Suppression of EEG visual-evoked potentials in rats through neuromodulatory focused ultrasound

Kim, Hyung-Min; Park, Michael Y.; Lee, Stephanie D.; Lee, Wonhye; Chiu, Alan W. L.; Yoo, Seung‐Schik

doi:10.1097/wnr.0000000000000330

Cited by 123 publications

(106 citation statements)

References 18 publications

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“…As reported by Min et al , ultrasound may induce a suppression of seizure activity [21] and EEG based visual evoked response potentials [47]. Since calcium imaging is an imaging modality that relies on neural depolarization, neural suppression, characterized by a lack of depolarization, is difficult to observe due to the lack of increase in intracellular calcium.…”

Section: Tfus Indirectly Activates Auditory Cortex and Subsequently Pmentioning

confidence: 99%

On the neuromodulatory pathways of the in vivo brain by means of transcranial focused ultrasound

Niu

2018

Current Opinion in Biomedical Engineering

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For last decade, low-intensity transcranial focused ultrasound (tFUS) has been rapidly developed for a myriad of successful applications in neuromodulation. tFUS possesses high spatial resolution, focality and depth penetration as a noninvasive neuromodulation tool. Despite the promise, confounding activation can be observed in rodents when stimulation parameters are not selected carefully. Here we summarize the existing classes of observations for ultrasound neuromodulation: ultrasound directly activates a localized area, or ultrasound indirectly activates auditory pathways, which further propagates to other cortical networks. We also present control in vivo animal studies, which suggest that underlying tFUS brain modulation is characterized by localized activation independent of auditory networks activations.

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Section: Tfus Indirectly Activates Auditory Cortex and Subsequently Pmentioning

confidence: 99%

On the neuromodulatory pathways of the in vivo brain by means of transcranial focused ultrasound

Niu

2018

Current Opinion in Biomedical Engineering

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“…Ultrasound neuromodulation has been successfully performed transcranially in various animal species, including mice (King et al 2013; King et al 2014; Mehić et al 2014; Tufail et al 2010), rats (Kim et al 2012; Kim et al 2014; Kim et al 2015; Min et al 2011; Younan et al 2013), sheep (Lee et al 2016), monkeys (Deffieux et al 2013), and even humans (Lee et al 2015; Legon et al 2014). Histological techniques have confirmed that it is possible to deliver sonications powerful enough to elicit ultrasound neuromodulation without causing damage to tissues (Tufail et al 2010; Yoo et al 2011).…”

Section: Introductionmentioning

confidence: 99%

Frequency Dependence of Ultrasound Neurostimulation in the Mouse Brain

Brown

Pauly

2016

Ultrasound in Medicine & Biology

195

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Ultrasound neuromodulation holds promise as a non-invasive technique for neuromodulation of the central nervous system. However, much remains to be determined about how the technique can be transformed into a useful technology, including the effect of ultrasound frequency. Previous studies have demonstrated neuromodulation in vivo using frequencies less than 1 MHz, with a trend towards improved efficacy with lower frequency. However, using higher frequencies could offer improved ultrasound spatial resolution. We investigate the ultrasound neuromodulation effects in mice at various frequencies both below and above 1 MHz and find that frequencies up to 2.9 MHz can still be effective for generating motor responses, but also confirm that as frequency increases, sonications require significantly more intensity to achieve equivalent efficacy. We argue that our results provide evidence that favors either a particle displacement or a cavitation-based mechanism for the phenomenon of ultrasound neuromodulation.

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“…The acoustic neuromodulatory effects can be tailored as either excitatory or suppressive, depending on the sonication parameters [11, 12]. Accumulating ex vivo [13, 14] and in vivo [12, 15–18] evidence shows that acoustic pressure waves delivered to localized brain structures modulate their excitability using low-level acoustic intensity (i.e., compatible with potential human application [19, 20]).…”

Section: Introductionmentioning

confidence: 99%

Simultaneous acoustic stimulation of human primary and secondary somatosensory cortices using transcranial focused ultrasound

et al. 2016

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BackgroundTranscranial focused ultrasound (FUS) is gaining momentum as a novel non-invasive brain stimulation method, with promising potential for superior spatial resolution and depth penetration compared to transcranial magnetic stimulation or transcranial direct current stimulation. We examined the presence of tactile sensations elicited by FUS stimulation of two separate brain regions in humans—the primary (SI) and secondary (SII) somatosensory areas of the hand, as guided by individual-specific functional magnetic resonance imaging data.ResultsUnder image-guidance, acoustic stimulations were delivered to the SI and SII areas either separately or simultaneously. The SII areas were divided into sub-regions that are activated by four types of external tactile sensations to the palmar side of the right hand—vibrotactile, pressure, warmth, and coolness. Across the stimulation conditions (SI only, SII only, SI and SII simultaneously), participants reported various types of tactile sensations that arose from the hand contralateral to the stimulation, such as the palm/back of the hand or as single/neighboring fingers. The type of tactile sensations did not match the sensations that are associated with specific sub-regions in the SII. The neuro-stimulatory effects of FUS were transient and reversible, and the procedure did not cause any adverse changes or discomforts in the subject’s mental/physical status.ConclusionsThe use of multiple FUS transducers allowed for simultaneous stimulation of the SI/SII in the same hemisphere and elicited various tactile sensations in the absence of any external sensory stimuli. Stimulation of the SII area alone could also induce perception of tactile sensations. The ability to stimulate multiple brain areas in a spatially restricted fashion can be used to study causal relationships between regional brain activities and their cognitive/behavioral outcomes.Electronic supplementary materialThe online version of this article (doi:10.1186/s12868-016-0303-6) contains supplementary material, which is available to authorized users.

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Suppression of EEG visual-evoked potentials in rats through neuromodulatory focused ultrasound

Cited by 123 publications

References 18 publications

On the neuromodulatory pathways of the in vivo brain by means of transcranial focused ultrasound

On the neuromodulatory pathways of the in vivo brain by means of transcranial focused ultrasound

Frequency Dependence of Ultrasound Neurostimulation in the Mouse Brain

Simultaneous acoustic stimulation of human primary and secondary somatosensory cortices using transcranial focused ultrasound

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