Your search keyword '"Datta, Abhishek"' showing total 10 results

1. Unpacking Galvanic Vestibular Stimulation using simulations and relating current flow to reported motions: Comparison across common and specialized electrode placements.

Author

Truong DQ, Thomas C, Ira S, Valter Y, Clark TK, and Datta A

Subjects

Humans, Computer Simulation, Motion, Vestibule, Labyrinth physiology, Electrodes, Electric Stimulation methods

Abstract

Background: Galvanic Vestibular Stimulation (GVS) is a non-invasive electrical stimulation technique that is typically used to probe the vestibular system. When using direct current or very low frequency sine, GVS causes postural sway or perception of illusory (virtual) motions. GVS is commonly delivered using two electrodes placed at the mastoids, however, placements involving additional electrodes / locations have been employed. Our objective was to systematically evaluate all known GVS electrode placements, compare induced current flow, and how it relates to the archetypal sway and virtual motions. The ultimate goal is to help users in having a better understanding of the effects of different placements., Methods: We simulated seven GVS electrode placements with same total injected current using an ultra-high resolution model. Induced electric field (EF) patterns at the cortical and the level of vestibular organs (left and right) were determined. A range of current flow metrics including potential factors such as inter-electrode separation, percentage of current entering the cranial cavity, and symmetricity were calculated. Finally, we relate current flow to reported GVS motions., Results: As expected, current flow patterns are electrode placement specific. Placements with two electrodes generally result in higher EF magnitude. Placements with four electrodes result in lower percentage of current entering the cranial cavity. Symmetric placements do not result in similar EF values in the left and the right organs respectively- highlighting inherent anatomical asymmetry of the human head. Asymmetric placements were found to induce as much as ~3-fold higher EF in one organ over the other. The percentage of current entering the cranial cavity varies between ~15% and ~40% depending on the placement., Conclusions: We expect our study to advance understanding of GVS and provide insight on probable mechanism of action of a certain electrode placement choice. The dataset generated across several metrics will support hypothesis testing relating empirical outcomes to current flow patterns. Further, the differences in current flow will guide stimulation strategy (what placement and how much scalp current to use) and facilitate a quantitatively informed rational / optimal decision., Competing Interests: DQT, CT, SI, YV, and AD are employees of Soterix Medical. The remaining authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest. This does not alter our adherence to PLOS ONE policies on sharing data and materials., (Copyright: © 2024 Truong et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published

2024

2. A Feasibility Study of Bilateral Anodal Stimulation of the Prefrontal Cortex Using High-Definition Electrodes in Healthy Participants.

Author

Xu J, Healy SM, Truong DQ, Datta A, Bikson M, and Potenza MN

Subjects

Adolescent, Adult, Feasibility Studies, Female, Humans, Male, Memory, Short-Term physiology, Mental Disorders diagnosis, Mental Disorders etiology, Middle Aged, Transcranial Direct Current Stimulation adverse effects, Young Adult, Affect physiology, Cognition physiology, Electrodes, Prefrontal Cortex physiology, Transcranial Direct Current Stimulation instrumentation, Transcranial Direct Current Stimulation methods

Abstract

Transcranial direct current stimulation (tDCS) studies often use one anode to increase cortical excitability in one hemisphere. However, mental processes may involve cortical regions in both hemispheres. This study's aim was to assess the safety and possible effects on affect and working memory of tDCS using two anodes for bifrontal stimulation. A group of healthy subjects participated in two bifrontal tDCS sessions on two different days, one for real and the other for sham stimulation. They performed a working memory task and reported their affect immediately before and after each tDCS session. Relative to sham, real bifrontal stimulation did not induce significant adverse effects, reduced decrement in vigor-activity during the study session, and did not improve working memory. These preliminary findings suggest that bifrontal anodal stimulation is feasible and safe and may reduce task-related fatigue in healthy participants. Its effects on neuropsychiatric patients deserve further study.

Published

2015

3. Electrode montages for tDCS and weak transcranial electrical stimulation: role of "return" electrode's position and size.

Author

Bikson M, Datta A, Rahman A, and Scaturro J

Subjects

Brain Mapping, Humans, Transcranial Magnetic Stimulation, Brain physiology, Electric Stimulation methods, Electrodes

Published

2010

4. Electrodes for high-definition transcutaneous DC stimulation for applications in drug delivery and electrotherapy, including tDCS.

