Magnetic Temporal Interference for Noninvasive Focal Brain Stimulation

Non-invasive stimulation of deep brain regions has been a major goal for neuroscience and neuromodulation in the past three decades. Transcranial magnetic stimulation (TMS), for instance, cannot target deep regions in the brain without activating the overlying tissues and has a poor spatial resolution. In this manuscript, we propose a new concept that relies on the temporal interference of two high-frequency magnetic fields generated by two electromagnetic solenoids. To illustrate the concept, custom solenoids were fabricated and optimized to generate temporal interfering electric fields for rodent brain stimulation. C-Fos expression was used to track neuronal activation. C-Fos expression was not present in regions impacted by only one high-frequency magnetic field indicating ineffective recruitment of neural activity in non-target regions. In contrast, regions impacted by two fields that interfere to create a low-frequency envelope display a strong increase in c-Fos expression. Therefore, this magnetic temporal interference solenoid-based system provides a framework to perform further stimulation studies that would investigate the advantages it could bring over conventional TMS systems.

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Efficacy and acceptability of non-invasive brain stimulation for the treatment of adult unipolar and bipolar depression: A systematic review and meta-analysis of randomised sham-controlled trials

10.1101/287656 ◽

2018 ◽

Author(s):

Julian Mutz ◽

Daniel R. Edgcumbe ◽

Andre R. Brunoni ◽

Cynthia H.Y. Fu

Keyword(s):

Brain Stimulation ◽

High Frequency ◽

Bipolar Depression ◽

Meta Analysis ◽

Low Frequency ◽

Controlled Trials ◽

Female Response ◽

Non Invasive ◽

Left Dlpfc ◽

Severity Scores

AbstractWe examined the efficacy and acceptability of non-invasive brain stimulation in adult unipolar and bipolar depression. Randomised sham-controlled trials of transcranial direct current stimulation (tDCS), transcranial magnetic stimulation (TMS) and theta-burst stimulation (TBS), without co-initiation of another treatment, were included. We analysed response, remission and all-cause discontinuation rates, and depression severity scores. Fifty-four studies were included (N = 2,959, mean age = 44.94 years, 61.98% female). Response rates demonstrated efficacy of high-frequency rTMS over the left DLPFC (OR = 3.94, 95% CI [2.52; 6.15]), right-sided low-frequency rTMS (OR = 7.44, 95% CI [2.06; 26.83]) bilateral rTMS (OR = 3.68, 95% CI [1.66; 8.13]), deep TMS (OR = 1.69, 95% CI [1.003; 2.85]), intermittent TBS (OR = 4.70, 95% CI [1.14; 19.38]) and tDCS (OR = 4.32, 95% CI [2.02; 9.29]); but not for continuous TBS, bilateral TBS or synchronised TMS. There were no differences in all-cause discontinuation rates. The strongest evidence was for high-frequency rTMS over the left DLPFC. Intermittent TBS provides an advance in terms of reduced treatment duration. tDCS is a potential treatment for non-resistant depression.

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Активация нейромедиаторов мозга животных интерференционными транскраниальными токами

Журнал технической физики ◽

10.21883/jtf.2021.12.51773.177-21 ◽

2021 ◽

Vol 91 (12) ◽

pp. 2067

Author(s):

Y. Katsnelson ◽

А.В. Ильинский ◽

Е.Б. Шадрин

Keyword(s):

Electric Fields ◽

High Frequency ◽

Low Frequency ◽

Mammalian Brain ◽

Electromagnetic Stimulation ◽

The Brain ◽

Transcranial Electromagnetic Stimulation ◽

Stimulation Of

A method of transcranial electromagnetic stimulation of the mammalian brain is proposed. The method is based on the interference of currents caused by high-frequency orthogonal oscillations of electric fields, which are modulated by low-frequency meander pulses. The effectiveness of the method was confirmed by the results of experiments on stimulating the brain of rats and rabbits.

