Measured and Perceived Effects of Upper Limb Home-Based Exergaming Interventions on Activity after Stroke: A Systematic Review and Meta-Analysis
Abstract
:1. Introduction
2. Materials and Methods
2.1. Search Strategy
2.2. Selection of Studies
2.3. Data Extraction and Management
2.4. Quality Assessment
2.5. Outcome Measurements
2.6. Meta-Analysis
3. Results
3.1. Study Identification
3.2. Participants
3.3. Interventional Group
3.4. Comparison
3.5. Training Settings
3.6. Outcome Measures
3.7. Immediate Effects on Upper Limb Activity
3.8. Long Term Effects on Upper Limb Activity
3.9. Quality Assessment
4. Discussion
4.1. Immediate Effects on Upper Limb Activity
4.2. Long Term Effects on Upper Limb Activity
4.3. Risk of Bias
4.4. Limitations
4.5. Perspectives
5. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Acknowledgments
Conflicts of Interest
Appendix A
Section and Topic | Item # | Checklist Item | Location Where Item Is Reported |
---|---|---|---|
TITLE | |||
Title | 1 | Identify the report as a systematic review. | 1 |
ABSTRACT | |||
Abstract | 2 | See the PRISMA 2020 for Abstracts checklist. | 12 |
INTRODUCTION | |||
Rationale | 3 | Describe the rationale for the review in the context of existing knowledge. | 29 |
Objectives | 4 | Provide an explicit statement of the objective(s) or question(s) the review addresses. | 111 |
METHODS | |||
Eligibility criteria | 5 | Specify the inclusion and exclusion criteria for the review and how studies were grouped for the syntheses. | 125 |
Information sources | 6 | Specify all databases, registers, websites, organisations, reference lists and other sources searched or consulted to identify studies. Specify the date when each source was last searched or consulted. | 120 |
Search strategy | 7 | Present the full search strategies for all databases, registers and websites, including any filters and limits used. | 116 |
Selection process | 8 | Specify the methods used to decide whether a study met the inclusion criteria of the review, including how many reviewers screened each record and each report retrieved, whether they worked independently, and if applicable, details of automation tools used in the process. | 138 |
Data collection process | 9 | Specify the methods used to collect data from reports, including how many reviewers collected data from each report, whether they worked independently, any processes for obtaining or confirming data from study investigators, and if applicable, details of automation tools used in the process. | 144 |
Data items | 10a | List and define all outcomes for which data were sought. Specify whether all results that were compatible with each outcome domain in each study were sought (e.g., for all measures, time points, analyses), and if not, the methods used to decide which results to collect. | 164 |
10b | List and define all other variables for which data were sought (e.g., participant and intervention characteristics, funding sources). Describe any assumptions made about any missing or unclear information. | 144 | |
Study risk of bias assessment | 11 | Specify the methods used to assess risk of bias in the included studies, including details of the tool(s) used, how many reviewers assessed each study and whether they worked independently, and if applicable, details of automation tools used in the process. | 154 |
Effect measures | 12 | Specify for each outcome the effect measure(s) (e.g., risk ratio, mean difference) used in the synthesis or presentation of results. | 179 |
Synthesis methods | 13a | Describe the processes used to decide which studies were eligible for each synthesis (e.g., tabulating the study intervention characteristics and comparing against the planned groups for each synthesis (item #5)). | 180 |
13b | Describe any methods required to prepare the data for presentation or synthesis, such as handling of missing summary statistics, or data conversions. | 186 | |
13c | Describe any methods used to tabulate or visually display results of individual studies and syntheses. | 199 | |
13d | Describe any methods used to synthesize results and provide a rationale for the choice(s). If meta-analysis was performed, describe the model(s), method(s) to identify the presence and extent of statistical heterogeneity, and software package(s) used. | 179 | |
13e | Describe any methods used to explore possible causes of heterogeneity among study results (e.g., subgroup analysis, meta-regression). | 195 | |
