Postural Control Dysfunction and Balance Rehabilitation in Older Adults with Mild Cognitive Impairment
Abstract
:1. Introduction
2. Materials and Methods
3. Results
3.1. Overview of Study Characteristics
3.1.1. Year of Publication
3.1.2. Sample Characteristics
3.1.3. MCI Diagnosis
3.1.4. Group Design
3.1.5. Intervention Paradigms
3.1.6. Intervention Dosage, Intensity, and Retention
3.1.7. Balance Outcomes
3.1.8. Risk of Bias
3.2. Study Results
4. Discussion
5. Conclusions
Author Contributions
Funding
Conflicts of Interest
References
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Author, Year | Sample Characteristics | Primary Diagnosis Criteria for MCI | Study Design | Training Intervention | Comparator Group (s) |
---|---|---|---|---|---|
Anderson-Hanley et al., 2018 [39] | 14 MCI adherent at 6 month, enrollees (83 MCI and 28 cognitively intact), age > 65, predominantly female (66%) | MoCA < 26 | 3 groups: exer-tour (low cognitive demand), exer-score (high cognitive demand), and game-only (no physical exercise, not examined at 6 month); no blinding specified; 83% dropout rate; game-only group reported more sedentary lifestyle (due to high dropout rate for this non-exercising arm, researchers recruited specifically individuals who elected for this group) | exer-tour: virtual reality bike rides, exer-score: pedaling through a videogame | the same videogame operated by a joystick or keyboard |
Choi and Lee, 2018 [40] | MCI (n = 60), age > 65, predominantly female (80%) | MoCA < 26 | 2 groups: ground kayak paddling and control; single (assessor)-blind | paddling exercise performed while sitting on chairs with and without a balance foam | a home exercise program |
Choi and Lee, 2019 [41] | MCI (n = 60), age ≥ 65, predominantly female (85%) | MoCA < 26 | 2 groups: virtual kayak paddling and control; single (assessor)-blind | paddling exercise in a virtual environment | a home exercise program |
Donnezan et al., 2018 [42] | MCI (n = 69), age > 65 | diagnosed by a neuropsychologist with evidence of executive deficits | 4 groups: simultaneous cognitive and physical training (PCT), physical training only (PT), cognitive training only (CT) or a no-intervention control group; no blinding specified | simultaneous cognitive and physical training: cognitive training and physical training delivered simultaneously within the same intervention | physical training: aerobic training on bikes, cognitive training: cognitive games, control: no intervention |
de Oliveira Silva et al., 2019 [43] | 19 MCI & 27 Alzheimer’s disease, age ≥ 65 | structured clinical interview to assess mental disorders according to the DSM-IV | 2 groups: exercise group, control group; single (assessor)-blind; 29% dropout rate in intervention group (7% in control group) | multimodal physical exercise (aerobic, strength, balance, and flexibility) | clinical follow-up without physical training |
Mirelman et al., 2016 [44] | 43 fallers with MCI, 109 older fallers, and 130 fallers with Parkinson’s disease, age 60–90, sex stratified | score of 0.5 on the CDR scale | 2 groups: treadmill training plus virtual reality interventions, treadmill training only; single (assessor)-blind | subjects watched their feet projected on a screen via walking on a treadmill with real-life challenges (including obstacles, multiple pathways, and distractors) simulated | treadmill training alone |
Del Din et al., 2020 [45] | 38 fallers with MCI, 109 older fallers, and 128 fallers with Parkinson’s disease, age 60–90 (subset from Mirelman et al., 2016 [44] | score of 0.5 on the CDR scale | 2 groups: treadmill training plus virtual reality interventions, treadmill training only; single (assessor)-blind | subjects watched their feet projected on a screen via walking on a treadmill with real-life challenges (including obstacles, multiple pathways, and distractors) simulated | treadmill training alone |
Delbroek et al., 2017 [46] | 17 institutionalized MCI, age ≥ 75 | MoCA < 26 | 2 groups: intervention (i.e., virtual reality dual-task training using the BioRescue) or control group (no additional training); single (assessor)-blind | nine exercises which were used to train balance, weight bearing, memory, attention, and dual tasking | no intervention |
