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

Collins, Morgan N.; Legon, Wynn; Mesce, Karen A.

doi:10.1523/eneuro.0514-20.2021

Cited by 11 publications

(15 citation statements)

References 87 publications

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“…50 Moreover, an increase in tissue temperature would reduce but not enchance its excitability. 51,52 Therefore, the observed effects of tbTUS over the motor cortex are likely related to nonthermal effect. Although how tbTUS excites neurons via mechanical forces is not fully understood, it may induce activation of mechanosensitive voltage-gated sodium and calcium channels.…”

Section: Effects Of Tbtus On Motor Behaviormentioning

confidence: 99%

Induction of Human Motor Cortex Plasticity by Theta Burst Transcranial Ultrasound Stimulation

Zeng,

Darmani,

Fomenko

et al. 2022

Annals of Neurology

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Objective: Transcranial ultrasound stimulation (TUS) is a promising noninvasive brain stimulation technique with advantages of high spatial precision and ability to target deep brain regions. This study aimed to develop a TUS protocol to effectively induce brain plasticity in human subjects. Methods: An 80-second train of theta burst patterned TUS (tbTUS), regularly patterned TUS (rTUS) with the same sonication duration, and sham tbTUS was delivered to the motor cortex in healthy subjects. Transcranial magnetic stimulation (TMS) was used to examine changes in corticospinal excitability, intracortical inhibition and facilitation, and the site of plasticity induction. The effects of motor cortical tbTUS on a visuomotor task and the effects of occipital cortex tbTUS on motor cortical excitability were also tested. Results: The tbTUS produced consistent increase in corticospinal excitability for at least 30 minutes, whereas rTUS and sham tbTUS produced no significant change. tbTUS decreased short-interval intracortical inhibition and increased intracortical facilitation. The effects of TMS in different current directions suggested that the site of the plastic changes was within the motor cortex. tbTUS to the occipital cortex did not change motor cortical excitability. Motor cortical tbTUS shortened movement time in a visuomotor task. Interpretation: tbTUS is a novel and efficient paradigm to induce cortical plasticity in humans. It has the potential to be developed for neuromodulation treatment for neurological and psychiatric disorders, and to advance neuroscience research.

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Section: Effects Of Tbtus On Motor Behaviormentioning

confidence: 99%

Induction of Human Motor Cortex Plasticity by Theta Burst Transcranial Ultrasound Stimulation

Zeng,

Darmani,

Fomenko

et al. 2022

Annals of Neurology

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“…[20][21][22][23] The influence of mechanical vs thermal mechanisms of acoustic stimulation is debated, but it could be a differentiating factor between tFUS and TPS. [24][25][26][27] Future studies could investigate this directly. With respect to model interpretation, the consideration of intensity as a proxy for neuromodulation is rational because it indicates regions in the brain directly affected by ultrasound stimulation.…”

Section: Discussionmentioning

confidence: 99%

Comparison of Transcranial Focused Ultrasound and Transcranial Pulse Stimulation for Neuromodulation: A Computational Study

Truong

Thomas

Hampstead

et al. 2022

Neuromodulation: Technology at the Neural Interface

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Objective: The objective of the study was to investigate transcranial wave propagation through two low-intensity focused ultrasound (LIFU)-based brain stimulation techniques-transcranial focused ultrasound stimulation (tFUS) and transcranial pulse stimulation (TPS). Although tFUS involves delivering long trains of acoustic pulses, the newly introduced TPS delivers ultrashort (~3 μs) pulses repeated at 4 Hz. Accordingly, only a single simulation study with limited geometry currently exists for TPS. We considered a highresolution three-dimensional (3D) whole human head model in addition to water bath simulations. We anticipate that the results of this study will help researchers investigating LIFU have a better understanding of the effects of the two different techniques.Approach: With an objective to first reproduce previous computational results, we considered two spherical tFUS transducers that were previously modeled. We assumed identical parameters (geometry, position, and imaging data set) to demonstrate differences, purely because of the waveform considered. For simulations with a 3D head data set, we also considered a parabolic transducer that has been used for TPS delivery.Results: Our initial results successfully verified previous modeling workflow. The tFUS distribution was characterized by the typical elliptical profile, with its major axis perpendicular to the face of the transducer. The TPS distribution resembled two mirrored meniscus profiles, with its widest diameter oriented parallel to the face of the transducer. The observed intensity value differences were theoretical because the two waveforms differ in both intensity and time. The consideration of a realistic 3D human head model resulted in only a minor distortion of the two waveforms.Significance: This study simulated TPS administration using a 3D realistic image-derived data set. Although our comparison results are strictly limited to the model parameters and assumptions made, we were able to elucidate some clear differences between the two approaches. We hope this initial study will pave the way for systematic comparison between the two approaches in the future.

