Manipulation of Subcortical and Deep Cortical Activity in the Primate Brain Using Transcranial Focused Ultrasound Stimulation

Folloni, Davide; Verhagen, Lennart; Mars, Rogier B.; Fouragnan, Elsa; Constans, Charlotte; Aubry, Jean‐François; Rushworth, Matthew; Sallet, Jérôme

doi:10.1016/j.neuron.2019.01.019

Cited by 273 publications

(246 citation statements)

References 36 publications

(71 reference statements)

Supporting

Mentioning

223

Contrasting

Order By: Relevance

“…1b) delivered ultrasound uniformly to neurons throughout our field of view. We used a frequency of 300 kHz, within the range utilized in recent studies in a variety of organisms Folloni et al, 2019;Lee et al, 2015;Lee et al, 2016a;Legon et al, 2018a;Legon et al, 2018b;Legon et al, 2014;Leo Ai, 2018;Wattiez et al, 2017), and continuous-wave stimulation, which was found to be as effective as pulsed ultrasound (King et al, 2013). The interpulse interval was fixed at 20 sec to allow a return to baseline.…”

Section: Focused Ultrasound Robustly Activates Cortical Neuronsmentioning

confidence: 99%

“…In contrast, focused ultrasound (FUS) has the potential to modulate neural activity in deep-brain regions with millimeter spatial precision based on the penetrance of sound waves in bone and soft tissue. Recently, transcranial FUS in the frequency range of 0.25-1 MHz and intensity of 1-100 W/cm 2 (ISPPA) has been shown to elicit neural and behavioral responses in small King et al, 2013;Sharabi et al, 2018;Tufail et al, 2010;Ye et al, 2016;Younan et al, 2013) and large (Dallapiazza et al, 2018;Deffieux et al, 2013;Folloni et al, 2019;Lee et al, 2016b;Verhagen et al, 2019;Wattiez et al, 2017;Yoo et al, 2011) model animals and humans (Lee et al, 2015;Lee et al, 2016a;Legon et al, 2018a;Legon et al, 2014;Leo Ai, 2018) without genetic or chemical alterations or deleterious side effects, even with chronic stimulation . These studies have driven widespread interest in the development of FUS as a research tool in neuroscience and a strategy for disease treatment (Naor et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

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

Yoo

Mittelstein

Hurt

et al. 2020

Preprint

View full text Add to dashboard Cite

Ultrasonic neuromodulation has the unique potential to provide non-invasive control of neural activity in deep brain regions with high spatial precision and without chemical or genetic modification. However, the biomolecular and cellular mechanisms by which focused ultrasound excites mammalian neurons have remained unclear, posing significant challenges for the use of this technology in research and potential clinical applications. Here, we show that focused ultrasound excites neurons through a primarily mechanical mechanism mediated by specific calcium-selective mechanosensitive ion channels. The activation of these channels results in a gradual build-up of calcium, which is amplified by calcium-and voltage-gated channels, generating a burst firing response. Cavitation, temperature changes, large-scale deformation, and synaptic transmission are not required for this excitation to occur. Pharmacological and genetic inhibition of specific ion channels leads to reduced responses to ultrasound, while over-expressing these channels results in stronger ultrasonic stimulation. These findings provide a critical missing explanation for the effect of ultrasound on neurons and facilitate the further development of ultrasonic neuromodulation and sonogenetics as unique tools for neuroscience research.

show abstract

Section: Focused Ultrasound Robustly Activates Cortical Neuronsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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

Yoo

Mittelstein

Hurt

et al. 2020

Preprint

View full text Add to dashboard Cite

show abstract

“…Pilot studies have investigated the neural effects of ultrasound parameters, such as ultrasound fundamental frequencies (UFF), intensities (UI), durations (UD), duty cycles (UDC), pulse repetition frequencies (UPRF), etc. Besides a few human studies (Hameroff et al, 2013;Lee et al, 2016b;Legon et al, 2014), animal models, such as worms (Ibsen et al, 2015;Kubanek et al, 2018;Zhou et al, 2017), rodents (Tufail et al, 2010;Ye et al, 2016;Yu et al, 2016), rabbits , swine (Dallapiazza et al, 2018), and monkeys Folloni et al, 2019), have been utilized to investigate the effects of ultrasonic parameters and acoustic-induced effects. tFUS have been observed to induce behavioral changes, e.g.…”