Makizako et al., 2012 [47] | 47 aMCI, age ≥ 65, female 46% | intact general cognitive function, MMSE 24–30, and having memory impairment (assessed via education-adjusted scores on the WMS-R Logical Memory II) | 2 groups: multicomponent exercise or control group; single (assessor)-blind | combinations of aerobic exercise, endurance walking, muscle strength training, postural balance retraining, and gait training | attended two education classes about health promotion |
Doi et al., 2013 [48] | 47 aMCI, age ≥ 65, female 46% (same cohort as in Makizako et al., 2012 [47]) | intact general cognitive function, MMSE 24–30, and having memory impairment (assessed via education-adjusted scores on the WMS-R Logical Memory II) | 2 groups: multicomponent exercise or control group; single (assessor)-blind | combinations of aerobic exercise, endurance walking, muscle strength training, postural balance retraining, and gait training | attended two education classes about health promotion |
Fogarty et al., 2016 [49] | 41 aMCI, age > 60 | based on an interview with the participant and an informant about history of cognitive concerns and functional decline, and a review of all available medical, neurological, psychiatric, and neuropsychological test data | 2 groups: a combined Taoist Tai Chi and memory intervention group or memory intervention group; no blinding specified; dropout rates were <20% but those who dropped out had lower cognitive scores than those who completed the interventions | memory intervention plus a low-impact exercise program involving learning the practice of Taoist Tai Chi | a memory intervention program for MCI |
Hagovska and Olekszyova, 2016 [50] | 78 MCI, age 65–75 | confirmed by their psychiatrist and psychologist and based on a standard clinical examination and neuropsychological testing, in line with the criteria defined in the ICD-9-CM 331.83 | 2 groups: CogniPlus or control group, no blinding specified | selected exercises from the CogniPlus program with balance training | daily balance training |
Hagovska et al., 2016 [51] | 78 MCI, age 65–75 (same cohort as in Hagovska and Olekszyova, 2016 [50]) | confirmed by their psychiatrist and psychologist and based on a standard clinical examination and neuropsychological testing, in line with the criteria defined in the ICD-9-CM 331.83 | 2 groups: CogniPlus or control group, no blinding specified | selected exercises from the CogniPlus program with balance training | daily balance training |
Lam et al., 2011 [52] | 329 MCI, age > 65 (interim report for RCT described in Lam et al., 2012 [53]) | CDR 0.5 or satisfying Mayo clinic criteria for aMCI | 2 groups: mind body or control group; double (assessor and trainer)-blind | 24-style Tai Chi | muscle stretching and toning exercises |
Lam et al., 2012 [53] | 261 MCI, age > 65 | CDR 0.5 or satisfying Mayo clinic criteria for aMCI | 2 groups: mind body or control group; double (assessor and trainer)-blind; significant dropout rates (46% in experimental and 22% in control) | 24-style Tai Chi | muscle stretching and toning exercises |
Langoni et al., 2019 [54] | 52 sedentary MCI, age ≥ 60 | medical records, home visits, and ACE score | 2 groups: strength and aerobic exercises group or control group; single (statistician)-blind | strength: ankle weights, elastic bands, and dumbbells; aerobic: walking | no intervention |
Langoni et al., 2019 [55] | 52 sedentary MCI, age ≥ 60 (same cohort as in Langoni et al., 2019 [54]) | medical records, home visits, and ACE score | 2 groups: strength and aerobic exercises group or control group; single (statistician)-blind | strength: ankle weights, elastic bands, and dumbbells; aerobic: walking | no intervention |
Lipardo and Tsang, 2020 [56] | 92 MCI, age ≥ 60, female 79% | determined by a trained neurologist-psychiatrist based on 3 criteria: cognitive level is not normal nor demented, decrease in cognitive ability, and normal performance of basic ADL but with slight impairment in instrumental ADL | 4 groups: combined physical and cognitive training, physical training, cognitive training, or waitlist control group; single (assessor)-blind | combined group: cognitive training elements incorporated in each type of exercise included in physical training group; physical training: multicomponent exercise program on balance, strength, endurance, and flexibility; cognitive training: paper-based cognitive exercises on executive function, memory, attention, and orientation training | no intervention |
