Focused ultrasound excites neurons via mechanosensitive calcium accumulation and ion channel amplification

Yoo, Seung Jick; Mittelstein, David R.; Hurt, Robert C.; Lacroix, Jérôme J.; Shapiro, Mikhail G.

doi:10.1101/2020.05.19.101196

Cited by 34 publications

(49 citation statements)

References 77 publications

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“…The mechanically gated channel Piezo2 is expressed in a subset of CA1 pyramidal neurons ( Wang and Hamill, 2020 ). Piezo1 ( Qiu et al, 2019 ) and TRP (transient receptor potential) channels ( Oh et al, 2020 ; Yoo et al, 2020 ) have been experimentally linked to ultrasound neuromodulation effects. In addition, most ion channels and membrane proteins, while not functioning physiologically as mechanoreceptors, are sensitive to mechanical stimuli to some extent, either through the energetics of their interactions with the hydrophobic core of the lipid bilayer or through mechanical interactions with the cytoskeleton or extracellular matrix.…”

Section: Discussionmentioning

confidence: 99%

Spike frequency–dependent inhibition and excitation of neural activity by high-frequency ultrasound

Prieto

Firouzi

Khuri‐Yakub

et al. 2020

Journal of General Physiology

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Ultrasound can modulate action potential firing in vivo and in vitro, but the mechanistic basis of this phenomenon is not well understood. To address this problem, we used patch-clamp recording to quantify the effects of focused, high-frequency (43 MHz) ultrasound on evoked action potential firing in CA1 pyramidal neurons in acute rodent hippocampal brain slices. We find that ultrasound can either inhibit or potentiate firing in a spike frequency–dependent manner: at low (near-threshold) input currents and low firing frequencies, ultrasound inhibits firing, while at higher input currents and higher firing frequencies, ultrasound potentiates firing. The net result of these two competing effects is that ultrasound increases the threshold current for action potential firing, the slope of frequency-input curves, and the maximum firing frequency. In addition, ultrasound slightly hyperpolarizes the resting membrane potential, decreases action potential width, and increases the depth of the after-hyperpolarization. All of these results can be explained by the hypothesis that ultrasound activates a sustained potassium conductance. According to this hypothesis, increased outward potassium currents hyperpolarize the resting membrane potential and inhibit firing at near-threshold input currents but potentiate firing in response to higher-input currents by limiting inactivation of voltage-dependent sodium channels during the action potential. This latter effect is a consequence of faster action potential repolarization, which limits inactivation of voltage-dependent sodium channels, and deeper (more negative) after-hyperpolarization, which increases the rate of recovery from inactivation. Based on these results, we propose that ultrasound activates thermosensitive and mechanosensitive two-pore-domain potassium (K2P) channels through heating or mechanical effects of acoustic radiation force. Finite-element modeling of the effects of ultrasound on brain tissue suggests that the effects of ultrasound on firing frequency are caused by a small (<2°C) increase in temperature, with possible additional contributions from mechanical effects.

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Section: Discussionmentioning

confidence: 99%

Spike frequency–dependent inhibition and excitation of neural activity by high-frequency ultrasound

Prieto

Firouzi

Khuri‐Yakub

et al. 2020

Journal of General Physiology

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“…An additional primary or complementary source of [K + ] O may be via two-pore potassium channels, which are thermosensitive ( Schneider et al, 2014 ), and whose conductance increases on exposure to US ( Kubanek et al, 2016 ) by a reportedly thermal mechanism ( Prieto et al, 2020 ). Importantly, both classes of potassium channels are expressed ubiquitously by neurons, and a mechanism targeting these channels would circumvent the need to limit US-based neuromodulation therapies to classes of cells that express ion channels susceptible to US mechanical activation, including Piezo ( Prieto et al, 2018 ), TRP ( Yoo et al, 2020 ), and DEG/ENaC/ASIC ( Kubanek et al, 2018 ), or to introduce non-endogenous mechanosensitive ion channels in desired target tissue a la sonogenetics ( Ibsen et al, 2015 ). Furthermore, given safety constraints associated with high pressures that may otherwise be required to modulate non-sensory neurons mechanically, thermal applications may be more practical and versatile than mechanical ones.…”

Section: Discussionmentioning

confidence: 99%

“…Population-level measurements can be difficult to interpret, as effects that appear to be direct on target tissues may result from mechanical activation of synaptically-coupled sensory neurons. Examples include auditory hair cells, which can produce widespread cortical activation following US brain application ( Guo et al, 2018 ; Sato et al, 2018 ), and cells expressing ion channels sensitive to US, including members of the Piezo ( Prieto et al, 2018 ), TRP ( Yoo et al, 2020 ), and DEG/ENaC/ASIC ( Kubanek et al, 2018 ) ion channel families, which are most commonly associated with sensory neurons.…”

Section: Introductionmentioning

confidence: 99%

The Inhibitory Thermal Effects of Focused Ultrasound on an Identified, Single Motoneuron