Section: Introductionmentioning

confidence: 99%

Intrinsic Cell-type Selectivity and Inter-neuronal Connectivity Alteration by Transcranial Focused Ultrasound

Kang

Niu²,

Krook-Magnuson

et al. 2019

Preprint

View full text Add to dashboard Cite

Transcranial focused ultrasound (tFUS) is a promising neuromodulation technique, but its mechanisms remain unclear. We investigate the effect of tFUS stimulation on different neuron types and synaptic connectivity in in vivo anesthetized rodent brains.Single units were separated into regular-spiking and fast-spiking units based on their extracellular spike shapes, further validated in transgenic optogenetic mice models of light-excitable excitatory and inhibitory neurons. For the first time, we show that excitatory neurons are significantly less responsive to low ultrasound pulse repetition frequencies (UPRFs), whereas the spike rates of inhibitory neurons do not change significantly across all UPRF levels. Our results suggest that we can preferentially target specific neuron types noninvasively by altering the tFUS UPRF. We also report in vivo observation of long-term synaptic connectivity changes induced by noninvasive tFUS in rats. This finding suggests tFUS can be used to encode temporally dependent stimulation paradigms into neural circuits and non-invasively elicit long-term changes in synaptic connectivity.

show abstract

“…Studies of neural stimulation might be able to provide causal evidence of cerebellar compensation in brain disorders, and indeed, recent studies in neuropsychiatry report behavioral improvement after cerebellar stimulation [129,130]. Technological advancements that allow targeting small and deep brain structures [131][132][133][134][135] underscore the potential for cerebellar stimulation to become a useful therapeutic modality in the clinical treatment of cognitive dysfunction. Recent reports also suggest that it might be relevant to investigate surgical correction of gross cerebellar structural abnormalities such as Chiari malformation and posterior fossa arachnoid cysts as an additional cerebellar-focused intervention to relieve brain-wide dysfunction [136].…”

Section: Cerebellar Cognitive Reserve (Guell X Schmahmann Jd)mentioning

confidence: 99%

Consensus Paper. Cerebellar Reserve: From Cerebellar Physiology to Cerebellar Disorders

et al. 2019

View full text Add to dashboard Cite

Cerebellar reserve refers to the capacity of the cerebellum to compensate for tissue damage or loss of function resulting from many different etiologies. When the inciting event produces acute focal damage (e.g., stroke, trauma), impaired cerebellar function may be compensated for by other cerebellar areas or by extracerebellar structures (i.e., structural cerebellar reserve). In contrast, when pathological changes compromise cerebellar neuronal integrity gradually leading to cell death (e.g., metabolic and immune-mediated cerebellar ataxias, neurodegenerative ataxias), it is possible that the affected area itself can compensate for the slowly evolving cerebellar lesion (i.e., functional cerebellar reserve). Here, we examine cerebellar reserve from the perspective of the three cornerstones of clinical ataxiology: control of ocular movements, coordination of voluntary axial and appendicular movements, and cognitive functions. Current evidence indicates that cerebellar reserve is potentiated by environmental enrichment through the mechanisms of autophagy and synaptogenesis, suggesting that cerebellar reserve is not rigid or fixed, but exhibits plasticity potentiated by experience. These conclusions have therapeutic implications. During the period when cerebellar reserve is preserved, treatments should be directed at stopping disease progression and/or limiting the pathological process. Simultaneously, cerebellar reserve may be potentiated using multiple approaches. Potentiation of cerebellar reserve may lead to compensation and restoration of function in the setting of cerebellar diseases, and also in disorders primarily of the cerebral hemispheres by enhancing cerebellar mechanisms of action. It therefore appears that cerebellar reserve, and the underlying plasticity of cerebellar microcircuitry that enables it, may be of critical neurobiological importance to a wide range of neurological/neuropsychiatric conditions.

show abstract

Manipulation of Subcortical and Deep Cortical Activity in the Primate Brain Using Transcranial Focused Ultrasound Stimulation

Cited by 273 publications

References 36 publications

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

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

Intrinsic Cell-type Selectivity and Inter-neuronal Connectivity Alteration by Transcranial Focused Ultrasound

Consensus Paper. Cerebellar Reserve: From Cerebellar Physiology to Cerebellar Disorders

Contact Info

Product

Resources

About