Lü et al., 2016 [57] | 45 MCI, age ≥ 65 | MoCA < 26, MMSE ≥ 24 | 2 groups: a dumbbell-training group (DTG) or a control group (CG); single (assessor)-blind | dumbbell-spinning exercises performed on the front part or lateral side of the body | no intervention |
Sungkarat et al., 2017 [58] | 59 aMCI, age ≥ 60, predominantly female (86%) | Petersen’s criteria, MoCA < 26, MMSE ≥ 24 | 2 groups: Tai Chi or control; single (accessor)-blind | 3 weeks Tai Chi classes and 12 weeks practice at home | received educational material |
Yoon et al., 2017 [59] | 30 women with MCI, age > 65 | Korean version of MoCA < 23 | 3 groups: an elastic band-base high-speed power training (HSPT), a low-speed strength training (LSST), or a control group; no blinding specified; significant dropout rates (30% in HSPT, 53% in LSST, and 63% in control); did not report whether baseline characteristics were equivalent among groups | both exercise regimens were based on the use of elastic exercise bands (the elastic band-base HSPT included a contraction phase instructed to be carried out as quickly as possible) | balance and tone exercises |
Author, Year | Training Duration | Training Intensity Progression | Training Frequency | No. of Sessions | Length of Intervention Program | Retention Interval | Balance Outcomes | Balance Related Findings |
---|---|---|---|---|---|---|---|---|
Anderson-Hanley et al., 2018 [39] | 20–45 min | n/a | 2–5×/week | n/a | 6 months | n/a | GUG | Performance in GUG increased significantly more in exer-tour compared with exer-score group (ES = 0.31). |
Choi and Lee, 2018 [40] | 60 min | n/a | 2×/week | 12 | 6 weeks | n/a | TUG test, FRT, and BBS | All balance outcomes were improved in both groups. The ground kayak paddling exercise was more effective for improving FRT than the control (ES = 1.08). |
Choi and Lee, 2019 [41] | 60 min | n/a | 2×/week | 12 | 6 weeks | n/a | ML/AP postural sway and velocity moment with eyes open/closed (EO/EC), OLS, TUG, FRT, BBS, and FSST | All balance outcomes were significantly improved in the virtual kayak paddling group and were superior to those in the control (EO-MLS ES = 0.63; EO-APS ES = 0.6; EO-VM ES = 0.39; EC-MLS ES = 0.51; EC-APS ES = 0.52; EC-VM ES = 0.38; right OLS ES = 1.03; left OLS ES = 0.77; TUG ES = 0.57; FRT ES = 0.44; BBS ES = 1.00; FSST ES = 0.63). |
Donnezan et al., 2018 [42] | 60 min | n/a | 2×/week | 24 | 12 weeks | only training groups evaluated at 6-month retest | TUG | TUG improved after physical training (ES = 0.50 vs. control) and simultaneous cognitive and physical training (ES = 1.29 vs. control). Retention observed at 6 months in the combined training group. |
de Oliveira Silva et al., 2019 [43] | 60 min | n/a | 2×/week | 24 | 12 weeks | n/a | ST_8UG, CoV_8UG, DT_8UG, DTC_8UG | The exercise program improved ST_8UG more than the control in MCI (ES = 0.61). No differences between training groups in individuals with Alzheimer’s disease. |
Mirelman et al., 2016 [44] | 45 min | motor and cognitive challenges increased based on subjects’ performance | 3×/week | 18 | 6 weeks | 6 months | fall rates and fall status (whether a subject had ≥ 2 falls), SPPB | Fall rates and fall status improved similarly in treadmill training and treadmill training plus virtual reality groups in MCI. |
Del Din et al., 2020 [45] | 40 min | n/a | 3×/week | 18 | 6 weeks | 6 months | number of falls, FRA | Both treadmill training and treadmill training plus virtual reality groups reduced FRA in MCI at 6 months post-intervention without between-group interaction. |
Delbroek et al., 2017 [46] | gradually increased from 18 min in week 1 to 30 min in week 5 | n/a | 2×/week | 12 | 6 weeks | n/a | iTUG, iTUG+DT, Tinetti-POMA | The intervention group improved significantly on iTUG total duration (ES = 0.05), turn-to-sit duration (ES = 0.19), and step-time before turn (ES = 1.15). No changes over time for either group in iTUG+DT or Tinetti-POMA. |
Makizako et al., 2012 [47] | 90 min | n/a | 2×/week | n/a | 6 months | n/a | OLS, dual task performance with balance demand | There were no significant improvement effects on balance-related outcomes. |
