We conducted a comprehensive search of PubMed, Cochrane Library, Embase, CINAHL, Web of Science, Scopus, China National Knowledge Infrastructure, and Wanfang databases from inception to March 2025, without language restrictions. Additionally, we manually searched the references of included studies and relevant published reports to identify eligible studies. A search strategy was developed for PubMed and the other databases (Table S1 in Multimedia Appendix 1).

We selected the studies based on the following inclusion and exclusion criteria (Textbox 1).

The search was conducted by the first author and recorded in a Microsoft Excel file, from which duplicate entries were subsequently removed. Two independent reviewers (CH and XL) manually screened each title and abstract, and if necessary, a third reviewer (SZ) was consulted to resolve any disagreements. All full texts that met the inclusion criteria were included in the analysis.

Two researchers (CH and XL) independently extracted and recorded the following information from the enrolled studies: (1) study characteristics (author, publication year, country, study design, sample size, age, sex, and PR exercise training program), (2) methodological characteristics, and (3) outcome indicators (exercise capacity, health-related quality of life (HRQL), severity of dyspnea, and psychological state). Any disagreements were resolved by a third researcher (SZ).

The risk of bias in individual studies was evaluated by two independent researchers (CH and XL) using the revised Cochrane Risk of Bias tool [16], which assesses the randomization process, adherence to interventions, completeness of outcome data, outcome measurement, and selection of reported results. The quality was rated as “low risk,” “some concerns,” or “high risk.” The Grading of Recommendations Assessment, Development, and Evaluations (GRADE) approach was employed to assess the quality of evidence for individual outcomes [17]. The quality of evidence was classified as high, moderate, low, or very low by evaluating five domains: risk of bias, inconsistency, indirectness, imprecision, and publication bias. Any disagreements were resolved by a third researcher (SZ).

Data analysis was conducted using Review Manager 5.3 (The Cochrane Collaboration) and Stata 17 (StataCorp LLC). To address potential baseline imbalances, we performed a pooled analysis using change scores, defined as the difference between baseline and postintervention values [18]. A random-effects model was used to estimate the aggregated outcomes. For dichotomous variables, we calculated odds ratios (ORs) with 95% CIs, while for continuous variables, mean differences (MDs) with 95% CIs were used. The overall results of the meta-analysis were visualized with forest plots. Forest plots visually summarize meta-analysis results by displaying individual study effect sizes (eg, risk ratios) with CIs, weighted summary effects, and heterogeneity metrics such as I². Heterogeneity among studies was assessed using Cochran Q test and quantified with the I² statistic. We interpreted I² values of 25%, 50%, and 75% as indicative of low, moderate, and high heterogeneity, respectively. Statistical significance was established at a 2-tailed P value of less than .05. The credibility of the evidence was evaluated using the GRADE approach, implemented through GRADEpro GDT software (Cochrane Collaboration). To assess potential publication bias, we generated funnel plots for outcomes with 10 or more studies and conducted Egger and Begg tests when appropriate. Subgroup analyses were performed based on the MSG system used (Xbox Kinect, Nintendo Wii, or Subor) to explore potential sources of heterogeneity and evaluate the consistency of treatment effects across different platforms.

This systematic review and meta-analysis was conducted in accordance with the Cochrane Handbook for Systematic Reviews of Interventions and the PRISMA (Preferred Reporting Items for Systematic Reviews and Meta-Analyses) 2020 statement (Checklist 1). The protocol was registered with the International Prospective Register of Systematic Reviews (PROSPERO; CRD42024603044). Since the data for this study were derived from previously published research, ethical approval and informed consent were not required.

The flow diagram of the selection procedure is presented in Figure 1. Initially, 3374 papers were identified through database searches. After the removal of duplicates, 2123 papers remained for the first screening. Following a review of titles and abstracts, 265 papers were selected for full-text evaluation, resulting in the exclusion of 1858 papers. Ultimately, 12 trials involving 776 participants met the inclusion criteria and were incorporated into the quantitative synthesis (Figure 1). Tables 1 and 2 summarize the characteristics of the included studies, which were published between 2014 and 2025. The majority of these studies were conducted in China (n=8) [12,19-25], while the remainder were distributed across Poland (n=2) [13,26], Indonesia (n=1) [27], and Italy (n=1) [28]. Intervention durations ranging from 2 to 18 weeks, most commonly between 6 and 8 weeks. A total of 3 main gaming systems were used: the Subor systems (6 studies) [12,19-23], Kinect-based systems (4 studies) [13,24-26], and Nintendo Wii systems (2 studies) [27,28]. Sessions typically lasted 20 to 30 minutes and were conducted 5 times weekly under professional supervision with established safety monitoring protocols.