Collins

Legon

Mesce

2021

eNeuro

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Focused ultrasound (US) is an emerging neuromodulation technology that has gained much attention due to its ability to modulate, noninvasively, neuronal activity in a variety of animals, including humans. However, there has been considerable debate about exactly which types of neurons can be influenced and what underlying mechanisms are in play. Are US-evoked motor changes driven indirectly by activated mechanosensory inputs, or more directly via central interneurons or motoneurons?Although it has been shown that US can mechanically depolarize mechanosensory neurons, there are no studies that have yet tested how identified motoneurons respond directly to US and what the underlying mechanism might be. Here, we examined the effects of US on a single, identified motoneuron within a well-studied and tractable invertebrate preparation, the medicinal leech, Hirudo verbana. Our approach aimed to clarify single neuronal responses to US, which may be obscured in other studies whereby US is applied across a diverse population of cells. We found that US has the ability to inhibit tonic spiking activity through a predominately thermal mechanism. USevoked effects persisted after blocking synaptic inputs, indicating that its actions were direct. Experiments also revealed that US-comparable heating blocked the axonal conduction of spontaneous action potentials. Finally, we found no evidence that US had significant mechanical effects on the neurons tested, a finding counter to prevailing views. We conclude that a non-sensory neuron can be directly inhibited via a thermal mechanism, a finding that holds promise for clinical neuromodulatory applications.

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“…The mechanically gated channel Piezo2 is expressed in a subset of CA1 pyramidal neurons (Wang and Hamill, 2020). Piezo1 (Qiu et al, 2019) and TRP channels (Oh et al, 2020;Yoo et al, 2020) have been experimentally linked to ultrasound neuromodulation effects. In addition, most ion channels and membrane proteins, while not functioning physiologically as mechanoreceptors, are sensitive to mechanical stimuli to some extent, either through the energetics of their interactions with hydrophobic core of the lipid bilayer or through mechanical interactions with the cytoskeleton or extracellular matrix.…”

Section: Discussionmentioning

confidence: 99%

Spike-frequency dependent inhibition and excitation of neural activity by high-frequency ultrasound

Prieto

Firouzi

Khuri‐Yakub

et al. 2020

Preprint

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Prieto et al. describe how ultrasound can either inhibit or potentiate action potential firing in hippocampal pyramidal neurons and demonstrate that these effects can be explained by increased potassium conductance. ABSTRACTUltrasound can modulate action potential firing in vivo and in vitro, but the mechanistic basis of this phenomenon is not well understood. To address this problem, we used patch-clamp recording to quantify the effects of focused, high-frequency (43 MHz) ultrasound on evoked action potential firing in CA1 pyramidal neurons in acute rodent hippocampal brain slices. We find that ultrasound can either inhibit or potentiate firing in a spike-frequency-dependent manner: at low (nearthreshold) input currents and low firing frequencies, ultrasound inhibits firing, while at higher input currents and higher firing frequencies, ultrasound potentiates firing. The net result of these two competing effects is that ultrasound increases the threshold current for action potential firing, the slope of frequency-input curves, and the maximum firing frequency. In addition, ultrasound slightly hyperpolarizes the resting membrane potential, decreases action potential width, and increases the depth of the afterhyperpolarization. All of these results can be explained by the hypothesis that ultrasound activates a sustained potassium conductance. According to this hypothesis, increased outward potassium currents hyperpolarize the resting membrane potential and inhibit firing at near-threshold input currents, but potentiate firing in response to higher input currents by limiting inactivation of voltage-dependent sodium channels during the action potential. This latter effect is a consequence of faster action-potential repolarization, which limits inactivation of voltage-dependent sodium channels, and deeper (more negative) afterhyperpolarization, which increases the rate of recovery from inactivation. Based on these results we propose that ultrasound activates thermosensitive and mechanosensitive, voltage-insensitive two-poredomain potassium (K2P) channels, through heating or mechanical effects of acoustic radiation force. Finite-element modelling of the effects of ultrasound on brain tissue suggests that the effects of ultrasound on firing frequency are caused by a small (less than 2°C) increase in temperature, with possible additional contributions from mechanical effects. 93force produced by reflection of the acoustic wave at the interface between the solution and the air 94 above it (Duck, 1998)). The mound of fluid was then aligned in the x-y plane to the center of a 95 reticle in one eyepiece of the dissecting microscope, and, after adding additional ACSF and the 96 tissue sample to the chamber, the center of the reticle was aligned with the region of the tissue 97 targeted for patch-clamp recording. The ultrasound intensity (50 W/cm 2 ) is the spatial peak, pulse 98 average intensity for the free field. The interval between ultrasound applications was at least 12 99 seconds. 101Electrophysiology. Current clamp re...

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Focused ultrasound excites neurons via mechanosensitive calcium accumulation and ion channel amplification

Cited by 34 publications

References 77 publications

Spike frequency–dependent inhibition and excitation of neural activity by high-frequency ultrasound

Spike frequency–dependent inhibition and excitation of neural activity by high-frequency ultrasound

The Inhibitory Thermal Effects of Focused Ultrasound on an Identified, Single Motoneuron

Spike-frequency dependent inhibition and excitation of neural activity by high-frequency ultrasound

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