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SimNIBS 2.1: A Comprehensive Pipeline for Individualized Electric Field Modelling for Transcranial Brain Stimulation

10.1101/500314 ◽

2018 ◽

Cited By ~ 8

Author(s):

Guilherme B. Saturnino ◽

Oula Puonti ◽

Jesper D Nielsen ◽

Daria Antonenko ◽

Kristoffer Hougaard H Madsen ◽

...

Keyword(s):

Electric Field ◽

Electric Fields ◽

Brain Stimulation ◽

Head Model ◽

Non Invasive ◽

Field Modelling ◽

Transcranial Brain Stimulation ◽

Automated Tools ◽

Automated Placement ◽

The Brain

Numerical simulation of the electric fields induced by Non-Invasive Brain Stimulation (NIBS), using realistic anatomical head models has gained interest in recent years for understanding the NIBS effects in individual subjects. Although automated tools for generating the head models and performing the electric field simulations have become available, individualized modelling is still not standard practice in NIBS studies. This is likely partly explained by the lack of robustness and usability of the previously available software tools, and partly by the still developing understanding of the link between physiological effects and electric field distributions in the brain. To facilitate individualized modelling in NIBS, we have introduced the SimNIBS (Simulation of NIBS) software package, providing easy-to-use automated tools for electric field modelling. In this article, we give an overview of the modelling pipeline in SimNIBS 2.1, with step-by-step examples of how to run a simulation. Furthermore, we demonstrate a set of scripts for extracting average electric fields for a group of subjects, and finally demonstrate the accuracy of automated placement of standard electrode montages on the head model. SimNIBS 2.1 is freely available at www.simnibs.org.

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Spatiotemporal structure of intracranial electric fields induced by transcranial electric stimulation in human and nonhuman primates

10.1101/053892 ◽

2016 ◽

Cited By ~ 1

Author(s):

Alexander Opitz ◽

Arnaud Falchier ◽

Chao-Gan Yan ◽

Erin Yeagle ◽

Gary Linn ◽

...

Keyword(s):

Electric Field ◽

Electric Fields ◽

Electric Stimulation ◽

Brain Regions ◽

Electrode Arrays ◽

Non Invasive ◽

Crucial Information ◽

Cebus Monkeys ◽

Transcranial Electric Stimulation ◽

The Brain

AbstractTranscranial electric stimulation (TES) is an emerging technique, developed to non-invasively modulate brain function. However, the spatiotemporal distribution of the intracranial electric fields induced by TES remains poorly understood. In particular, it is unclear how much current actually reaches the brain, and how it distributes across the brain. Lack of this basic information precludes a firm mechanistic understanding of TES effects. In this study we directly measure the spatial and temporal characteristics of the electric field generated by TES using stereotactic EEG (s-EEG) electrode arrays implanted in cebus monkeys and surgical epilepsy patients. We found a small frequency dependent decrease (10%) in magnitudes of TES induced potentials and negligible phase shifts over space. Electric field strengths were strongest in superficial brain regions with maximum values of about 0.5 mV/mm. Our results provide crucial information for the interpretation of human TES studies and the optimization and design of TES stimulation protocols. In addition, our findings have broad implications concerning electric field propagation in non-invasive recording techniques such as EEG/MEG.

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Kurtosis and skewness of high-frequency brain signals are altered in paediatric epilepsy

Brain Communications ◽

10.1093/braincomms/fcaa036 ◽

2020 ◽

Vol 2 (1) ◽

Cited By ~ 2

Author(s):

Jing Xiang ◽

Ellen Maue ◽

Yuyin Fan ◽

Lei Qi ◽

Francesco T Mangano ◽

...

