Single-neuron mechanical perturbation evokes calcium plateaus that excite and modulate the network

Single-neuron mechanical perturbation evokes calcium plateaus that excite and modulate the network

Mechanical stimulation is a promising means to non-invasively excite and modulate neuronal networks with a high spatial resolution. Despite the thorough characterization of the initiation mechanism, whether or how mechanical responses disperse into non-target areas remains to be discovered. Our in v...

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Bibliographic Details
Published in:Scientific reports Vol. 13; no. 1; p. 20669
Main Authors: Cepkenovic, Bogdana, Friedland, Florian, Noetzel, Erik, Maybeck, Vanessa, Offenhäusser, Andreas
Format: Journal Article
Language:English
Published: London Nature Publishing Group UK 24-11-2023
Nature Publishing Group
Nature Portfolio
Subjects:
631/1647/1453/1970
631/1647/1453/2206
631/378/1697/1277
631/378/1697/2603
631/378/3920
631/378/548/1954
631/378/87
Action Potentials - physiology
Calcium
Calcium channels
Calcium influx
Calcium, Dietary
Deformation
Excitability
Gap Junctions
Humanities and Social Sciences
Information processing
Mechanical stimuli
Mechanosensitive channels
multidisciplinary
Neural networks
Neurons
Neurons - physiology
Plateaus
Propagation
Science
Science (multidisciplinary)
Signal transduction
Spatial discrimination
Synapses - physiology
Ultrasonic imaging
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Summary:Mechanical stimulation is a promising means to non-invasively excite and modulate neuronal networks with a high spatial resolution. Despite the thorough characterization of the initiation mechanism, whether or how mechanical responses disperse into non-target areas remains to be discovered. Our in vitro study demonstrates that a single-neuron deformation evokes responses that propagate to about a third of the untouched neighbors. The responses develop via calcium influx through mechanosensitive channels and regeneratively propagate through the neuronal ensemble via gap junctions. Although independent of action potentials and synapses, mechanical responses reliably evoke membrane depolarizations capable of inducing action potentials both in the target and neighbors. Finally, we show that mechanical stimulation transiently potentiates the responding assembly for further inputs, as both gain and excitability are transiently increased exclusively in neurons that respond to a neighbor’s mechanical stimulation. The findings indicate a biological component affecting the spatial resolution of mechanostimulation and point to a cross-talk in broad-network mechanical stimulations. Since giga-seal formation in patch-clamp produces a similar mechanical stimulus on the neuron, our findings inform which neuroscientific questions could be reliably tackled with patch-clamp and what recovery post-gigaseal formation is necessary.
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ISSN:2045-2322
2045-2322
DOI:10.1038/s41598-023-47090-z