Doi et al., 2013 [48] | 90 min | n/a | 2×/week | n/a | 6 months | n/a | HR | The intervention group had a significant effect on the vertical HR (ES = 0.64). |
Fogarty et al., 2016 [49] | 90 min | n/a | 2×/week | 20 | 10 weeks | 3 months | postural sway on regular/disturbed surfaces with eyes open/closed | No significant change in postural sway for combined Taoist Tai Chi and memory intervention group compared with memory intervention only group. |
Hagovska and Olekszyova, 2016 [50] | 30 min | n/a | 2×/week | 20 | 10 weeks | n/a | FES-I, Tinetti-POMA, and functional stretching, TUG | The experimental group showed better performance after training in Tinetti-POMA (ES = 0.89) and TUG (ES = 0.87) with dual tasking. |
Hagovska et al., 2016 [51] | 30 min | n/a | 2×/week | 20 | 10 weeks | n/a | BESTest | The experimental group showed better performance after training in BESTest postural reaction (ES = 0.25) and total score (ES = 0.88; largely accounted for by pre-intervention rather than post-intervention differences between groups). 5 other statistically insignificant subscores. |
Lam et al., 2011 [52] | 30 min | n/a | 3×/week | n/a | 1 year | n/a | BBS | The intervention group showed improved BBS score 2 months after completing induction (the induction phase lasted 8-12 weeks; ES = 0.13). |
Lam et al., 2012 [53] | 30 min | n/a | 3×/week | n/a | 1 year | n/a | BBS | The intervention group had better performance over the control group at 1 year (ES = 0.28). |
Langoni et al., 2019 [54] | 60 min | n/a | 2×/week | 48 | 6 months | n/a | BBS, TUG | The training group showed improvement in BBS (ES = 1.08) and TUG (ES = 0.91) after intervention. |
Langoni et al., 2019 [55] | 60 min | increased in strength exercise on incremental number of sets and repetitions and subjects’ performance | 2×/week | 48 | 6 months | n/a | FRT | The training group showed improvement in FRT after intervention (ES = 0.74; control group declined while training group improved). |
Lipardo and Tsang, 2020 [56] | 60–90 min | n/a | 1–3×/week | n/a | 12 weeks | 6 months | fall rate, PPA, TUG | No significant difference among groups on fall rate and PPA score post intervention. TUG improved in cognitive training group (ES = 0.21 vs. waitlist) and combined physical and cognitive training group (ES = 0.55 vs. waitlist; ES = 0.4 vs. physical only; ES = 0.38 vs. cognitive only (primarily accounted for by pre-intervention difference between groups)). |
Lü et al., 2016 [57] | 60 min | n/a | 3×/week | 36 | 12 weeks | n/a | TUG, FRT, ABC | The intervention improved TUG performance compared with control (ES = 0.25). |
Sungkarat et al., 2017 [58] | 50 min | n/a | 3×/week | n/a | 15 weeks | n/a | PPA, PPA parameter scores (e.g., postural away) | Tai Chi group significantly improved PPA score (ES = 0.56) and PPA parameter scores (e.g., postural sway, ES = 0.59) post-intervention than control. |
Yoon et al., 2017 [59] | 60 min | progressively increased with time | 2×/week | 24 | 12 weeks | n/a | SPPB, TUG | SPPB increased significantly in high-speed power training (HSPT) and low-speed strength training (LSST) groups compared with control (ES = 0.89 for HSPT, ES = 0.70 for LSST). HSPT resulted in higher changes in SPPB and TUG versus LSST (ES = 0.36 for SPPB, ES = 0.35 for TUG). |
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Liu, X.; Chen, M.H.; Yue, G.H. Postural Control Dysfunction and Balance Rehabilitation in Older Adults with Mild Cognitive Impairment. Brain Sci. 2020, 10, 873. https://doi.org/10.3390/brainsci10110873
Liu X, Chen MH, Yue GH. Postural Control Dysfunction and Balance Rehabilitation in Older Adults with Mild Cognitive Impairment. Brain Sciences. 2020; 10(11):873. https://doi.org/10.3390/brainsci10110873
Chicago/Turabian StyleLiu, Xuan, Michelle H. Chen, and Guang H. Yue. 2020. "Postural Control Dysfunction and Balance Rehabilitation in Older Adults with Mild Cognitive Impairment" Brain Sciences 10, no. 11: 873. https://doi.org/10.3390/brainsci10110873
APA StyleLiu, X., Chen, M. H., & Yue, G. H. (2020). Postural Control Dysfunction and Balance Rehabilitation in Older Adults with Mild Cognitive Impairment. Brain Sciences, 10(11), 873. https://doi.org/10.3390/brainsci10110873