Keyword(s):

High Frequency ◽

Intractable Epilepsy ◽

Low Frequency ◽

Brain Regions ◽

Control Group ◽

Frequency Bands ◽

Non Invasive ◽

Brain Signals ◽

Paediatric Epilepsy ◽

Virtual Electrode

Abstract Intracranial studies provide solid evidence that high-frequency brain signals are a new biomarker for epilepsy. Unfortunately, epileptic (pathological) high-frequency signals can be intermingled with physiological high-frequency signals making these signals difficult to differentiate. Recent success in non-invasive detection of high-frequency brain signals opens a new avenue for distinguishing pathological from physiological high-frequency signals. The objective of the present study is to characterize pathological and physiological high-frequency signals at source levels by using kurtosis and skewness analyses. Twenty-three children with medically intractable epilepsy and age-/gender-matched healthy controls were studied using magnetoencephalography. Magnetoencephalographic data in three frequency bands, which included 2–80 Hz (the conventional low-frequency signals), 80–250 Hz (ripples) and 250–600 Hz (fast ripples), were analysed. The kurtosis and skewness of virtual electrode signals in eight brain regions, which included left/right frontal, temporal, parietal and occipital cortices, were calculated and analysed. Differences between epilepsy and controls were quantitatively compared for each cerebral lobe in each frequency band in terms of kurtosis and skewness measurements. Virtual electrode signals from clinical epileptogenic zones and brain areas outside of the epileptogenic zones were also compared with kurtosis and skewness analyses. Compared to controls, patients with epilepsy showed significant elevation in kurtosis and skewness of virtual electrode signals. The spatial and frequency patterns of the kurtosis and skewness of virtual electrode signals among the eight cerebral lobes in three frequency bands were also significantly different from that of the controls (2–80 Hz, P < 0.001; 80–250 Hz, P < 0.00001; 250–600 Hz, P < 0.0001). Compared to signals from non-epileptogenic zones, virtual electrode signals from epileptogenic zones showed significantly altered kurtosis and skewness (P < 0.001). Compared to normative data from the control group, aberrant virtual electrode signals were, for each patient, more pronounced in the epileptogenic lobes than in other lobes(kurtosis analysis of virtual electrode signals in 250–600 Hz; odds ratio = 27.9; P < 0.0001). The kurtosis values of virtual electrode signals in 80–250 and 250–600 Hz showed the highest sensitivity (88.23%) and specificity (89.09%) for revealing epileptogenic lobe, respectively. The combination of virtual electrode and kurtosis/skewness measurements provides a new quantitative approach to distinguishing pathological from physiological high-frequency signals for paediatric epilepsy. Non-invasive identification of pathological high-frequency signals may provide novel important information to guide clinical invasive recordings and direct surgical treatment of epilepsy.

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Brain Circuits Involved in the Development of Chronic Musculoskeletal Pain: Evidence From Non-invasive Brain Stimulation

Frontiers in Neurology ◽

10.3389/fneur.2021.732034 ◽

2021 ◽

Vol 12 ◽

Author(s):

Mina Kandić ◽

Vera Moliadze ◽

Jamila Andoh ◽

Herta Flor ◽

Frauke Nees

Keyword(s):

