Clinical Trial Details
— Status: Active, not recruiting
Administrative data
NCT number |
NCT02263274 |
Other study ID # |
13-01171 |
Secondary ID |
|
Status |
Active, not recruiting |
Phase |
N/A
|
First received |
|
Last updated |
|
Start date |
November 2013 |
Est. completion date |
June 2025 |
Study information
Verified date |
July 2023 |
Source |
NYU Langone Health |
Contact |
n/a |
Is FDA regulated |
No |
Health authority |
|
Study type |
Interventional
|
Clinical Trial Summary
The primary study objective is to measure the electrical fields evoked by tDCS using subjects
who have implanted intracranial electrodes as part of their evaluation for epilepsy surgery.
The measurements obtained in these subjects and their brain MRI will be employed to validate
existing mathematical models.
In the future, these refined models can be used to target tDCS to predetermined brain regions
in healthy and subjects and patient populations. As described above in the safety section,
the intensities of stimulation applied in this project are not expected to produce changes in
brain function, are below intensities commonly applied in clinical trials, and fall well
below safety limits suggested by animal studies.
Description:
Noninvasive brain stimulation (NBS) represents a promising set of tools for neurotherapeutics
and rehabilitation. In a literature search, NBS has been tested for over seventy neurologic
and psychiatric conditions. NBS may complement existing medical treatments, especially for
neurologic indications without suitable pharmacotherapies (e.g. tinnitus, dyskinesias) or for
patients with pharmaco-resistant illness (e.g. intractable epilepsy, severe depression).
In particular, transcranial direct current stimulation (tDCS) modulates brain activity by
delivering low intensity unidirectional current through the scalp. Rather than induce action
potentials, tDCS modulates resting neuronal transmembrane potential to influence brain
plasticity. Moreover, from a pragmatic perspective, tDCS' benefits include its low cost,
portability, and ease of use. Furthermore, tDCS can easily be combined with other
interventions such as mental imagery, computerized cognitive interventions, or robot-assisted
motor activity.
Current physiological understanding of how TDCS affects brain plasticity at a synaptic,
cellular, and a network level is limited. Experimentally, spontaneous neuronal firing
activity under the anode generally increases, while firing activity under the cathode
decreases, although the precise effects probably depend on the orientation of the axons to
the electric field (Nitsche and Paulus, 2000, Bindman et al., 1964, Creutzfeldt et al., 1962,
Purpura and McMurtry, 1965). The neuromodulatory effects of tDCS have also been broadly
attributed to LTP- and LTD-like mechanisms of synaptic plasticity, involving modulation of
NMDA-receptor activity, and sodium and calcium channel activity (Hattori et al., 1990, Islam
et al., 1995, Liebetanz et al., 2002). Furthermore, functional neuroimaging studies have
revealed both local and distant network effects induced by tDCS, probably mediated by
interneuronal circuits (Lefaucheur, 2008).
Advancing the investigators mechanistic understanding of how tDCS affects cortical
excitability on a local and distributed level is necessary to (1) customize stimulation
parameters (e.g. electrode size, positioning, current intensity and duration) to precisely
target brain regions and maximize therapeutic outcomes, (2) confirm safety outcomes for
vulnerable patient populations (e.g. children, patients with skull defects and implanted
hardware). Previously, patients with a scalp or skull defect have been excluded from
stimulation (Bikson, 2012) protocols because of a theoretical risk of current shunting
through highly conductive CSF collections. However patients with penetrating brain injury,
stroke, or previous brain surgery are precisely those who may most benefit from these
technologies.
Computational models using finite element methods (FEM) aim to determine the pattern and
intensity of current flow through the brain by incorporating both (1) stimulation parameters
and (2) patient characteristics such as underlying anatomy and tissue properties (e.g. size
and position of skull defect relative to electrode configuration) (Bikson 2012). For example,
one computational model incorporating electrode configuration and skull defect size and
properties (Datta et al., 2010) predicts that the majority of electrode configurations
surrounding the skull defect (with the exception of stimulating directly on top of a small
skull defect) will not significantly increase the peak cortical electrical field intensity.
Rather, current is directed to the edges of the bony defect, which may be counterproductive
to therapeutic goals. Another computational case study on a stroke patient demonstrated that
a relatively conductive stroke lesion concentrated current in the perilesional areas, and
that placement of the reference electrode (e.g. right should, right mastoid, right
orbitofrontal, and contralateral hemisphere) significantly altered the path of greatest
current flow (Datta et al., 2011).
Yet, these modeling predictions are limited in their clinical application, as experimental
validation is necessary. Quantitative determination of the electrical field at the neural
tissue level is required to establish efficacy and safety for a given individual (Bikson
2012). To the investigators knowledge, there are no published studies that have empirically
confirmed the predicted patterns and current flow intensities predicted by these models. This
proposed experimental study represents the first-in-kind to quantify voltage intensities, as
measured at the brain surface, in response to various stimulation parameters, and will
represent a significant advance in the field of noninvasive neurostimulation