The gating kinetics of single-ion channels are generally modeled in terms of Markov processes with relatively small numbers of channel states. More recently, fractal (Liebovitch et al. 1987. Math. Biosci. 84:37–68) and diffusion (Millhauser et al. 1988. Proc. Natl. Acad. Sci. USA. 85:1502–1507) models of channel gating have been proposed. These models propose the existence of many similar conformational substrates of the channel protein, all of which contribute to the observed gating kinetics. It is important to determine whether or not Markov models provide the most accurate description of channel kinetics if progress is to be made in understanding the molecular events of channel gating. In this study six alternative classes of gating mode...
The stochastic behavior of single ion channels is most often described as an aggregated continuous-t...
A position-dependent stochastic diffusion model of gating in ion channels is developed by considerin...
The nonexponential closed-time distributions observed for ionic channels have been explained recentl...
The gating kinetics of single ion channels have been well described by models which assume that chan...
A statistical comparison is presented of Markov and fractal models of ion channel gating. The analys...
Previously, we described a model which treats ion channel gating as a discrete diffusion problem. In...
The kinetics of ion channels have been widely modeled as a Markov process. In these models it is ass...
AbstractKramers’ diffusion theory of reaction rates in the condensed phase is considered as an alter...
A one-dimensional version of the model recently proposed by Läuger (1988) to explain the closed-time...
Conti and Stühmer (1989. Eur. Biophys. J. 17:53–59) have measured the nonstationary shot noise in th...
Ion channels regulate the concentrations of ions within cells. By stochastically opening and closing...
Markov models of ion channel dynamics have evolved as experimental advances have improved our unders...
Reptation theory is a highly successful approach for describing polymer dynamics in entangled system...
Many ion channels spontaneously switch between different levels of activity. Although this behaviour...
We have developed a novel technique for simulating the influence of the effects of single channel ki...
The stochastic behavior of single ion channels is most often described as an aggregated continuous-t...
A position-dependent stochastic diffusion model of gating in ion channels is developed by considerin...
The nonexponential closed-time distributions observed for ionic channels have been explained recentl...
The gating kinetics of single ion channels have been well described by models which assume that chan...
A statistical comparison is presented of Markov and fractal models of ion channel gating. The analys...
Previously, we described a model which treats ion channel gating as a discrete diffusion problem. In...
The kinetics of ion channels have been widely modeled as a Markov process. In these models it is ass...
AbstractKramers’ diffusion theory of reaction rates in the condensed phase is considered as an alter...
A one-dimensional version of the model recently proposed by Läuger (1988) to explain the closed-time...
Conti and Stühmer (1989. Eur. Biophys. J. 17:53–59) have measured the nonstationary shot noise in th...
Ion channels regulate the concentrations of ions within cells. By stochastically opening and closing...
Markov models of ion channel dynamics have evolved as experimental advances have improved our unders...
Reptation theory is a highly successful approach for describing polymer dynamics in entangled system...
Many ion channels spontaneously switch between different levels of activity. Although this behaviour...
We have developed a novel technique for simulating the influence of the effects of single channel ki...
The stochastic behavior of single ion channels is most often described as an aggregated continuous-t...
A position-dependent stochastic diffusion model of gating in ion channels is developed by considerin...
The nonexponential closed-time distributions observed for ionic channels have been explained recentl...