Chronic Pain ◽

Musculoskeletal Pain ◽

Brain Stimulation ◽

Brain Regions ◽

Mechanistic Models ◽

Imaging Studies ◽

Non Invasive ◽

Brain Circuits ◽

The Brain

It has been well-documented that the brain changes in states of chronic pain. Less is known about changes in the brain that predict the transition from acute to chronic pain. Evidence from neuroimaging studies suggests a shift from brain regions involved in nociceptive processing to corticostriatal brain regions that are instrumental in the processing of reward and emotional learning in the transition to the chronic state. In addition, dysfunction in descending pain modulatory circuits encompassing the periaqueductal gray and the rostral anterior cingulate cortex may also be a key risk factor for pain chronicity. Although longitudinal imaging studies have revealed potential predictors of pain chronicity, their causal role has not yet been determined. Here we review evidence from studies that involve non-invasive brain stimulation to elucidate to what extent they may help to elucidate the brain circuits involved in pain chronicity. Especially, we focus on studies using non-invasive brain stimulation techniques [e.g., transcranial magnetic stimulation (TMS), particularly its repetitive form (rTMS), transcranial alternating current stimulation (tACS), and transcranial direct current stimulation (tDCS)] in the context of musculoskeletal pain chronicity. We focus on the role of the motor cortex because of its known contribution to sensory components of pain via thalamic inhibition, and the role of the dorsolateral prefrontal cortex because of its role on cognitive and affective processing of pain. We will also discuss findings from studies using experimentally induced prolonged pain and studies implicating the DLPFC, which may shed light on the earliest transition phase to chronicity. We propose that combined brain stimulation and imaging studies might further advance mechanistic models of the chronicity process and involved brain circuits. Implications and challenges for translating the research on mechanistic models of the development of chronic pain to clinical practice will also be addressed.

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Deep Brain Stimulation of the Posterior Insula in Chronic Pain: A Theoretical Framework

Brain Sciences ◽

10.3390/brainsci11050639 ◽

2021 ◽

Vol 11 (5) ◽

pp. 639

Author(s):

David Bergeron ◽

Sami Obaid ◽

Marie-Pierre Fournier-Gosselin ◽

Alain Bouthillier ◽

Dang Khoa Nguyen

Keyword(s):

Chronic Pain ◽

Electrical Stimulation ◽

Deep Brain Stimulation ◽

Brain Stimulation ◽

High Frequency ◽

Brain Lesion ◽

Low Frequency ◽

Posterior Insula ◽

Deep Brain ◽

Stimulation Of

Introduction: To date, clinical trials of deep brain stimulation (DBS) for refractory chronic pain have yielded unsatisfying results. Recent evidence suggests that the posterior insula may represent a promising DBS target for this indication. Methods: We present a narrative review highlighting the theoretical basis of posterior insula DBS in patients with chronic pain. Results: Neuroanatomical studies identified the posterior insula as an important cortical relay center for pain and interoception. Intracranial neuronal recordings showed that the earliest response to painful laser stimulation occurs in the posterior insula. The posterior insula is one of the only regions in the brain whose low-frequency electrical stimulation can elicit painful sensations. Most chronic pain syndromes, such as fibromyalgia, had abnormal functional connectivity of the posterior insula on functional imaging. Finally, preliminary results indicated that high-frequency electrical stimulation of the posterior insula can acutely increase pain thresholds. Conclusion: In light of the converging evidence from neuroanatomical, brain lesion, neuroimaging, and intracranial recording and stimulation as well as non-invasive stimulation studies, it appears that the insula is a critical hub for central integration and processing of painful stimuli, whose high-frequency electrical stimulation has the potential to relieve patients from the sensory and affective burden of chronic pain.

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Head models of healthy and depressed adults for simulating the effects of non-invasive brain stimulation

F1000Research ◽

10.12688/f1000research.15125.1 ◽

2018 ◽

Vol 7 ◽

pp. 704 ◽

Cited By ~ 1

Author(s):

Nya Mehnwolo Boayue ◽

Gábor Csifcsák ◽

Oula Puonti ◽

Axel Thielscher ◽

Matthias Mittner

Keyword(s):

Electric Fields ◽

Brain Stimulation ◽

Brain Anatomy ◽

Imaging Data ◽

Magnetic Resonance Imaging Data ◽

Structural Variations ◽

Major Depressive ◽

Non Invasive ◽

The Past ◽

Dorsolateral Prefrontal

During the past decade, it became clear that the effects of non-invasive brain stimulation (NIBS) techniques such as transcranial direct current stimulation (tDCS) and transcranial magnetic stimulation (TMS) are substantially influenced by variations in individual head and brain anatomy. In addition to structural variations in the healthy, several psychiatric disorders are characterized by anatomical alterations that are likely to further constrain the intracerebral effects of NIBS. Here, we present high-resolution realistic head models derived from structural magnetic resonance imaging data of 19 healthy adults and 19 patients diagnosed with major depressive disorder (MDD). By using a freely available software package for modelling the effects of different NIBS protocols, we show that our head models are well-suited for assessing inter-individual and between-group variability in the magnitude and focality of tDCS-induced electric fields for two protocols targeting the left dorsolateral prefrontal cortex.

