Ignite Creation Date:
2025-12-24 @ 9:18 PM
Ignite Modification Date:
2026-01-04 @ 1:04 PM
Study NCT ID:
NCT03814304
Status:
COMPLETED
Last Update Posted:
2025-08-28
First Post:
2019-01-09
Is Gene Therapy:
True
Has Adverse Events:
False
Brief Title:
Personalized tDCS in Elderly Fallers Study
Sponsor:
Hebrew SeniorLife
Organization:
Study Overview
Official Title:
Personalized Brain Activity Modulation to Improve Balance and Cognition in Elderly Fallers
Status:
COMPLETED
Status Verified Date:
2025-08
Last Known Status:
None
Delayed Posting:
No
If Stopped, Why?:
Not Stopped
Has Expanded Access:
False
If Expanded Access, NCT#:
N/A
Has Expanded Access, NCT# Status:
N/A
Acronym:
None
Brief Summary:
The objective of this study is to determine if a four-week, 20-session intervention of personalized transcranial direct current stimulation (tDCS), as compared to sham intervention, improves dual task standing and walking performance (Aim 1), as well as other physical (Aim 2) and cognitive (Aim 3) factors on the causal pathway to falls, in older adults who report two or more falls within the past year and fear of falling again in the future, yet who do not have any acute or over neurological or musculoskeletal condition.
Primary endpoints will include the "dual task" costs to gait speed when walking and postural sway speed when standing, as induced by performing a serial subtraction cognitive task (i.e., \[(speeddual task - speedsingle task) / speedsingle task) X 100\] (Aim 1), the Short Physical Performance Battery (Aim 2), and the Trail Making Test (Part B minus Part A) (AIM 3). Secondary endpoints will include the dual task cost to serial subtraction performance, additional gait and balance outcomes derived from the dual task paradigm, the Timed Up-and-Go, fear of falling, habitual physical activity, and performance within a battery of neuropsychological tests focused on global cognitive function, attention, verbal fluency and memory.
Primary endpoints will include the "dual task" costs to gait speed when walking and postural sway speed when standing, as induced by performing a serial subtraction cognitive task (i.e., \[(speeddual task - speedsingle task) / speedsingle task) X 100\] (Aim 1), the Short Physical Performance Battery (Aim 2), and the Trail Making Test (Part B minus Part A) (AIM 3). Secondary endpoints will include the dual task cost to serial subtraction performance, additional gait and balance outcomes derived from the dual task paradigm, the Timed Up-and-Go, fear of falling, habitual physical activity, and performance within a battery of neuropsychological tests focused on global cognitive function, attention, verbal fluency and memory.
Detailed Description:
In older adults, falls are costly, consequential and correlated with both physical and cognitive decline. Most falls occur when standing or walking. Many activities require people to stand or walk while performing tasks like talking or making decisions. Such "dual tasking" interferes with the control of standing and walking. This interference, or "cost," is exaggerated in older adults with previous falls and is predictive of future falls. Neuroimaging evidence indicates that standing and walking,especially when dual tasking, activate distributed brain networks including the left dorsolateral prefrontal cortex (dlPFC)-a brain region sub-serving executive function. Thus, strategies that facilitate activation of the left dlPFC and its connected neural networks hold promise to mitigate dual task costs, improve physical and cognitive function, and ultimately, reduce falls.
Transcranial direct current stimulation (tDCS) provides a noninvasive means of selectively modulating cortical excitability. The investigators have shown in younger and older adults that a 20-minute session of tDCS designed to increase excitability of the left dlPFC reduces dual task costs and improves mobility when tested just after stimulation. The investigators have since completed a pilot, sham-controlled trial of a 2-week, 10-session tDCS intervention targeting the left dlPFC in 20 older adults with slow gait and mild-to-moderate executive dysfunction. The intervention was successfully double-blinded and well-attended. tDCS, compared to sham, reduced dual task costs and induced trends towards improved mobility and executive function over a 2-week follow-up. The investigators thus contend that tDCS targeting the left dlPFC holds promise to improve the control of standing and walking-and ultimately reduce falls-in older adults. Still, the size and duration of tDCS-induced benefits to older adult "fallers" have not been established. Moreover, to date, tDCS delivery has attempted to optimize current flow based on a "typical" brain and has thus not accounted for individual differences in skin, skull, cerebrospinal fluid and brain tissue in the aging brain. Such personalization is now possible with the current flow modeling the investigators propose.
The Overall Aim is to compare, in older adults with previous falls, the effects of a personalized tDCS intervention designed to target the left dlPFC on the dual task costs to standing and walking, and other physical and cognitive factors that are on the causal pathway to falls and important to everyday function. The investigators will conduct a randomized, sham-controlled, double-blinded trial with assessments at baseline and post-intervention (immediate, 3-, 6-month follow-up) in 120 non-demented men and women (60 per arm) aged 60 or older who are at risk of falls and report mobility and balance problems and a fear of falling, yet have no major neural or musculoskeletal disorders that explain their falls. The tDCS intervention will comprise 20, 20-minute sessions of tDCS over a 4-week period.
The investigators hypothesize that, in older adults at risk of falls and over a 6-month follow-up, a personalized tDCS intervention targeting the left dlPFC, as compared to sham, will mitigate dual task costs to the control of standing and walking and enhance other metrics of both physical and cognitive function.
Transcranial direct current stimulation (tDCS) provides a noninvasive means of selectively modulating cortical excitability. The investigators have shown in younger and older adults that a 20-minute session of tDCS designed to increase excitability of the left dlPFC reduces dual task costs and improves mobility when tested just after stimulation. The investigators have since completed a pilot, sham-controlled trial of a 2-week, 10-session tDCS intervention targeting the left dlPFC in 20 older adults with slow gait and mild-to-moderate executive dysfunction. The intervention was successfully double-blinded and well-attended. tDCS, compared to sham, reduced dual task costs and induced trends towards improved mobility and executive function over a 2-week follow-up. The investigators thus contend that tDCS targeting the left dlPFC holds promise to improve the control of standing and walking-and ultimately reduce falls-in older adults. Still, the size and duration of tDCS-induced benefits to older adult "fallers" have not been established. Moreover, to date, tDCS delivery has attempted to optimize current flow based on a "typical" brain and has thus not accounted for individual differences in skin, skull, cerebrospinal fluid and brain tissue in the aging brain. Such personalization is now possible with the current flow modeling the investigators propose.
The Overall Aim is to compare, in older adults with previous falls, the effects of a personalized tDCS intervention designed to target the left dlPFC on the dual task costs to standing and walking, and other physical and cognitive factors that are on the causal pathway to falls and important to everyday function. The investigators will conduct a randomized, sham-controlled, double-blinded trial with assessments at baseline and post-intervention (immediate, 3-, 6-month follow-up) in 120 non-demented men and women (60 per arm) aged 60 or older who are at risk of falls and report mobility and balance problems and a fear of falling, yet have no major neural or musculoskeletal disorders that explain their falls. The tDCS intervention will comprise 20, 20-minute sessions of tDCS over a 4-week period.
The investigators hypothesize that, in older adults at risk of falls and over a 6-month follow-up, a personalized tDCS intervention targeting the left dlPFC, as compared to sham, will mitigate dual task costs to the control of standing and walking and enhance other metrics of both physical and cognitive function.
Study Oversight
Has Oversight DMC:
True
Is a FDA Regulated Drug?:
False
Is a FDA Regulated Device?:
False
Is an Unapproved Device?:
None
Is a PPSD?:
None
Is a US Export?:
None
Is an FDA AA801 Violation?: