The declination on cognitive and motor functions in older adults increases the difficulty to achieve successful aging. Previous studies had reported that contrast to the traditional cognitive training methods, computer cognitive training (CCT) is comparable or has better effect on the cognitive function improvement with elders.On the other hand, some researchers claimed motor-cognitive dual-task training may possess greater effects than single cognitive training on cognitive functions. However, it is still on debate. Therefore, the research aims to investigate cognitive and motor benefits to healthy older adults over 65s trained by our computer-based cognitive game with high and low level of motor engagements.The research questions include: (1) Is CCT beneficial of cognitive functions? (2) Does CCT with high level of motor engagements (i.e. motor-cognitive dual-task training) have greater effects than single cognitive training on cognitive functions? (3) Can the training effect remain?
Quasi-experimental design was adapted in our research.There are four time-series assessments during the experiment: baseline, pretest, posttest, and follow-up. After the baseline assessment, participants were randomized to two groups: gross-motor group (GMG) and fine-motor group (FMG). The intervals between baseline and pretest as well as between pretest and posttest were both 4 weeks, while the interval between posttest and follow-up was 8 weeks. The investigators developed a computer-based cognitive game and compared the efficacy of cognitive and motor functions between computer-based cognitive game combining two different demands on motor control. Investigators hypothesized: All participants who take part in the computer-based cognitive game training don't have learning effects on pretest and are able to improve cognitive functions including short-term memory, divided attention and inhibitory function after intervention; Gross-motor group make more progress than fine-motor group on cognitive and motor functions after intervention. Furthermore, gross-motor group maintained more training effect over cognitive and motor functions at follow-up than fine-motor group.
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
HEALTH_SERVICES_RESEARCH
Masking
NONE
Enrollment
16
First task was short-term memory training. Participants were instructed to memorize different colored circles with ordinal numbers which would disappear later. They triggered correct colored sensor in sequence according to their memory. Second task was divided attention training. Different colored circles with ordinal numbers would not disappear this time.The participants should trigger correct colored sensor according to their sequence. Third task was inhibitory function training. There were red and green lights, just like the traffic light, hung up at the upper left of the scene. Red light represented prohibition of triggering the colored sensor, while green light urged to trigger it. Yellow, red, blue and green circles showed up randomly and moved toward the beige region. When the circle came extremely closer to the beige region, the traffic light was randomized to lighten up red or green.The participants should judge and trigger the correct colored sensor.
National Taiwan University Hospital
Taipei, Taiwan
Change from Baseline Montreal Cognitive Assessment (MoCA) Taiwan Version at the 4th, 8th and 16th weeks
overall cognitive function
Time frame: baseline, 4th weeks pretest, 8th weeks posttest, 16th weeks follow-up
Change from Baseline Digit Span Task-forward (DS-forward) at the 4th, 8th and 16th weeks
short-term memory
Time frame: baseline, 4th weeks pretest, 8th weeks posttest, 16th weeks follow-up
Change from Baseline Color Trails Test-2 (CTT-2) at the 4th, 8th and 16th weeks
divided attention
Time frame: baseline, 4th weeks pretest, 8th weeks posttest, 16th weeks follow-up
Change from Baseline Stroop Color Word Test (SCWT) at the 4th, 8th and 16th weeks
inhibitory function
Time frame: baseline, 4th weeks pretest, 8th weeks posttest, 16th weeks follow-up
Change from Baseline Nine Hole Peg Test (NHPT) at the 4th, 8th and 16th weeks
motor function of upper limbs
Time frame: baseline, 4th weeks pretest, 8th weeks posttest, 16th weeks follow-up
Change from Baseline Get-Up and Go Test (GUG) at the 4th, 8th and 16th weeks
motor function of lower limbs and balance
Time frame: baseline, 4th weeks pretest, 8th weeks posttest, 16th weeks follow-up
Change from Baseline Five-Times-Sit-to-Stand Test (FTSST) at the 4th, 8th and 16th weeks
motor function of lower limbs and balance
Time frame: baseline, 4th weeks pretest, 8th weeks posttest, 16th weeks follow-up
Change from 4th weeks Game1 (first scenario) evaluated the performance of short-term memory at 8th weeks
Game assessment was a new way to evaluate cognitive performance of the participant through the score. All participants proceeded all three scenarios but challenged same degree of difficulty.
Time frame: 4th weeks pretest, 8th weeks posttest
Change from 4th weeks Game2 (second scenario) evaluated divided attention at 8th weeks
Game assessment was a new way to evaluate cognitive performance of the participant through the score. All participants proceeded all three scenarios but challenged same degree of difficulty.
Time frame: 4th weeks pretest, 8th weeks posttest
Change from 4th weeks Game3 (third scenario) evaluated inhibitory function at 8th weeks
Game assessment was a new way to evaluate cognitive performance of the participant through the score. All participants proceeded all three scenarios but challenged same degree of difficulty.
Time frame: 4th weeks pretest, 8th weeks posttest
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