Author

Minhas P, Bansal V, Patel J, Ho JS, Diaz J, Datta A, and Bikson M

Subjects

Adult, Drug Delivery Systems instrumentation, Electric Stimulation Therapy instrumentation, Female, Forearm, Gels adverse effects, Humans, Hydrogen-Ion Concentration, Male, Pain etiology, Pain Measurement, Temperature, Time Factors, Transcutaneous Electric Nerve Stimulation adverse effects, Transcutaneous Electric Nerve Stimulation methods, Young Adult, Electrodes adverse effects, Transcutaneous Electric Nerve Stimulation instrumentation

Abstract

Transcutaneous electrical stimulation is applied in a range of biomedical applications including transcranial direct current stimulation (tDCS). tDCS is a non-invasive procedure where a weak direct current (<2 mA) is applied across the scalp to modulate brain function. High-definition tDCS (HD-tDCS) is a technique used to increase the spatial focality of tDCS by passing current across the scalp using <12 mm diameter electrodes. The purpose of this study was to design and optimize "high-definition" electrode-gel parameters for electrode durability, skin safety and subjective pain. Anode and cathode electrode potential, temperature, pH and subjective sensation over time were assessed during application of 2 mA direct current, for up to 22 min on agar gel or subject forearms. A selection of five types of solid-conductors (Ag pellet, Ag/AgCl pellet, rubber pellet, Ag/AgCl ring and Ag/AgCl disc) and seven conductive gels (Signa, Spectra, Tensive, Redux, BioGel, Lectron and CCNY-4) were investigated. The Ag/AgCl ring in combination with CCNY-4 gel resulted in the most favorable outcomes. Under anode stimulations, electrode potential and temperature rises were generally observed in all electrode-gel combinations except for Ag/AgCl ring and disc electrodes. pH remained constant for all solid-conductors except for both Ag and rubber pellet electrodes with Signa and CCNY-4 gels. Sensation ratings were independent of stimulation polarity. Ag/AgCl ring electrodes were found to be the most comfortable followed by Ag, rubber and Ag/AgCl pellet electrodes across all gels., (Copyright 2010 Elsevier B.V. All rights reserved.)

Published

2010

5. Gyri-precise head model of transcranial direct current stimulation: improved spatial focality using a ring electrode versus conventional rectangular pad.

Author

Datta A, Bansal V, Diaz J, Patel J, Reato D, and Bikson M

Subjects

Humans, Magnetic Resonance Imaging instrumentation, Transcutaneous Electric Nerve Stimulation methods, Cerebral Cortex anatomy & histology, Cerebral Cortex physiology, Electrodes, Head anatomy & histology, Models, Anatomic, Transcutaneous Electric Nerve Stimulation instrumentation

Abstract

The spatial resolution of conventional transcranial direct current stimulation (tDCS) is considered to be relatively diffuse owing to skull dispersion. However, we show that electric fields may be clustered at distinct gyri/sulci sites because of details in tissue architecture/conductivity, notably cerebrospinal fluid (CSF). We calculated the cortical electric field/current density magnitude induced during tDCS using a high spatial resolution (1 mm3) magnetic resonance imaging (MRI)-derived finite element human head model; cortical gyri/sulci were resolved. The spatial focality of conventional rectangular-pad (7 x 5 cm2) and the ring (4 x 1) electrode configurations were compared. The rectangular-pad configuration resulted in diffuse (unfocal) modulation, with discrete clusters of electric field magnitude maxima. Peak-induced electric field magnitude was not observed directly underneath the pads, but at an intermediate lobe. The 4 x 1 ring resulted in enhanced spatial focality, with peak-induced electric field magnitude at the sulcus and adjacent gyri directly underneath the active electrode. Cortical structures may be focally targeted by using ring configurations. Anatomically accurate high-resolution MRI-based forward-models may guide the "rational" clinical design and optimization of tDCS.

