Radiation Force as a Physical Mechanism for Ultrasonic Neurostimulation of the <i>Ex Vivo</i> Retina

Menz, Mike D.; Ye, Patrick; Firouzi, Kamyar; Nikoozadeh, Amin; Pauly, Kim Butts; Khuri-Yakub, Pierre; Baccus, Stephen A.

doi:10.1523/jneurosci.2394-18.2019

Cited by 94 publications

(118 citation statements)

References 66 publications

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“…Nonetheless, the shear viscosity/relaxation time in our model is reasonable for a soft, gel-like material, and is comparable to fast relaxation times observed experimentally in brain tissue (Arbogast and Margulies, 1999;Abolfathi et al, 2009;Rashid et al, 2012Rashid et al, , 2013. Moreover, the simulated time course of displacement is consistent with experimental measurements of the tissue displacement in response to ultrasound at 43 MHz and 40 W/cm 2 in the salamander retina, which was found to be complete in less than ms (Menz et al, 2019).…”

Section: Effects Of Ultrasound On Action-potential Waveformsupporting

confidence: 85%

“…In conclusion, our results demonstrate that high-frequency ultrasound is a viable and promising modality for neuromodulation applications where frequency is not limited by transmission through the skull, and our insights into the common molecular mechanisms underlying both inhibitory and excitatory effects of high-frequency ultrasound pave the way for rational design and optimization of neuromodulation protocols to consistently produce either inhibitory or excitatory effects. Sources for material properties are as follows: a standard value; b based on typical acoustic properties of plastics (Selfridge, 1985); c following Menz et al (2019), based on (Thijssen et al, 1985); d (Company, 1965); e measured (Prieto et al, 2018); f following Menz et al (2019), based on (de Korte et al, 1994); g based on typical thermal properties of plastics (Gaur and Wunderlich, 1982;Harper, 2006); h typical values for soft tissues (Hand, 1998); i based on typical mechanical properties of plastics (Harper, 2006); j Menz et al (2019), from measurements of ultrasound-induced displacement in the retina; k tissue assumed to be incompressible for small deformations; l see text. ms for the onset and 0.22 mV and 6.7 ms for the offset, for the example shown; mean values (±SEM) were 0.41 ± 0.04 mV and 10.4 ± 1.2 ms for the onset and 0.35 ± 0.04 mv and 9.7 ± 1.7 ms for the offset (N = 15).…”

Section: Discussionmentioning

confidence: 99%

“…Ultrasound can non-invasively modulate action potential activity in neurons in vivo and in vitro, with improved depth penetration and spatial resolution relative to other non-invasive neuromodulation modalities, and it may therefore become an important new technology in basic and clinical neuroscience (Fry et al, 1958;Gavrilov et al, 1996;Tufail et al, 2010;Bystritsky et al, 2011;Fomenko et al, 2018;Blackmore et al, 2019). Investigation of this phenomenon has predominantly focused on low-frequency ultrasound (defined here as less than 3 MHz, although there is no firmly defined boundary between "high" and "low" frequency in the neuromodulation field), but higher ultrasound frequencies have also been shown to modulate action potential firing in vitro (Menz et al, 2013;Menz et al, 2019) and to directly modulate ion channel activity in heterologous systems (Kubanek et al, 2016;Prieto et al, 2018). The focus on lower frequency ultrasound is understandable, since envisioned clinical applications involving transcranial focused ultrasound have been a primary motivation for research on ultrasound neuromodulation, and loss of ultrasound power due to attenuation in the skull limits these applications to low frequency ultrasound.…”

Section: Introductionmentioning

confidence: 99%

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

Prieto

Firouzi

Khuri‐Yakub

et al. 2020

Preprint

Self Cite

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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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Section: Effects Of Ultrasound On Action-potential Waveformsupporting

confidence: 85%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

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

Prieto

Firouzi

Khuri‐Yakub

et al. 2020

Preprint

Self Cite

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“…The number of neurons exposed to the US is inherently lower in the slice than in vivo given that the slice occupies only a small portion of the US focus as opposed to in vivo, where the entire sound focus may interact with a large population of neurons in brain tissue. A similar explanation relating exposure volume to stimulation is offered in both Ye et al 18 and Menz et al 38 Furthermore, several in vivo studies explore higher pressure regimes for USN. In our model pulses above 350 kPa often resulted in slice motion which limited our ability to explore higher pressure.…”

Section: Direct Neuromodulation In the Absence Of Auditory Confoundsmentioning

confidence: 68%

Ultrasound neuromodulation depends on pulse repetition frequency and can modulate inhibitory effects of TTX

Manuel

Kusunose

Zhan

et al. 2020

Sci Rep

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Ultrasound is gaining traction as a neuromodulation method due to its ability to remotely and non-invasively modulate neuronal activity with millimeter precision. However, there is little consensus about optimal ultrasound parameters required to elicit neuromodulation and how specific parameters drive mechanisms that underlie ultrasound neuromodulation. We address these questions in this work by performing a study to determine effective ultrasound parameters in a transgenic mouse brain slice model that enables calcium imaging as a quantitative readout of neuronal activity for ultrasound neuromodulation. We report that (1) calcium signaling increases with the application of ultrasound; (2) the neuronal response rate to ultrasound is dependent on pulse repetition frequency (PRF); and (3) ultrasound can reversibly alter the inhibitory effects of tetrodotoxin (TTX) in pharmacological studies. This study offers mechanistic insight into the PRF dependence of ultrasound neuromodulation and the nature of ultrasound/ion channel interaction.

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“…Furthermore, they varied the acoustic frequency in a wide range between 0.5 and 43 MHz, finding enhanced retinal activity under higher frequencies. This observation argues against any major direct role played by cavitation in ultrasonic stimulation of the retina, as cavitation tends to diminish when the frequency is increased [ 70 ].…”

Section: Ultrasonic Retinal Stimulationmentioning

confidence: 99%

Ultrasonic Retinal Neuromodulation and Acoustic Retinal Prosthesis

Huang

Zhou

et al. 2020

Micromachines

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Ultrasound is an emerging method for non-invasive neuromodulation. Studies in the past have demonstrated that ultrasound can reversibly activate and inhibit neural activities in the brain. Recent research shows the possibility of using ultrasound ranging from 0.5 to 43 MHz in acoustic frequency to activate the retinal neurons without causing detectable damages to the cells. This review recapitulates pilot studies that explored retinal responses to the ultrasound exposure, discusses the advantages and limitations of the ultrasonic stimulation, and offers an overview of engineering perspectives in developing an acoustic retinal prosthesis. For comparison, this article also presents studies in the ultrasonic stimulation of the visual cortex. Despite that, the summarized research is still in an early stage; ultrasonic retinal stimulation appears to be a viable technology that exhibits enormous therapeutic potential for non-invasive vision restoration.

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Radiation Force as a Physical Mechanism for Ultrasonic Neurostimulation of the Ex Vivo Retina

Cited by 94 publications

References 66 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

Ultrasound neuromodulation depends on pulse repetition frequency and can modulate inhibitory effects of TTX

Ultrasonic Retinal Neuromodulation and Acoustic Retinal Prosthesis

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