13f | Describe any sensitivity analyses conducted to assess robustness of the synthesized results. | 154 | |
Reporting bias assessment | 14 | Describe any methods used to assess risk of bias due to missing results in a synthesis (arising from reporting biases). | 154 |
Certainty assessment | 15 | Describe any methods used to assess certainty (or confidence) in the body of evidence for an outcome. | 200 |
RESULTS | |||
Study selection | 16a | Describe the results of the search and selection process, from the number of records identified in the search to the number of studies included in the review, ideally using a flow diagram. | 202 |
16b | Cite studies that might appear to meet the inclusion criteria, but which were excluded, and explain why they were excluded. | 219 | |
Study characteristics | 17 | Cite each included study and present its characteristics. | 287 |
Risk of bias in studies | 18 | Present assessments of risk of bias for each included study. | 405 |
Results of individual studies | 19 | For all outcomes, present, for each study: (a) summary statistics for each group (where appropriate) and (b) an effect estimate and its precision (e.g., confidence/credible interval), ideally using structured tables or plots. | 347,371 |
Results of syntheses | 20a | For each synthesis, briefly summarise the characteristics and risk of bias among contributing studies. | 347,371 |
20b | Present results of all statistical syntheses conducted. If meta-analysis was done, present for each the summary estimate and its precision (e.g., confidence/credible interval) and measures of statistical heterogeneity. If comparing groups, describe the direction of the effect. | 347,371 | |
20c | Present results of all investigations of possible causes of heterogeneity among study results. | 347,371 | |
20d | Present results of all sensitivity analyses conducted to assess the robustness of the synthesized results. | 347,371 | |
Reporting biases | 21 | Present assessments of risk of bias due to missing results (arising from reporting biases) for each synthesis assessed. | 347,371 |
Certainty of evidence | 22 | Present assessments of certainty (or confidence) in the body of evidence for each outcome assessed. | 347,371 |
DISCUSSION | |||
Discussion | 23a | Provide a general interpretation of the results in the context of other evidence. | 411 |
23b | Discuss any limitations of the evidence included in the review. | 505 | |
23c | Discuss any limitations of the review processes used. | 505 | |
23d | Discuss implications of the results for practice, policy, and future research. | 525 | |
OTHER INFORMATION | |||
Registration and protocol | 24a | Provide registration information for the review, including register name and registration number, or state that the review was not registered. | |
24b | Indicate where the review protocol can be accessed, or state that a protocol was not prepared. | ||
24c | Describe and explain any amendments to information provided at registration or in the protocol. | ||
Support | 25 | Describe sources of financial or non-financial support for the review, and the role of the funders or sponsors in the review. | |
Competing interests | 26 | Declare any competing interests of review authors. | 576 |
Availability of data, code and other materials | 27 | Report which of the following are publicly available and where they can be found: template data collection forms; data extracted from included studies; data used for all analyses; analytic code; any other materials used in the review. |
Appendix B. Search Strategy
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Author (Year) [ref.] | Study Design Intervention Time Follow Up | Participants Sample Size n, Male/Female, Age Year, Months since Stroke Impairment (Min–Max) Mean (SD) or Median Mean (Interquartile Range) | Interventional Group (IG) Hardware Software Movements Control Group (CG) Type Movements | No of Sessions, Frequency and Length | Outcome Measures | Main Findings End of Intervention Effectiveness for IG Comparison with CG Follow Up Effectiveness for IG Comparison with CG | Risk of Bias (PEDro) |
---|---|---|---|---|---|---|---|
Adie et al. (2016) [31] | RCT, multicentric 6 wk. 24 wk. | 235 subacute patients IG: n = 117, 66/51, 66.8 (14.6) yr., 1.9 (1.6) ARAT score (0–57): 41.2 (15.9) CG: n = 118, 65/53, 68.0 (11.9) yr., 1.8 (1.6) ARAT: 41.0 (16.6) | IG: Wii™ remote control 4 Wii™ sports games Arm unilateral movements CG: Arm exercises based on the GRASP n.a. | 15 min warm-up, 45 min/d, 6 wk. | Observation:
| Both groups showed an improved arm function (ARAT) No significant difference in arm function (ARAT) between groups Both groups showed an improved arm function (ARAT) or occupational performance (COPM) No significant difference between groups | 8 |
Ballester et al. (2017) [34] | RCT 3 wk. 12 wk. | 35 chronic patients IG: n = 17, 8/9, 65.1 (10.3), 35.3 (25.2) CAHAI-13 (13–91): 52.8 (23.1) CG: n = 18, 6/12, 61.8 (12.9), 26.2 (13.9) CAHAI-13: 53.5 (22.5) | IG: RGS system—Kinect™ motion capture device, a pair of data gloves (DGTech Engineering Solutions) 1 custom game with 3 subtasks Shoulder, elbow and finger bilateral movements CG: horizontal and vertical stacking and unstacking of plastic cups Shoulder, elbow and finger bilateral movements | 1–3 sessions, 5/wk., 3 wk. IG: 2min30 AEMF + 26min40 session (10 min per hand) CG: 20 min (10 min per hand) | Observation:
n.a. | Significantly greater in arm function (CAHAI-13) for the IG Significant difference between groups in favor of IG No retention of the improvements in arm function (CAHAI-13) No significant difference between groups | 6 |
McNulty et al. (2015) [35] | RCT 2 wk. 24 wk. | 41 chronic patients IG: n = 21, 13/8, 59.9 (13.8), 11.0 (3.1) Motor classification (low:moderate:high): 3/8/10 CG: n = 20, 18/2, 56.1 (17.0), 6.5 (2.1) Motor classification: 5/7/8 | IG: WMT—Wii™ remote control (+ self-adhesive wrap if poor grip strength) 5 Wii™ sports games + game specific drills Arm and hand unilateral movements, standing CG: mCIMT—A mitt worn on the less-affected hand, shaping practice tailored Arm and hand unilateral movements | 60 min, 10 sessions, 2 wk. CG: Arm use 90% of the walking time + 15–20 min training tasks | Observation:
| Both groups showed an improved arm function (WMFT-tt) and perceived daily use (MALQOM) No significant difference between groups Both groups showed maintained improvements in arm function (WMFT-tt) No significant difference between groups | 7 |
Nijenhuis et al. (2016) [38] | RCT, pilot 6 wk. 8 wk. | 20 chronic patients IG: n = 10, 7/2, 58 (48–65), 11 (10–26) ARAT score (0–57): 31.0 (3.5–50.0) CG: n = 10, 3/7, 62 (54–70), 12 (10–30) ARAT: 25.0 (3.8–30.8) | IG: SCRIPT (custom passive dynamic wrist and hand orthosis sensor), SaeboMAS (gravity compensation of the proximal arm) 3 custom games Arm and hand unilateral movements CG: Conventional exercises from an exercise book 34 exercises Arm and hand unilateral movements | 30 min, 6/wk., 6 wk. | Observation:
| No significant difference between groups IG showed moderate improvements for arm function (ARAT) No significant difference between groups | 5 |
Piron et al. (2009) [37] | RCT 4 wk. 4 wk. | 36 chronic patients IG: n = 18, 11/7, 66.0 (7.9), 14.7 (6.6) n/a CG: n = 18, 10/8, 64.4 (7.9), 11.9 (3.7) n/a | IG: VRRS.net®: 3D motion tracking system (Polhemus 3Space Fastrack®), a magnetic receiver attached to a real object, videoconferencing system 5 virtual tasks Arm unilateral movements CG: Conventional physiotherapy in the center Arm unilateral movements + postural control | 60 min, 5/wk., 4 wk. | Observation: n.a. Self-report:
| Both groups showed significant improvements in patient’s perceived manual ability (ABILHAND) No significant difference between groups Both groups showed maintained improvements in patient’s perceived manual ability (ABILHAND) No significant difference between groups | 6 |
Rand et al. (2016) [36] | RCT, pilot 5 wk. 4 wk. | 24 chronic patients IG: n = 13, 9/4, 59.1 (10.5), 19.6 (11.3) FMA-UE (0–60): 35.4 (11.0) CG: n = 11, 6/5, 64.9 (6.9), 13.0 (6.0) FMA-UE: 41.3 (10.7) | IG: Kinect™ (sensor) and EyeToy™ (camera) 6 commercial games: 3 Kinect™ and 3 EyeToy™ games Shoulder and elbow unilateral and trunk movements, standing CG: 15–25 exercises and activities of the GRASP Arm and hand bilateral movements, seated | 60 min, 6/wk., 5 wk. | Observation:
| Both groups showed significant improvements in arm function (ARAT), perceived daily use (MAL) and manual dexterity (BBT) No significant difference between groups Both groups showed significant improvements in arm function (ARAT) No significant difference between groups | 6 |
