Digital computer solutions for excitable membrane models

Cooley, James W.; Dodge, F. A.; Cohen, Hirsh

doi:10.1002/jcp.1030660517

Cited by 58 publications

(36 citation statements)

References 7 publications

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“…We conclude that the nonfiring stable state in the deterministic HH model becomes a key player in the stochastic HH model. Experimentally, the coexistence of the two stable solutions in the the squid giant axon, as well as in the corresponding HH model, was demonstrated by Guttman et al (1980) (see also Cooley et al, 1965).…”

Section: Subhresholdmentioning

confidence: 92%

“…Channel stochasticity has such a dramatic effect on the voltage dynamics because it exploits a peculiar, and largely neglected, aspect of the deterministic HH equations: its two stable states for suprathreshold current input (see the discussion of the bistability in the HH equations in Cooley, Dodge, andCohen, 1965, andGuttman, Lewis, andRinzel, 1980). For a DC input, one state is the well-known repetitive firing behavior (the light trace in Figure 6A) whereas the other state is a nonfiring behavior of early damped voltage oscillations that converges to a steady voltage (see Figure 6A, dark trace).…”

Section: Subhresholdmentioning

confidence: 99%

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Ion Channel Stochasticity May Be Critical in Determining the Reliability and Precision of Spike Timing

1998

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The firing reliability and precision of an isopotential membrane patch consisting of a realistically large number of ion channels is investigated using a stochastic Hodgkin-Huxley (HH) model. In sharp contrast to the deterministic HH model, the biophysically inspired stochastic model reproduces qualitatively the different reliability and precision characteristics of spike firing in response to DC and fluctuating current input in neocortical neurons, as reported by Mainen & Sejnowski (1995). For DC inputs, spike timing is highly unreliable; the reliability and precision are significantly increased for fluctuating current input. This behavior is critically determined by the relatively small number of excitable channels that are opened near threshold for spike firing rather than by the total number of channels that exist in the membrane patch. Channel fluctuations, together with the inherent bistability in the HH equations, give rise to three additional experimentally observed phenomena: subthreshold oscillations in the membrane voltage for DC input, "spontaneous" spikes for subthreshold inputs, and "missing" spikes for suprathreshold inputs. We suggest that the noise inherent in the operation of ion channels enables neurons to act as "smart" encoders. Slowly varying, uncorrelated inputs are coded with low reliability and accuracy and, hence, the information about such inputs is encoded almost exclusively by the spike rate. On the other hand, correlated presynaptic activity produces sharp fluctuations in the input to the postsynaptic cell, which are then encoded with high reliability and accuracy. In this case, information about the input exists in the exact timing of the spikes. We conclude that channel stochasticity should be considered in realistic models of neurons.

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Section: Subhresholdmentioning

confidence: 92%

Section: Subhresholdmentioning

confidence: 99%

Ion Channel Stochasticity May Be Critical in Determining the Reliability and Precision of Spike Timing

1998

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“…This does not mean that the mechanism of triggered activity may not reside in altered cellular electrophysiological properties, irrespective of coupling. It has been shown theoretically (Cooley et al, 1965) that "hard" oscillations (that is, oscillatory activity in a system that also has a stable, nonoscillatory stationary state) may be found in Hodgkin-Huxley elements. Our results do show, however, that coupling of elements that lack this property themselves may easily result in this type of behavior, suggesting that the conditions for triggerable focal activity may be less restricted than commonly assumed.…”

Section: Simulation Of Arrhythmias In a Network/wm Capelle And Durrermentioning

confidence: 99%

Computer simulation of arrhythmias in a network of coupled excitable elements.

Capelle¹,

Durrer²

1980

Circulation Research

199

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Uhley HN (1961) SUMMARY Arrhythmias were simulated in sheets or cables, consisting of coupled excitable elements, which were characterized by a simple regenerative mechanism. The geometry of the network, the amount of coupling among individual elements, and the properties of the elements relating to excitability, automaticity, and duration of the refractory period could be adjusted arbitrarily in an interactive computer program. When a critical amount of coupling was present between automatic and nonautomatic cells, sustained repetitive activity could be initiated and stopped by stimulation of the elements. Using this mechanism, it also was possible to evoke reciprocal activity in a one-dimensional cable. In uniform sheets of coupled elements, circus movement of the activation front could be evoked. The presence of an obstacle or dispersion of the refractory periods of the elements was not a prerequisite for the initiation of circus movements. The vortex of circus movements in the homogeneous sheets consisted of elements which were inactivated by depolarizing currents from the circulating wavefront. In sheets of sufficient size, multiple vortices could be present. Circ Res 47: 454-466, 1980WE used computer simulation to study the possible role of spatial interaction among excitable elements in the mechanisms underlying cardiac arrhythmias, of both the focal and the reentrant type. Intuitively, the mechanism of focal tachycardias is thought to reside mainly in the ionic properties of the cell membrane, whereas the involvement of many interacting cells is a prerequisite for reentrant arrhythmias. We were interested in whether it would be possible to evoke both focal and reentrant arrhythmias in a synthetic sheet consisting of a primitive kind of excitable element, and whether the influence the elements exert on each other would play an important role in the genesis and maintenance of these arrhythmias. As it turns out, many of the features of clinical and experimental tachycardias could be simulated rather easily in such a model, and the results suggest that the role of spatial interaction among cardiac cells may be of considerable importance in both types of arrhythmia. Although many model studies of impulse propagation have been published, relatively few of them deal with sheets consisting of large numbers of

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“…The results of Cole, Antosiewicz and Rabinowitz [1] and Cooley, Dodge and Cohen [2] indicate that for each I £ (6.8, 9.8) there is a stable large-amplitude periodic orbit, and an unstable small-amplitude periodic solution which disappears at / = 9.8. Thus, in accordance with our theorem, it appears that there is a bifurcation of small-amplitude unstable periodic solutions on the interval (6.8, 9.8) with I = 9.8 being the bifurcation point.…”

Section: Introductionmentioning

confidence: 97%

“…Cooley, Dodge and Cohen [2] investigated a suggestion of FitzHugh that repetitive firing in the space clamped axon may be associated with instability of the steady state solution. For each / > 0 their numerical calculations indicate that (1.6)-(1.9) has exactly one steady-state solution, ir, = (vi, n"(v,), h"(v,)).…”

Section: Introductionmentioning

confidence: 99%

The bifurcation of periodic solutions in the Hodgkin-Huxley equations

Troy¹

1978

Quart. Appl. Math.

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Abstract.We consider the current clamped version of the Hodgkin-Huxley nerve conduction equations. Under appropriate assumptions on the functions and parameters we show that there are two critical values of /, the current parameter, at which a Hopf bifurcation of periodic orbits occurs.Comparisons are made with numerical and experimental calculations of other authors in order to give a reasonable conjecture as to the global behavior of the families of bifurcating periodic orbits.Introduction.In this paper we continue the analysis begun in [13] on the current clamped version of the Hodgkin-Huxley nerve conduction equations.The Hodgkin-Huxley equations have the form

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Digital computer solutions for excitable membrane models

Cited by 58 publications

References 7 publications

Ion Channel Stochasticity May Be Critical in Determining the Reliability and Precision of Spike Timing

Ion Channel Stochasticity May Be Critical in Determining the Reliability and Precision of Spike Timing

Computer simulation of arrhythmias in a network of coupled excitable elements.

The bifurcation of periodic solutions in the Hodgkin-Huxley equations

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