Published

2009

6. Bio-heat transfer model of transcranial DC stimulation: comparison of conventional pad versus ring electrode.

Author

Datta A, Elwassif M, and Bikson M

Subjects

Computer Simulation, Dose-Response Relationship, Radiation, Electromagnetic Fields, Energy Transfer physiology, Equipment Design, Equipment Failure Analysis, Humans, Radiation Dosage, Thermal Conductivity, Electrodes, Models, Biological, Skin Temperature physiology, Skin Temperature radiation effects, Transcranial Magnetic Stimulation instrumentation, Transcranial Magnetic Stimulation methods

Abstract

Transcranial Direct Current Stimulation (tDCS) is a non-invasive procedure where a weak electrical current is applied across the scalp to modulate brain function. The proliferation of this therapy has been accompanied by isolated reports regarding concern about their safety namely skin irritation. The potential cause of skin irritation has sometimes been attributed to increased scalp temperature during stimulation. We have developed novel technology for tDCS that improves spatial focality at the cost of increased stimulation electrode current density; high density tDCS (HD-tDCS). The goal of this paper was to provide information on the thermal effects of tDCS using a MRI-derived finite element human head model. The tissue temperature increases of tDCS using conventional rectangular-pad (7 x 5 cm(2)) and HD-tDCS using the ring (4 x 1) electrode configurations were compared using a bio-heat model. Our results indicate that clinical tDCS do not increase tissue temperature and 4 x 1 ring configurations leads to a negligible increase in scalp temperature.

Published

2009

7. Transcranial current stimulation focality using disc and ring electrode configurations: FEM analysis.

Author

Datta A, Elwassif M, Battaglia F, and Bikson M

Subjects

Computer Simulation, Equipment Design, Equipment Failure Analysis, Finite Element Analysis, Humans, Brain physiology, Electrodes, Evoked Potentials physiology, Head physiology, Models, Neurological, Transcranial Magnetic Stimulation instrumentation, Transcranial Magnetic Stimulation methods

Abstract

We calculated the electric fields induced in the brain during transcranial current stimulation (TCS) using a finite-element concentric spheres human head model. A range of disc electrode configurations were simulated: (1) distant-bipolar; (2) adjacent-bipolar; (3) tripolar; and three ring designs, (4) belt, (5) concentric ring, and (6) double concentric ring. We compared the focality of each configuration targeting cortical structures oriented normal to the surface ('surface-radial' and 'cross-section radial'), cortical structures oriented along the brain surface ('surface-tangential' and 'cross-section tangential') and non-oriented cortical surface structures ('surface-magnitude' and 'cross-section magnitude'). For surface-radial fields, we further considered the 'polarity' of modulation (e.g. superficial cortical neuron soma hyper/depolarizing). The distant-bipolar configuration, which is comparable with commonly used TCS protocols, resulted in diffuse (un-focal) modulation with bi-directional radial modulation under each electrode and tangential modulation between electrodes. Increasing the proximity of the two electrodes (adjacent-bipolar electrode configuration) increased focality, at the cost of more surface current. At similar electrode distances, the tripolar-electrodes configuration produced comparable peak focality, but reduced radial bi-directionality. The concentric-ring configuration resulted in the highest spatial focality and uni-directional radial modulation, at the expense of increased total surface current. Changing ring dimensions, or use of two concentric rings, allow titration of this balance. The concentric-ring design may thus provide an optimized configuration for targeted modulation of superficial cortical neurons.

Published

2008

8. Impact of galvanic vestibular stimulation electrode current density on brain current flow patterns: Does electrode size matter?

Author

Truong, Dennis Q., Guillen, Alexander, Nooristani, Mujda, Maheu, Maxime, Champoux, Francois, and Datta, Abhishek

Subjects

VESTIBULAR stimulation, DENSITY currents, MASTOID process, VESTIBULAR apparatus, ELECTRODES, ELECTRIC fields

Abstract

Background: Galvanic vestibular stimulation (GVS) uses at least one electrode placed on the mastoid process with one or multiple placed over other head areas to stimulate the vestibular system. The exact electrode size used is not given much importance in the literature and has not been reported in several studies. In a previous study, we compared the clinical effects of using different electrode sizes (3 cm2 and 35 cm2) with placebo but with the same injected current, on postural control. We observed significant improvement using the smaller size electrode but not with the bigger size electrode. The goal of this study was to simulate the current flow patterns with the intent to shed light and potentially explain the experimental outcome. Methods: We used an ultra-high-resolution structural dataset and developed a model to simulate the application of different electrode sizes. We considered current flow in the brain and in the vestibular labyrinth. Results: Our simulation results verified the focality increase using smaller electrodes that we postulated as the main reason for our clinical effect. The use of smaller size electrodes in combination with the montage employed also result in higher induced electric field (E-field) in the brain. Conclusions: Electrode size and related current density is a critical parameter to characterize any GVS administration as the choice impacts the induced E-field. It is evident that the higher induced E-field likely contributed to the clinical outcome reported in our prior study. [ABSTRACT FROM AUTHOR]

Published

2023

9. Feasibility of using high-definition transcranial direct current stimulation (HD-tDCS) to enhance treatment outcomes in persons with aphasia.