Standen et al. (2017) [33] | RCT 8 wk. None | 27 subacute patients IG: n = 17, 8/9, 59 (12.03), 5.5 (4.0–14.9) Median WFMT (seconds): 2.60 (1.65, 6.00) CG: n = 10, 8/2, 63 (14.06), 4.0 (2.0–5.1) Median WFMT (seconds): 3.34 (1.9–4.9) | IG: Virtual glove with Wiimotes™ 3 custom games Arm and hand unilateral movements CG: Usual care n/a | IG: Max 20 min, 3/d, 8 wk. CG: n/a | Observation:
| IG showed significantly greater change in perceived daily use (MAL) A significant difference between groups in favor of IG n.a. | 6 |
Wolf et al. (2015) [32] | RCT, multicentric 8 wk. None | 99 subacute patients IG: n = 51, 25/26, 59.1 (14.1), 3.8 (1.7) FMA-UE (0–66): 34.1 (12.1) CG: n = 48, 31/20, 54.7 (12.2), 4.2 (1.5) FMA-UE: 33.3 (12.0) | IG: HMP + HEP Robotic device with pneumatic artificial muscle, touchscreen, and Web-based monitoring (n/a) games HMP wrist and fingers unilateral movements + HEP shoulder/arm, elbow/forearm, wrist/hand, and task-based activities CG: classic home exercise program HEP shoulder/arm, elbow/forearm, wrist/hand, and task-based activities | 180 min, 5/wk., 8 wk. IG: 120 min of robotic-based exercises and 60 min of functional-based activities CG: 120 min of traditional impairment-based exercises and 60 min of functional activities | Observation:
n.a. | Both groups showed significant improvement in arm function (ARAT and WMFT) A difference between groups were observed for CG on WMFT n.a. | 8 |
Zondervan et al. (2016) [39] | RCT, crossover 3 wk. 4 wk. | 18 chronic patients IG: n = 9, 5/3, 59 (35–74), 60.0 (48.0) FMA-UE (0–66): 56.4 (6.3) CG: n = 9, 5/4, 60 (45–74), 36.0 (12.0) FMA-UE: 53.8 (8.9) | IG: MusicGlove: an instrumented glove, laptop screen 1 custom game Fingers and thumb unilateral movements CG: a pamphlet of hand exercises Unilateral passive/active wrist, hand and fingers movements | 180 min, 3/wk., 3 wk. | Observation:
| Both groups showed significant improvement in dexterity (BBT) No significant difference between groups IG showed significantly greater improvements in perceived daily use (MAL) A significant difference between groups in favor of IG | 7 |
Authors (Year) | C1 | C2 | C3 | C4 | C5 | C6 | C7 | C8 | C9 | C10 | C11 | PEDro Score |
---|---|---|---|---|---|---|---|---|---|---|---|---|
Adie et al. (2016) [31] | YES | YES | YES | YES | NO | NO | YES | YES | YES | YES | YES | 8 |
Ballester et al. (2017) [34] | YES | YES | YES | YES | NO | NO | NO | YES | NO | YES | YES | 6 |
McNulty et al. (2015) [35] | YES | YES | YES | YES | NO | YES | YES | YES | NO | YES | NO | 7 |
Nijenhuis et al. (2016) [38] | YES | YES | YES | YES | NO | NO | NO | YES | NO | YES | NO | 5 |
Piron et al. (2009) [37] | YES | YES | YES | YES | NO | NO | YES | NO | NO | YES | YES | 6 |
Rand et al. (2017) [36] | YES | YES | NO | YES | NO | NO | YES | YES | NO | YES | YES | 6 |
Standen et al. (2017) [33] | YES | YES | YES | NO | NO | NO | YES | YES | NO | YES | YES | 6 |
Wolf et al. (2015) [32] | YES | YES | YES | YES | NO | NO | YES | YES | YES | YES | YES | 8 |
Zondervan et al. (2016) [39] | YES | YES | YES | YES | NO | NO | YES | YES | NO | YES | YES | 7 |
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Gelineau, A.; Perrochon, A.; Robin, L.; Daviet, J.-C.; Mandigout, S. Measured and Perceived Effects of Upper Limb Home-Based Exergaming Interventions on Activity after Stroke: A Systematic Review and Meta-Analysis. Int. J. Environ. Res. Public Health 2022, 19, 9112. https://doi.org/10.3390/ijerph19159112
Gelineau A, Perrochon A, Robin L, Daviet J-C, Mandigout S. Measured and Perceived Effects of Upper Limb Home-Based Exergaming Interventions on Activity after Stroke: A Systematic Review and Meta-Analysis. International Journal of Environmental Research and Public Health. 2022; 19(15):9112. https://doi.org/10.3390/ijerph19159112
Chicago/Turabian StyleGelineau, Axelle, Anaick Perrochon, Louise Robin, Jean-Christophe Daviet, and Stéphane Mandigout. 2022. "Measured and Perceived Effects of Upper Limb Home-Based Exergaming Interventions on Activity after Stroke: A Systematic Review and Meta-Analysis" International Journal of Environmental Research and Public Health 19, no. 15: 9112. https://doi.org/10.3390/ijerph19159112
APA StyleGelineau, A., Perrochon, A., Robin, L., Daviet, J. -C., & Mandigout, S. (2022). Measured and Perceived Effects of Upper Limb Home-Based Exergaming Interventions on Activity after Stroke: A Systematic Review and Meta-Analysis. International Journal of Environmental Research and Public Health, 19(15), 9112. https://doi.org/10.3390/ijerph19159112