Computer modeling of whole-cell voltage-clamp analyses to delineate guidelines for good practice of manual and automated patch-clamp

The patch-clamp technique and more recently the high throughput patch-clamp technique have contributed to major advances in the characterization of ion channels. However, the whole-cell voltage-clamp technique presents certain limits that need to be considered for robust data generation. One major c...

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Bibliographic Details
Published in:Scientific reports 2021-02, Vol.11 (1), p.3282-3282, Article 3282
Main Authors: Montnach, Jérôme, Lorenzini, Maxime, Lesage, Adrien, Simon, Isabelle, Nicolas, Sébastien, Moreau, Eléonore, Marionneau, Céline, Baró, Isabelle, De Waard, Michel, Loussouarn, Gildas
Format: Article
Language:English
Subjects:
631/443/592
631/57
631/57/2266
631/57/2283
Animals
Cell lines
Cells, Cultured
Heart
Humanities and Social Sciences
Inactivation
Ion channels
Ion Channels - metabolism
Ion currents
Life Sciences
Mathematical models
Membrane potential
Membrane Potentials
Mice
Models, Biological
multidisciplinary
Myocytes, Cardiac - metabolism
Patch-Clamp Techniques
Pharmacology
Potassium
Potassium channels (voltage-gated)
Science
Science (multidisciplinary)
Sodium channels (voltage-gated)
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Summary:The patch-clamp technique and more recently the high throughput patch-clamp technique have contributed to major advances in the characterization of ion channels. However, the whole-cell voltage-clamp technique presents certain limits that need to be considered for robust data generation. One major caveat is that increasing current amplitude profoundly impacts the accuracy of the biophysical analyses of macroscopic ion currents under study. Using mathematical kinetic models of a cardiac voltage-gated sodium channel and a cardiac voltage-gated potassium channel, we demonstrated how large current amplitude and series resistance artefacts induce an undetected alteration in the actual membrane potential and affect the characterization of voltage-dependent activation and inactivation processes. We also computed how dose–response curves are hindered by high current amplitudes. This is of high interest since stable cell lines frequently demonstrating high current amplitudes are used for safety pharmacology using the high throughput patch-clamp technique. It is therefore critical to set experimental limits for current amplitude recordings to prevent inaccuracy in the characterization of channel properties or drug activity, such limits being different from one channel type to another. Based on the predictions generated by the kinetic models, we draw simple guidelines for good practice of whole-cell voltage-clamp recordings.
ISSN:2045-2322
2045-2322
DOI:10.1038/s41598-021-82077-8