

On the number of states of the neuronal sources

et al. 2003

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In a previous paper (Proceedings of the World Congress on Neuroinformatics (2001)) the authors applied the socalled Lempel Á/Ziv complexity to study neural discharges (spike trains) from an information-theoretical point of view. Along with other results, it is shown there that this concept of complexity allows to characterize the responses of primary visual cortical neurons to both random and periodic stimuli. To this aim we modeled the neurons as information sources and the spike trains as messages generated by them. In this paper, we study further consequences of this mathematical approach, this time concerning the number of states of such neuronal information sources. In this context, the state of an information source means an internal degree of freedom (or parameter) which allows outputs with more general stochastic properties, since symbol generation probabilities at every time step may additionally depend on the value of the current state of the neuron. Furthermore, if the source is ergodic and Markovian, the number of states is directly related to the stochastic dependence lag of the source and provides a measure of the autocorrelation of its messages. Here, we find that the number of states of the neurons depends on the kind of stimulus and the type of preparation ( in vivo versus in vitro recordings), thus providing another way of differentiating neuronal responses. In particular, we observed that (for the encoding methods considered) in vitro sources have a higher lag than in vivo sources for periodic stimuli. This supports the conclusion put forward in the paper mentioned above that, for the same kind of stimulus, in vivo responses are more random (hence, more difficult to compress) than in vitro responses and, consequently, the former transmit more information than the latter. #

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Currents carried by sodium and potassium ions through the membrane of the giant axon of Loligo

Cited by 2,197 publications

References 9 publications

Information transmission in oscillatory neural activity

Information transmission in oscillatory neural activity

Ion Dynamics in Cationic Lipid Bilayer Systems in Saline Solutions

On the number of states of the neuronal sources

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