Short-term Postural Training for Older Adults

Not Applicable

Completed

• Conditions: Aging; Balance
• Interventions: Behavioral: size of error visual feedback

• Registration Number: NCT04137952
• Lead Sponsor: National Cheng-Kung University Hospital

Brief Summary

Generalization refers to skill transfer under various working spaces following motor practice. The extent of generalization effect links causal to in-depth recognition of error properties during motor practice. Idiom says "imperfect practice makes perfect". It could be beneficial for the elderly to gain superior capacity of balance transfer skill under the short-term productive failure learning environments. In contrast to traditional visual feedback that uses error avoidance training to optimize target balance task, the present 3-year proposal is to propose three potential neuro-cognitive strategies to improve motor skill transfer following stabilometer training. The strategies are expected to enhance opportunities of error experience and motor exploration via modified visual feedback, underlying facilitations of attentional resource and error-related neural networks. In the first year, the neuro-cognitive strategy for balance practice is progressive augmentation of visual error size to improve balance skill transfer. In the second year, the neuro-cognitive strategy for balance practice is visual feedback with virtual uncertainness of motor goal. In the third year, the neuro-cognitive strategy for balance practice is stroboscopic vision. EEG and central of pressure will be processed with non-linear approaches. Graph theory will characterize EEG functional connectivity and brain network efficiency regarding to brain mechanisms for practice-related leaning transfer. Trajectories of central of pressure will be analyzed with stabilogram diffusion analysis to reveal behavior mechanisms for practice-related variations in feedback and feedforward process for error corrections.

Detailed Description

Not available

Study Timeline

• Study Start: 2019-08-01
• Study First Submitted: 2019-10-20
• Study First Submitted QC: 2019-10-22
• Study First Posted: 2019-10-24
• Status Verified: 2021-06
• Primary Completion: 2022-12-30
• Study Completion: 2022-12-30
• Last Update Submitted: 2023-11-10
• Last Update Posted: 2023-11-13

Recruitment & Eligibility

• Status: COMPLETED
• Sex: All
• Target Recruitment: 150

Inclusion Criteria

• Age above 60 years old healthy older adults without a history of falls.
• Able to understand and give informed consent.
• The Mini-Mental State Examination test score above 25-30.
• Lower limb muscle strength is evaluated as G grade
• The corrected visual acuity was within the normal range.

Exclusion Criteria

• Any known history of mental illness
• Any neuromuscular or degenerative neurological disease(ex:stroke、SCI、TBI...etc)
• Any known history of cerebral cerebellar disease or intracranial metal implants.
• Weak of hearing or wearing a hearing aid

Study & Design

• Study Type: INTERVENTIONAL
• Study Design: PARALLEL

Arm && Interventions

Group	Intervention	Description
intermittent visual gain	size of error visual feedback	Day1 (Pretest): 1. stabilometer stance with wearing flash glasses (low frequency with opaque ratio 50%), 4 times/45 sec 2. stabilometer stance with wearing flash glasses (high frequency with opaque ratio 50%), 4 times/45 sec. 3. stabilometer stance with wearing flash glasses (clear), 4 times/45 sec 4. air pillow stance, 8 times/1 min Day2 (training section): 1. Exp. group:Posture tracking with wearing flash glasses (low frequency with opaque ratio 50%), 12 times/45 sec. 2. Control group:Posture tracking with wearing flash glasses (clear), 12 times/45 sec. Day3 (Posttest): 1. stabilometer stance with wearing flash glasses (low frequency with opaque ratio 50%), 4 times/45 sec 2. stabilometer stance with wearing flash glasses (high frequency with opaque ratio 50%), 4 times/45 sec 3. stabilometer stance with wearing flash glasses (clear), 4 times/45 sec 4. air pillow stance, 8 times/1 min
deterministic visual error gain	size of error visual feedback	Day1(Pretest): 1. stabilometer stance, 3 times/1 min 2. air pillow stance, 3 time/30 sec 3. poture-supraposture dual task, 3 times/1 min Day2 to Day5: 1. Exp.group:27 times of posture tracking with high visual error gain. 2. Control group:27 times of posture training with normal visual error gain. Day6 (Posttest): 1. stabilometer stance, 3 times/1 min 2. air pillow stance, 3 time/30 sec 3. poture-supraposture dual task, 3 times/1 min
stochastic visual noise	size of error visual feedback	Day1(Pretest): 1. stabilometer stance, 3 times/1 min 2. air pillow stance, 3 time/30 sec 3. poture-supraposture dual task, 3 times/1 min Day2 to Day5: 1. Exp.group A:27 times of posture training with posture tracking signal-to-noise ratio=2:1. 2. Exp.group B:27 times of posture training with posture tracking signal-to-noise ratio=4:1. 3. Control group:27 times of posture training with normal visual error gain. Day6(Posttest): 1. stabilometer stance, 3 times/1 min 2. air pillow stance, 3 time/30 sec 3. poture-supraposture dual task, 3 times/1 min

Primary Outcome Measures

Name	Time	Method
EEG graph analysis	through study completion, an average of 1 year	Graph theory will characterize EEG functional connectivity and brain network efficiency regarding to brain mechanisms for practice-related leaning transfer.

Secondary Outcome Measures

Name	Time	Method
stabilogram diffusion analysis of central of pressure	through study completion, an average of 1 year	Trajectories of central of pressure will be analyzed with stabilogram diffusion analysis to reveal behavior mechanisms for practice-related variations in feedback and feedforward process for error corrections.
root mean sqaure error of stabilometer	through study completion, an average of 1 year	The root-mean-square value of the tracking trajectory of stabilometer and the target signal.

Trial Locations

Locations (1)

National Chen Kong University Hospital; 🇨🇳 Taian, Eastern District, Taiwan