Investigating a new neuromodulation treatment for brain disorders using synchronized activation of multimodal pathways

Markovitz, Craig D.; Smith, Benjamin T.; Gloeckner, Cory D.; Lim, Hubert H.

doi:10.1038/srep09462

Cited by 25 publications

(30 citation statements)

References 61 publications

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“…However, DBS and other invasive approaches have risks associated with surgery and involve high costs. TMS, tDCS, and other noninvasive approaches do not require surgery, but they often do not sufficiently achieve targeted activation (Brunoni et al, 2011;Deng et al, 2013;Markovitz et al, 2015a). More recently, ultrasound (US) stimulation has emerged as a potential approach that can address the trade-offs faced by modern neuromodulation technologies in that it can be applied noninvasively with the ability to activate or modulate targeted brain regions.…”

Section: Introductionmentioning

confidence: 99%

Ultrasound Produces Extensive Brain Activation via a Cochlear Pathway

Guo

Hamilton

Offutt

et al. 2018

Neuron

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238

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Ultrasound (US) can noninvasively activate intact brain circuits, making it a promising neuromodulation technique. However, little is known about the underlying mechanism. Here, we apply transcranial US and perform brain mapping studies in guinea pigs using extracellular electrophysiology. We find that US elicits extensive activation across cortical and subcortical brain regions. However, transection of the auditory nerves or removal of cochlear fluids eliminates the US-induced activity, revealing an indirect auditory mechanism for US neural activation. Our findings indicate that US activates the ascending auditory system through a cochlear pathway, which can activate other non-auditory regions through cross-modal projections. This cochlear pathway mechanism challenges the idea that US can directly activate neurons in the intact brain, suggesting that future US stimulation studies will need to control for this effect to reach reliable conclusions.

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Section: Introductionmentioning

confidence: 99%

Ultrasound Produces Extensive Brain Activation via a Cochlear Pathway

Guo

Hamilton

Offutt

et al. 2018

Neuron

Self Cite

238

220

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“…For A1 activation, the US transducer was placed over A1 and coupled directly to the brain via agarose gel. The A1 probe was placed such that electrical stimulation resulted in ICC activation, based on previous studies (Markovitz et al, 2015a). US paradigms (single pulse or 10 Hz-1.5 kHz PRF, 0.1-10 msec PD, 25 kPa-2 MPa pressure, 500 msec PD; Table S1) were tested in A1.…”

Section: Methodsmentioning

confidence: 99%

“…However, DBS and other invasive 5 approaches have risks associated with surgery and involve high costs. TMS, tDCS and other noninvasive 6 approaches do not require surgery, but they do not sufficiently achieve targeted activation (Brunoni et al, 7 2011;Deng et al, 2013;Markovitz et al, 2015a). More recently, ultrasound (US) stimulation has emerged 8 as a potential approach that can address the trade-offs faced by modern neuromodulation technologies, in 9 that it can be applied noninvasively but with the ability to activate or modulate targeted brain regions.…”

Section: Introductionmentioning

confidence: 99%

Ultrasound Produces Extensive Brain Activation via a Cochlear Pathway

Guo

Hamilton

Offutt

et al. 2017

Preprint

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SummaryUltrasound (US) can noninvasively activate intact brain circuits, making it a promising neuromodulation technique. However, little is known about the underlying mechanism. Here, we apply transcranial US and perform brain mapping studies in guinea pigs using extracellular electrophysiology. We find that US elicits extensive activation across cortical and subcortical brain regions. However, transection of the auditory nerves or removal of cochlear fluids eliminates the US-induced activity, revealing an indirect auditory mechanism for US neural activation. US likely vibrates the cerebrospinal fluid in the brain, which is continuous with the fluid in the cochlea via cochlear aqueducts; thus, US can activate the ascending auditory pathways and other non-auditory regions through cross-modal projections. This finding of a cochlear fluidinduced vibration mechanism challenges the idea that US can directly activate neurons in the intact brain, suggesting that future US stimulation studies will need to control for this effect to reach reliable conclusions.peer-reviewed)

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“…However, given that electromagnetic fields obey Laplace's equation, it is impossible to create local maxima in the field intensity, no matter what the configuration of the source coils (Norton, 2003). TMS often does not achieve adequate spatial resolution on the millimeter scale, and it is helpless for specific activation of neuronal cells in a region less than 5 mm (Deng et al, 2013;Markovitz et al, 2015;Guo et al, 2018). In addition, because its magnetic focusing becomes poorer as the penetration depth increases, TMS is not suitable for the stimulation of deep brain tissues.…”

Section: Introductionmentioning

confidence: 99%

High-Resolution Transcranial Electrical Simulation for Living Mice Based on Magneto-Acoustic Effect

et al. 2019

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Transcranial electrical stimulation is an important neuromodulation tool, which has been widely applied in the cognitive sciences and in the treatment of neurological and psychiatric diseases. In this work, a novel non-invasive method of transcranial electrical stimulation with high-resolution transcranial magneto-acoustic stimulation (TMAS) method has been tested experimentally in living mice for the first time. It can achieve spatial resolution of 2 mm in the cortex and even in the deep brain regions. The induced electrical field of TMAS was simulated and measured using a test sample. Then, an animal experimental system was built, and the healthy as well as Parkinson's disease (PD) mice were simulated by TMAS in vivo. To investigate the effect of transcranial ultrasound stimulation (TUS) at the same time as TMAS, a TUS group was added in the experiments and its results compared with those of the TMAS group. The results not only demonstrate the high-resolution ability and safety of TMAS, but also show that both TMAS and TUS improved the synaptic plasticity of the PD mice and might improve the spatial learning and memory ability of the healthy mice and the PD mice, although the improvement performance of the TMAS group was superior to that of the TUS-group. Based on the in vivo TMAS studies, we propose that TMAS functions as a dual-mode stimulation combining the electric field of the magnetoacoustic effect and the mechanical force of TUS. Our results also provide an explanation of the mechanism of TMAS. This research suggests that future use of US stimulation in magnetic resonance imaging (MRI)-guided studies should involve careful consideration of the induced magneto-acoustic electrical field caused by the static magnetic field of MRI.

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Investigating a new neuromodulation treatment for brain disorders using synchronized activation of multimodal pathways

Cited by 25 publications

References 61 publications

Ultrasound Produces Extensive Brain Activation via a Cochlear Pathway

Ultrasound Produces Extensive Brain Activation via a Cochlear Pathway

Ultrasound Produces Extensive Brain Activation via a Cochlear Pathway

High-Resolution Transcranial Electrical Simulation for Living Mice Based on Magneto-Acoustic Effect

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