Implementation of a Fast 16-Bit Dynamic Clamp Using LabVIEW-RT

Overview

Journal J Neurophysiol

Publisher American Physiological Society

Specialties Neurology
Physiology

Date 2003 Sep 26

PMID 14507986

Citations 39

Authors

Paul H M Kullmann

Diek W Wheeler

Joshua Beacom

John P Horn

Affiliations

Soon will be listed here.

Abstract

The dynamic-clamp method provides a powerful electrophysiological tool for creating virtual ionic conductances in living cells and studying their influence on membrane potential. Here we describe G-clamp, a new way to implement a dynamic clamp using the real-time version of the Lab-VIEW programming environment together with a Windows host, an embedded microprocessor that runs a real-time operating system and a multifunction data-acquisition board. The software includes descriptions of a fast voltage-dependent sodium conductance, delayed rectifier, M-type and A-type potassium conductances, and a leak conductance. The system can also read synaptic conductance waveforms from preassembled data files. These virtual conductances can be reliably implemented at speeds < or =43 kHz while simultaneously saving two channels of data with 16-bit precision. G-clamp also includes utilities for measuring current-voltage relations, synaptic strength, and synaptic gain. Taking an approach built on a commercially available software/hardware platform has resulted in a system that is easy to assemble and upgrade. In addition, the graphical programming structure of LabVIEW should make it relatively easy for others to adapt G-clamp for new experimental applications.

Citing Articles

Patch-clamp analysis of nicotinic synapses whose strength straddles the firing threshold of rat sympathetic neurons.

Kullmann P, Horn J Front Neurosci. 2022; 16:869753.

PMID: 36267230 PMC: 9577239. DOI: 10.3389/fnins.2022.869753.

Web-Based Interfaces for Virtual Neuron Model Definition, Network Configuration, Behavioral Experiment Definition and Experiment Results Visualization.

Epelde G, Morgan F, Mujika A, Callaly F, Leskovsky P, McGinley B Front Neuroinform. 2018; 12:80.

PMID: 30483089 PMC: 6243129. DOI: 10.3389/fninf.2018.00080.

A Dynamic Clamp on Every Rig.

Desai N, Gray R, Johnston D eNeuro. 2017; 4(5).

PMID: 29085905 PMC: 5659377. DOI: 10.1523/ENEURO.0250-17.2017.

Nonlinear effects of hyperpolarizing shifts in activation of mutant Na1.7 channels on resting membrane potential.

Estacion M, Waxman S J Neurophysiol. 2017; 117(4):1702-1712.

PMID: 28148645 PMC: 5380781. DOI: 10.1152/jn.00898.2016.

Tonotopic Optimization for Temporal Processing in the Cochlear Nucleus.

Oline S, Ashida G, Burger R J Neurosci. 2016; 36(32):8500-15.

PMID: 27511020 PMC: 4978807. DOI: 10.1523/JNEUROSCI.4449-15.2016.