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ANALYSIS OF HIGH-FREQUENCY C-CORE MAGNETIC FLUX LEAKAGES FOR BONE TUMOR WITH INDUCTION HEATING BY USING MULTI-COIL

Proceedings 17th International Conference on Microwave and High Frequency Heating ◽

10.4995/ampere2019.2019.9900 ◽

2019 ◽

Author(s):

Metharak Jokpudsa ◽

Supawat Kotchapradit ◽

Chanchai Thongsopa ◽

Thanaset Thosdeekoraphat

Keyword(s):

Magnetic Field ◽

High Frequency ◽

Tumor Tissue ◽

Low Frequency ◽

Heat Energy ◽

High Frequencies ◽

Frequency Magnetic Field ◽

High Frequency Magnetic Field ◽

The Magnetic Field ◽

Flux Leakage

High-frequency magnetic field has been developed pervasively. The induction of heat from the magnetic field can help to treat tumor tissue to a certain extent. Normally, treatment by the low-frequency magnetic field needed to be combined with magnetic substances. To assist in the induction of magnetic fields and reduce flux leakage. However, there are studies that have found that high frequencies can cause heat to tumor tissue. In this paper present, a new magnetic application will focus on the analysis of the high-frequency magnetic nickel core with multi-coil. In order to focus the heat energy using a high-frequency magnetic field into the tumor tissue. The magnetic coil was excited by 915 MHz signal and the combination of tissues used are muscle, bone, and tumor. The magnetic power on the heating predicted by the analytical model, the power loss density (2.98e-6 w/m3) was analyzed using the CST microwave studio.

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Orientation of Temporal Interference for Non-Invasive Deep Brain Stimulation in Epilepsy

10.1101/2020.07.07.191692 ◽

2020 ◽

Author(s):

Florian Missey ◽

Evgeniia Rusina ◽

Emma Acerbo ◽

Boris Botzanowski ◽

Romain Carron ◽

...

Keyword(s):

Electric Fields ◽

Brain Regions ◽

Intracranial Stimulation ◽

Epileptogenic Zone ◽

Implanted Electrodes ◽

Non Invasive ◽

Gamma Range ◽

Wide Range ◽

Drug Resistant Epilepsy ◽

Intracranial Electrodes

AbstractIn patients with focal drug-resistant epilepsy, electrical stimulation from intracranial electrodes is frequently used for the localization of seizure onset zones and related pathological networks. The ability of electrically stimulated tissue to generate beta and gamma range oscillations, called rapid-discharges, is a frequent indication of an epileptogenic zone. However, a limit of intracranial stimulation is the fixed physical location and number of implanted electrodes, leaving numerous clinically and functionally relevant brain regions unexplored. Here, we demonstrate an alternative technique relying exclusively on nonpenetrating surface electrodes, namely an orientation-tunable form of temporally-interfering (TI) electric fields to target the CA3 of the mouse hippocampus which focally evokes seizure-like events (SLEs) having the characteristic frequencies of rapid-discharges, but without the necessity of the implanted electrodes. The orientation of the topical electrodes with respect to the orientation of the hippocampus is demonstrated to strongly control the threshold for evoking SLEs. Additionally, we demonstrate the use of square waves as an alternative to sine waves for TI stimulation. An orientation-dependent analysis of classic implanted electrodes to evoke SLEs in the hippocampus is subsequently utilized to support the results of the minimally-invasive temporally-interfering fields. The principles of orientation-tunable TI stimulation seen here can be generally applicable in a wide range of other excitable tissues and brain regions, overcoming several limitations of fixed electrodes which penetrate tissue.

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