Based on the revised Cochrane Risk of Bias tool assessment of these 12 RCTs, all studies demonstrated “Some concerns” in the overall risk of bias evaluation, with none rated as high risk. In specific domains, the randomization process exhibited mixed quality, with 33.3% (4/12) of studies rated as low risk and 66.7% (8/12) as having some concerns. All studies (12/12, 100%) were rated as “Some concerns” for deviations from intended interventions, indicating potential issues with protocol adherence. However, all studies demonstrated a low risk of bias regarding missing outcome data and the selection of reported results, reflecting good follow-up rates and appropriate outcome reporting. The measurement of outcomes was generally appropriate, with 66.7% (8/12) of studies showing low risk and 33.3% (4/12) showing some concerns. Further details are provided in Figure S1A and S1B in Multimedia Appendix 2.

The quality of all synthesized evidence was assessed as “low” or “very low” using the GRADE approach (Table S2 in Multimedia Appendix 3). Sensitivity analysis used the selective model analysis method, wherein both fixed-effect and random-effect models were applied to the aforementioned experimental data, yielding consistent results. A leave-one-out analysis was conducted by sequentially excluding each study and re-estimating the analysis. This process revealed minimal changes in all indicators compared with the original analysis, suggesting low sensitivity and enhancing the robustness and reliability of the results. Additionally, the funnel plot for the 6MWD (10 studies, P_Egger=0.69) showed no apparent publication bias.

This meta-analysis demonstrates that PR+MSG shows advantages over routine PR in improving exercise capacity, balance function, symptom control, quality of life, and psychological outcomes across multiple health domains. These findings provide scientific evidence supporting the integration of gaming technology into rehabilitation programs.

This meta-analysis represents the first comprehensive review specifically focusing on MSG-assisted exercise training in patients with COPD, distinguishing itself from previous reviews that broadly examined various technological interventions. By systematically evaluating multiple outcomes (exercise capacity, symptoms, quality of life, and psychological parameters) through RCTs, this study provides the first synthesis of evidence on the comprehensive benefits of MSG-based rehabilitation. These findings offer practical guidance for enhancing patient care in contemporary clinical settings while suggesting promising directions for future research in technology-enhanced rehabilitation strategies.

Several key limitations warrant consideration in this study. First, methodologically, effective blinding was challenging due to the distinctive nature of game-assisted rehabilitation compared with conventional approaches, potentially introducing implementation bias. The heterogeneity among included studies manifested primarily in the varying gaming platforms and rehabilitation protocols, as well as inconsistent intervention specifications (intensity, frequency, and duration), which may have introduced clinical heterogeneity and affected outcome comparability. While we identified these possible contributing factors, the relatively small number of eligible studies precluded us from conducting meaningful subgroup analyses to quantify their specific contributions to the observed heterogeneity. Additionally, most included studies were constrained by small sample sizes and relatively short follow-up periods, limiting both the assessment of long-term efficacy and internal validity. The overall methodological quality of the included studies was suboptimal, with most evidence rated as “low” or “very low” quality. Furthermore, this study did not systematically evaluate the cost-effectiveness of implementing game-assisted rehabilitation systems in clinical settings. These limitations underscore the need for future research to conduct larger, well-designed RCTs with standardized intervention protocols, extended follow-up periods, and comprehensive cost-benefit analyses to provide more reliable theoretical guidance for clinical practice.

The findings demonstrate that incorporating MSGs into PR programs offers a promising strategy to enhance both clinical outcomes and patient engagement. This approach may be particularly beneficial for three key patient populations: those with poor adherence to conventional rehabilitation protocols, patients reporting exercise-related anxiety or low motivation, and individuals requiring concurrent physical and psychological support. Health care providers can leverage this technology-enhanced rehabilitation method to create more personalized and engaging treatment plans, potentially improving long-term adherence and rehabilitation outcomes. Additionally, the game-based format may help clinicians better monitor patient progress and adjust intervention intensity in real-time, though implementation should consider individual patient preferences, physical capabilities, and facility resources.

This systematic review and meta-analysis suggests that PR+MSG may improve multiple clinical outcomes in patients with COPD, including exercise capacity, respiratory symptoms, HRQL, and psychological well-being. The observed heterogeneity in effectiveness across gaming platforms highlights the importance of personalized intervention selection based on individual patient characteristics and health care resource settings. While our results indicate potential benefits, the predominance of low-quality evidence underscores the need for risk-benefit assessment in clinical implementation of PR+MSG approaches. Future research priorities should include larger, methodologically rigorous RCTs, developing standardized intervention protocols, investigating sustained therapeutic effects, and conducting cost-effectiveness analyses to establish more definitive evidence for the optimal implementation of gaming technology in PR programs.