Mild traumatic brain injury (mTBI) often causes persistent motor and cognitive deficits in children resulting in functional limitations. We are testing a brain stimulation method along with evaluating objective tools to help record and restore communication among affected brain areas, which will facilitate recovery in youth after mTBI.
About 1.9 million children sustain mTBI per year from sports injuries alone in the US. In about 30% of children, the cognitive-motor effects of mTBI interrupt typical neurodevelopment leading to chronic neurological conditions. The limited evidence available on mTBI suggests that residual symptoms may involve the brain stem (BS); the subcortical region that is now shown to influence cognitive-motor control. The BS also has functional interconnections to other cortical regions involved in cognitive-motor learning such as the dorsolateral prefrontal cortex, premotor cortex, and primary motor cortex. While clinicians examine certain risk factors such as amnesia and history of prior concussions, they lack objective biomarkers to accurately predict the post-mTBI prognosis in children, and to accurately guide treatment. Further, there is no evidence-based standard of care established, so children may be released to pre-injury activity levels before full neurophysiological recovery, predisposing them to further mTBI and associated sequelae. Transcranial Direct Current Stimulation (tDCS), a non-invasive treatment, has been demonstrated to positively influence cognitive-motor control by modulating the excitability of both cortical and subcortical structures. Additionally, resting state functional connectivity has shown promise in diagnosing and predicting recovery in adult TBI. However, the efficacy of tDCS for children with mTBI is not yet established due to their atypical cortical activity and variable symptomology. Consequently, we aim to determine the efficacy of tDCS for promoting recovery in 10 youths (aged 10 to 15 years) who exhibit persistent symptoms of mTBI using a cross-over design compared with 10 never-injured youths as controls, and to test the application of neural correlates to provide insights into their functional change and recovery by comparing group differences.
Study Type
INTERVENTIONAL
Allocation
NON_RANDOMIZED
Purpose
TREATMENT
Masking
NONE
Enrollment
10
The safety and tolerability of tDCS have been established in children with mTBI (1). A recent study of 13-18 year youths post-mTBI showed that three sessions of 1.5 mA anodal tDCS over the left DLPFC, positively influenced prolonged working memory deficits. (2) Additionally, rodent studies show the effectiveness of tDCS in improving cognitive-motor (motor planning and balance/gait) function in rats with mTBI. (3)
Ghazala Saleem
Buffalo, New York, United States
RECRUITINGChanges in the Revised Physical and Neurological Examination of Subtle Signs (PANESS - Gaits and Stations Measures)
The PANESS is used to assess static and dynamic postural stability of adolescents. The PANESS contains nine static and dynamic balance tasks: 1) walking on heels, 2) walking on toes, 3) walking on sides of feet, 4) double-legged stance, 5) single-legged stance for 30 seconds, 6) tandems stance for 20 seconds, 7) forward tandem walking, 8) backward tandem walking, and 9) hopping in place on one foot. The scores from all tasks are combined to form an aggregated score.
Time frame: Day 1 (at the initial visit), Day 26- 30 (final post-anodal transcranial direct current stimulation (tDCS), Day 60 -64 (final post-sham tDCS), and Day 94 (at 30-days follow up visit).
Changes in the Nine-Hole Peg Test
The test consists of a square board with 9 holes. The participants are asked to pick up pegs one at a time and place them into holes as quickly as possible. The participants are then instructed to remove the pegs one by one from the board and put them back into the container. The average time from four trials is examined to arrive at the total score.
Time frame: Day 1 (at the initial visit), Day 26- 30 (final post-anodal transcranial direct current stimulation (tDCS), Day 60 -64 (final post-sham tDCS), and Day 94 (at 30-days follow up visit).
Changes in the Dual-Task Screen
It consists of a gait task and an eye-hand coordination task. In the single gait task condition, participants are instructed to walk as quickly as possibly for 6 meter and step over a 1.5 meter obstacle placed 4 meter from the start. In the dual gait condition, participants will repeat the gait task while counting the months of the year backward. In the eye-hand coordination single task, participants will be instructed to stand 1.5 meter away from the wall and throw and catch a tennis ball for 30 seconds. In the dual task eye-hand coordination condition, the participants will repeat the catch and throw task while serially subtracting 3s from 100s. The difference between the single task and the dual task will be calculated to arrive at the score for each participant.
Time frame: Day 1 (at the initial visit), Day 26- 30 (final post-anodal transcranial direct current stimulation (tDCS), Day 60 -64 (final post-sham tDCS), and Day 94 (at 30-days follow up visit).
Changes in Motor Control Test Measurements (Posturography)
The motor control test (MCT) will be administered using the Posturography Machine to assess the ability of the patient to recover from translational disturbances of the support surface. The six conditions each participant will perform include three forward translations with small, medium, and large intensities as well as three backward translations with small, medium, and large intensities. Each participant go through three trials at each translation and intensity. The participant will be scored on latency; their ability to respond to the translation in milliseconds, and the amplitude scaling; the average amount of weight carried by each leg during the translation. An increased latency indicates impairment within the neural pathways that cause musculoskeletal problems in addition to central abnormalities. Abnormal amplitude scaling indicates inadequate or asymmetrical level of force exerted during the recovery from the support disturbance.
Time frame: Day 1 (at the initial visit), Day 26- 30 (final post-anodal transcranial direct current stimulation (tDCS), Day 60 -64 (final post-sham tDCS), and Day 94 (at 30-days follow up visit).
Changes in resting-state functional magnetic resonance imaging outcome
MRI scanning will be used to assess the functional connectivity among the brain areas involved in motor learning and motor planning. Functional connectivity will be measured by looking at differences in the control group and the experimental group.
Time frame: Day 2-5 (post initial behavioral testing), Day 26- 32 (final post-anodal transcranial direct current stimulation (tDCS), Day 60 -66 (final post-sham tDCS), and Day 94 - 96 (post 30-days follow up behavioral testing visit).
Changes in PHQ-8
This 8-item questionnaire assesses depression in children. The scores of all variables will be aggregated to form a total score.
Time frame: Day 1 (at the initial visit), Day 26- 30 (final post-anodal transcranial direct current stimulation (tDCS), Day 60 -64 (final post-sham tDCS), and Day 94 (at 30-days follow up visit).
Changes in GAD-7
This 7-item questionnaire assesses anxiety in children. The scores of all variables will be aggregated to form a total score.
Time frame: Day 1 (at the initial visit), Day 26- 30 (final post-anodal transcranial direct current stimulation (tDCS), Day 60 -64 (final post-sham tDCS), and Day 94 (at 30-days follow up visit).
Changes in WASI-II
This measure assesses overall cognitive abilities in children. The scores of all variables will be aggregated to form a total score.
Time frame: Day 1 (at the initial visit), Day 26- 30 (final post-anodal transcranial direct current stimulation (tDCS), Day 60 -64 (final post-sham tDCS), and Day 94 (at 30-days follow up visit).
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