Phase‐response curves of ion channel gating kinetics

Schleimer, Jan-Hendrik; Schreiber, Susanne

doi:10.1002/mma.5232

Cited by 9 publications

(11 citation statements)

References 45 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…How the form of the f-I curve depends on capacitance can be analytically calculated for a single-compartment conductance-based neuron model undergoing a saddle-node on a limit cycle bifurcation at spiking onset like the WB model considered here ( Izhikevich, 2006 ), pp. 162–168; ( Schleimer and Schreiber, 2018 ). In this case, the time between two spikes

is dominated by the slow traversal T 2 of the saddle node, which close to threshold is multiple times longer than the brief duration T 1 of the spike and can be derived by considering solely local dynamics

…”

Section: Methodsmentioning

confidence: 99%

“…162–163. In principle,

and

can be calculated for arbitrary gating kinetics by projecting the dynamics on the center manifold ( Schleimer and Schreiber, 2018 ). For the assumption of small gating time constants, however, they can be expressed in simpler terms using the steady state I-V relation of the neuron divided by its membrane capacitance

taking the form

and

, where the saddle node voltage

and current

are given by the equations

In summary, both

and

are proportional to

and the rheobase current

is independent of capacitance, thus confirming the expected scaling.…”

Section: Impedance Of a Capacitance-clamped Rc Circuitmentioning

confidence: 99%

See 1 more Smart Citation

A dynamic clamp protocol to artificially modify cell capacitance

Pfeiffer

Tomás

et al. 2022

eLife

Self Cite

View full text Add to dashboard Cite

Dynamics of excitable cells and networks depend on the membrane time constant, set by membrane resistance and capacitance. Whereas pharmacological and genetic manipulations of ionic conductances of excitable membranes are routine in electrophysiology, experimental control over capacitance remains a challenge. Here, we present capacitance clamp, an approach that allows electrophysiologists to mimic a modified capacitance in biological neurons via an unconventional application of the dynamic clamp technique. We first demonstrate the feasibility to quantitatively modulate capacitance in a mathematical neuron model and then confirm the functionality of capacitance clamp in in vitro experiments in granule cells of rodent dentate gyrus with up to threefold virtual capacitance changes. Clamping of capacitance thus constitutes a novel technique to probe and decipher mechanisms of neuronal signaling in ways that were so far inaccessible to experimental electrophysiology.

show abstract

…”

Section: Methodsmentioning

confidence: 99%

“…162–163. In principle,

and

taking the form

and

, where the saddle node voltage

and current

are given by the equations

In summary, both

and

are proportional to

and the rheobase current

is independent of capacitance, thus confirming the expected scaling.…”

Section: Impedance Of a Capacitance-clamped Rc Circuitmentioning

confidence: 99%

A dynamic clamp protocol to artificially modify cell capacitance

Pfeiffer

Tomás

et al. 2022

eLife

Self Cite

View full text Add to dashboard Cite

show abstract

“…Equation (14) and other relationships between the state and the dynamics in directions transverse to a stable periodic orbit are particularly important in the development of second order accurate reduction strategies. These issues have been explored previously and the interested reader is referred to [8], [22], [21] for a detailed discussion. Substituting Eq.…”

Section: Background On Isostable Coordinates and Isostable Reductionmentioning

confidence: 99%

“…In an analogous strategy to the one used in the previous section, one can use the continuity assumption on θ and ψ j , the relation ∂ψj ∂x • F(x) = κ j ψ j , and Eq. (22) to derive the jump conditions across Π:…”

Section: B Jump Conditions For the First And Second Derivatives Of Tmentioning

confidence: 99%

“…For instance [8] uses such an expansion to obtain the frequency change of an oscillator in response to parameter perturbations. Additionally, [21] and [22] use higher order corrections to characterize neural spiking statistics in response to ion channel fluctuations wherein the notion of radial susceptibilities is analogous to the IRCs considered in this work. The transformation of the dynamical system from Eq.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Isostable reduction of oscillators with piecewise smooth dynamics and complex Floquet multipliers

Wilson

2019

Phys. Rev. E

View full text Add to dashboard Cite

Phase-amplitude reduction is a widely applied technique in the study of limit cycle oscillators with the ability to represent a complicated and high-dimensional dynamical system in a more analytically tractable coordinate system. Recent work has focused on the use of isostable coordinates, which characterize the transient decay of solutions towards a periodic orbit, and can ultimately be used to increase the accuracy of these reduced models. The breadth of systems to which this phaseamplitude reduction strategy can be applied, however, is still rather limited. In this work, the theory of phase-amplitude reduction using isostable coordinates is further developed to accommodate a broader set of dynamical systems. In the first part, limit cycles of piecewise smooth dynamical systems are considered and strategies are developed to compute the associated reduced equations. In the second part, the notion of isostable coordinates for complex-valued Floquet multipliers is introduced resulting in one phase-like coordinate and one amplitude-like coordinate for each pair of complex conjugate Floquet multipliers. Examples are given with relevance to piecewise smooth representations of excitable cardiomyocytes and the relationship between the reduced coordinate system and the emergence of cardiac alternans is discussed. Also, phase-amplitude reduction is implemented for a chaotic, externally forced pendulum with complex Floquet multipliers and a resulting control strategy for the stabilization of its periodic solution is investigated.

show abstract

How to correctly quantify neuronal phase-response curves from noisy recordings

Hesse

Schreiber

2019

J Comput Neurosci

Self Cite

View full text Add to dashboard Cite

At the level of individual neurons, various coding properties can be inferred from the inputoutput relationship of a cell. For small inputs, this relation is captured by the phase-response curve (PRC), which measures the effect of a small perturbation on the timing of the subsequent spike. Experimentally, however, an accurate experimental estimation of PRCs is challenging. Despite elaborate measurement efforts, experimental PRC estimates often cannot be related to those from modeling studies. In particular, experimental PRCs rarely resemble the generic PRC expected close to spike initiation, which is indicative of the underlying spike-onset bifurcation. Here, we show for conductance-based model neurons that the correspondence between theoretical and measured phase-response curve is lost when the stimuli used for the estimation are too large. In this case, the derived phase-response curve is distorted beyond recognition and takes on a generic shape that reflects the measurement protocol, but not the real neuronal dynamics. We discuss how to identify appropriate stimulus strengths for perturbation and noise-stimulation methods, which permit to estimate PRCs that reliably reflect the spike-onset bifurcation -a task that is particularly difficult if a lower bound for the stimulus amplitude is dictated by prominent intrinsic neuronal noise.

show abstract

Phase‐response curves of ion channel gating kinetics

Cited by 9 publications

References 45 publications

A dynamic clamp protocol to artificially modify cell capacitance

A dynamic clamp protocol to artificially modify cell capacitance

Isostable reduction of oscillators with piecewise smooth dynamics and complex Floquet multipliers

How to correctly quantify neuronal phase-response curves from noisy recordings

Contact Info

Product

Resources

About