Adaptive learning algorithms for nernst potential and I-V curves in nerve cell membrane ion channels modeled as hidden Markov models

Vikram Krishnamurthy; Shin Ho Chung

doi:10.1109/TNB.2003.820275

Adaptive learning algorithms for nernst potential and I-V curves in nerve cell membrane ion channels modeled as hidden Markov models

Vikram Krishnamurthy^*, Shin Ho Chung

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

6 Citations (Scopus)

Abstract

We present discrete stochastic optimization algorithms that adaptively learn the Nernst potential in membrane ion channels. The proposed algorithms dynamically control both the ion channel experiment and the resulting hidden Markov model signal processor and can adapt to time-varying behavior of ion channels. One of the most important properties of the proposed algorithms is their its self-learning capability-they spend most of the computational effort at the global optimizer (Nernst potential). Numerical examples illustrate the performance of the algorithms on computer-generated synthetic data.

Original language	English
Pages (from-to)	266-278
Number of pages	13
Journal	IEEE Transactions on Nanobioscience
Volume	2
Issue number	4
DOIs	https://doi.org/10.1109/TNB.2003.820275
Publication status	Published - Dec 2003

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abstract = "We present discrete stochastic optimization algorithms that adaptively learn the Nernst potential in membrane ion channels. The proposed algorithms dynamically control both the ion channel experiment and the resulting hidden Markov model signal processor and can adapt to time-varying behavior of ion channels. One of the most important properties of the proposed algorithms is their its self-learning capability-they spend most of the computational effort at the global optimizer (Nernst potential). Numerical examples illustrate the performance of the algorithms on computer-generated synthetic data.",

keywords = "Discrete stochastic approximation, Hidden Markov models (HMMs), Ion channel currents, Nernst potential",

author = "Vikram Krishnamurthy and Chung, {Shin Ho}",

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AU - Chung, Shin Ho

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N2 - We present discrete stochastic optimization algorithms that adaptively learn the Nernst potential in membrane ion channels. The proposed algorithms dynamically control both the ion channel experiment and the resulting hidden Markov model signal processor and can adapt to time-varying behavior of ion channels. One of the most important properties of the proposed algorithms is their its self-learning capability-they spend most of the computational effort at the global optimizer (Nernst potential). Numerical examples illustrate the performance of the algorithms on computer-generated synthetic data.

AB - We present discrete stochastic optimization algorithms that adaptively learn the Nernst potential in membrane ion channels. The proposed algorithms dynamically control both the ion channel experiment and the resulting hidden Markov model signal processor and can adapt to time-varying behavior of ion channels. One of the most important properties of the proposed algorithms is their its self-learning capability-they spend most of the computational effort at the global optimizer (Nernst potential). Numerical examples illustrate the performance of the algorithms on computer-generated synthetic data.

KW - Discrete stochastic approximation

KW - Hidden Markov models (HMMs)

KW - Ion channel currents

KW - Nernst potential

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JO - IEEE Transactions on Nanobioscience

JF - IEEE Transactions on Nanobioscience

IS - 4

ER -

Adaptive learning algorithms for nernst potential and I-V curves in nerve cell membrane ion channels modeled as hidden Markov models

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