Author

Richardson, Jessica, Fridriksson, Julius, Datta, Abhishek, Dmochowski, Jacek, and Parra, Lucas C.

Subjects

BEHAVIOR, BLOOD pressure, CHI-squared test, CROSSOVER trials, ELECTRODES, HEART beat, NEUROPSYCHOLOGICAL tests, PAIN, PROBABILITY theory, RESEARCH funding, STATISTICS, T-test (Statistics), THERAPEUTICS, DATA analysis, PAIN measurement, RANDOMIZED controlled trials, VISUAL analog scale, TREATMENT effectiveness, REHABILITATION of aphasic persons, STROKE rehabilitation, DESCRIPTIVE statistics, TRANSCRANIAL direct current stimulation

Abstract

BACKGROUND: Transcranial direct current stimulation (tDCS) enhances treatment outcomes post-stroke. Feasibility and tolerability of high-definition (HD) tDCS (a technique that increases current focality and intensity) for consecutive weekdays as an adjuvant to behavioral treatment in a clinical population has not been demonstrated. OBJECTIVE: To determine HD-tDCS feasibility outcomes: 1) ability to implement study as designed, 2) acceptability of repeated HD-tDCS administration to patients, and 3) preliminary efficacy. METHODS: Eight patients with chronic post-stroke aphasia participated in a randomized crossover trial with two arms: conventional sponge-based (CS) tDCS and HD-tDCS. Computerized anomia treatment was administered for five consecutive days during each treatment arm. RESULTS: Individualized modeling/targeting procedures and an 8-channel HD-tDCS device were developed. CS-tDCS and HD-tDCS were comparable in terms of implementation, acceptability, and outcomes. Naming accuracy and response time improved for both stimulation conditions. Change in accuracy of trained items was numerically higher (but not statistically significant) for HD-tDCS compared to CS-tDCS for most patients. CONCLUSIONS: Regarding feasibility, HD-tDCS treatment studies can be implemented when designed similarly to documented CS-tDCS studies. HD-tDCS is likely to be acceptable to patients and clinicians. Preliminary efficacy data suggest that HD-tDCS effects, using only 4 electrodes, are at least comparable to CS-tDCS. [ABSTRACT FROM AUTHOR]

Published

2015

10. Individualized model predicts brain current flow during transcranial direct-current stimulation treatment in responsive stroke patient.

Author

Datta, Abhishek, Baker, Julie M., Bikson, Marom, and Fridriksson, Julius

Subjects

CEREBROVASCULAR disease patients, DIRECT currents, BRAIN disease treatment, CEREBROVASCULAR disease, BRAIN stimulation, ELECTRODES, APHASIA, CEREBRAL cortex, ELECTRIC stimulation

Abstract

Although numerous published reports have demonstrated the beneficial effects of transcranial direct-current stimulation (tDCS) on task performance, fundamental questions remain regarding the optimal electrode configuration on the scalp. Moreover, it is expected that lesioned brain tissue will influence current flow and should therefore be considered (and perhaps leveraged) in the design of individualized tDCS therapies for stroke. The current report demonstrates how different electrode configurations influence the flow of electrical current through brain tissue in a patient who responded positively to a tDCS treatment targeting aphasia. The patient, a 60-year-old man, sustained a left hemisphere ischemic stroke (lesion size = 87.42 mL) 64 months before his participation. In this study, we present results from the first high-resolution (1 mm3) model of tDCS in a brain with considerable stroke-related damage; the model was individualized for the patient who received anodal tDCS to his left frontal cortex with the reference cathode electrode placed on his right shoulder. We modeled the resulting brain current flow and also considered three additional reference electrode positions: right mastoid, right orbitofrontal cortex, and a “mirror” configuration with the anode over the undamaged right cortex. Our results demonstrate the profound effect of lesioned tissue on resulting current flow and the ability to modulate current pattern through the brain, including perilesional regions, through electrode montage design. The complexity of brain current flow modulation by detailed normal and pathologic anatomy suggest: (1) That computational models are critical for the rational interpretation and design of individualized tDCS stroke-therapy; and (2) These models must accurately reproduce head anatomy as shown here. [Copyright &y& Elsevier]

Published

2011