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“…However, as previously mentioned, lower NSRs at 3.3 MHz may be due to difficulties in properly positioning the focal spot on the neural structure. Furthermore, it is important to consider that local temperature elevations of a few degrees may produce an inhibitory effect and thus contribute to lowering the NSR for FUS applied at 3.3 MHz 55,56 . In particular, a recent study by Collins et al.…”

Section: Discussionmentioning

confidence: 99%

“…Furthermore, it is important to consider that local temperature elevations of a few degrees may produce an inhibitory effect and thus contribute to lowering the NSR for FUS applied at 3.3 MHz. 55,56 In particular, a recent study by Collins et al on an invertebrate medicinal leech model showed that ultrasound parameters capable of generating heat (2-3 • C) induced an inhibitory response as demonstrated by a reduction of close to 43%, on average, in the firing rate of a single motoneuron. 56 Nonetheless, when studying the effects of changing the PRF and number of pulses per FUS stimulus, significant jumps in NSR were observed for very low differences in thermal elevations.…”

Section: Discussionmentioning

confidence: 99%

Neurostimulation success rate of repetitive‐pulse focused ultrasound in an in vivo giant axon model: An acoustic parametric study

et al. 2021

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Purpose: Focused ultrasound (FUS) is a promising tool to develop new modalities of therapeutic neurostimulation. The ability of FUS to stimulate the nervous system,in a noninvasive and spatiotemporally precise manner,has been demonstrated in animals and human subjects, but the underlying biomechanisms are not fully understood yet. The objective of the present study was to investigate the bioeffects involved in the generation of trains of action potentials (APs) by repetitive-pulse FUS stimuli in a simple invertebrate neural model. Methods: The respective influences of different acoustic parameters on the neurostimulation success rate (NSR),defined as the rate of FUS stimuli capable of evoking at least one AP, were explored using the system of afferent nerves and giant fibers of Lumbricus terrestris as neural model. Each parameter was studied independently by administering random FUS sequences while keeping all but one FUS parameter constant. The NSR was evaluated as a function of (i) the spatial-average pulse-average intensity (I sapa ); (ii) the pulse duration (PD); (iii) the pulse repetition frequency (PRF); iv) the number of cycles per pulse (N cycles ); (v) two ultrasound frequencies, f 0 = 1.1 MHz and f 3 = 3.3 MHz, corresponding to the fundamental and third-harmonic resonant frequencies of the FUS transducer, respectively (spherical, radius of curvature: 50 mm); and (vi) levels of emerging stable cavitation and inertial cavitation. Results:The NSR associated to 1.1 MHz repetitive-pulse FUS stimuli was found to increase as a function of increasing I sapa , PD, PRF, and N cycles . When evaluating each parameter at f = 1.1 MHz, it was observed that NSRs close to 100% were achieved when sufficiently elevating their respective values. When computing the NSR as a function of the spatial-average, temporal-average intensity (I sata ), defined as the product of PRF, PD, and I sapa , a significant elevation of the NSR from 0% to close to 100% was measured by increasing I sata from values approximate to 4 W/cm 2 to values higher than 12 W/cm 2 . No clear and consistent trend was observed in trials aimed at exploring the effects of different levels of stable and inertial acoustic cavitation on the NSR. Finally, the feasibility of inducing neural responses with 3.3 MHz repetitive-pulse FUS stimuli was also demonstrated with NSRs reaching up to 60%, in the range of FUS parameters studied. Conclusion:The time-averaged value of the radiation force per unit volume of tissue is proportional to the acoustic intensity. As a result, the observations from this study suggest that the neural structure responding to the stimulus is sensitive to the mean radiation force carried by the FUS sequence, regardless of the combination of FUS parameters giving rise to such force. The results from 682

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

Cited by 11 publications

References 87 publications

Induction of Human Motor Cortex Plasticity by Theta Burst Transcranial Ultrasound Stimulation

Induction of Human Motor Cortex Plasticity by Theta Burst Transcranial Ultrasound Stimulation

Comparison of Transcranial Focused Ultrasound and Transcranial Pulse Stimulation for Neuromodulation: A Computational Study

Neurostimulation success rate of repetitive‐pulse focused ultrasound in an in vivo giant axon model: An acoustic parametric study

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