The bibliometric analysis was conducted in the open-access R-Based Bibliometrix package designed by Aria and Cuccurullo [28]. This has been favored due to its smooth interaction with Web of Science (WoS) and fully exploits the Keyword Plus property for a beautiful analysis of exergaming research [29].

Combining data from different databases can lead to inconsistencies in citation metrics, metadata, and affiliation information, which may negatively impact the accuracy and reliability of the analysis [30]. For this reason, in this research, we decided to use 1 database for the study, that is, the WoS. WoS offers comprehensive options for analysis due to its good citation metrics, elaborate metadata structure, and important tools like Keyword Plus, which provides an increased number of terminologies in addition to keywords provided by the authors [31].

The searches included peer-reviewed original and review papers published from 1997 to 2024. According to the search string applied, the earliest accessible indexed record from WoS dated back to 1997. Therefore, 1997 was used as the initial cutoff point for inclusion. Two independent researchers (AK and EK) carried out the searches, and the retrieved data were evaluated independently on a Microsoft Excel database for relevance to the study scope. Search strategies were based on a literature review, and the search prompt was created with search strategies, such as (TI=(“exergame*” OR “gamercising” OR “exergaming” OR “gamercize*” OR “active video game*”)). The detailed search strategy appears in Multimedia Appendix 1. The WoS search resulted in 2663 studies. No language restrictions were applied.

As part of the data cleaning process, duplicate records were removed (n=2), and author names, affiliations, and journal titles were manually reviewed and standardized by 2 researchers to ensure consistency and reduce misclassification. Studies without accessible abstracts or full texts, those published from 2025 onward (n=5), and gray literature (n=1030) were excluded. Gray literature refers to academic work available in journals, books, print, or electronic formats that may be used commercially and are not controlled by publishing entities [32]. Ultimately, 1626 records were included in the analysis.

Studies meeting the data processing criteria were imported into the user-friendly Biblioshiny interface via R Studio. The analysis evaluated the impact of sources by examining paper counts, h-indexes, total citation (TC) counts, and citations per publication. The h-index is a key metric for assessing the impact of an author or journal [33]. Citations play a critical role in measuring the influence of sources within a research field. Network metrics, such as modularity (Q) and network density, were also used to evaluate the frequency of relationships and clustering structures. A modularity value between 0.4 and 0.8 indicates a well-structured clustering network [34]. Finally, social network analysis was used to visualize the actors and relationships in exergaming research.

Ethics approval was not required for this study, as human participants were not involved.

The data for the 1626 included studies are presented in Multimedia Appendix 2 and are outlined in the data collection flow diagram (Figure 1).

Table 1 provides information on the key descriptive statistics regarding studies conducted in the exergaming field. The research in this area comprises 1626 documents sourced from 553 different outlets between 1997 and 2024. The annual growth rate of publications is 22.07%, with an average document age of 5.7 years. Notably, each study has received an impressive average citation rate of 21.95%. While there are 38 single-authored documents, 6556 authors have contributed to the field, predominantly through papers (n=1402) and reviews (n=224). The rate of international author collaboration is 26.88%, with an average of 5.57 authors per document. Additionally, 2917 keywords provided by the authors enhance the richness of the dataset. Finally, the 1626 documents have been cited 45,050 times in studies indexed on WoS.

Figure 2 shows that studies on exergaming began at very low levels in 1997, experienced significant growth starting in 2015, and peaked in 2021. Although there was a slight decline in 2022, scientific output continued in 2023 and 2024. It has been observed that the studies conducted in the field of exergaming and the average citation counts to these studies are not parallel, and there is a decrease in the average citation counts, unlike the number of publications.

An examination of the most relevant journals in the field of exergaming reveals that Games for Health Journal ranks first with 139 papers (Tables 2 and 3). This journal is followed by JMIR Serious Games with 63 papers. When evaluating the journals with the highest number of citations, Games for Health Journal once again tops the list with 1885 citations, followed by Medicine & Science in Sports & Exercise with 1241 citations. The local impact and impact factors of the top journals on exergaming are presented in Multimedia Appendix 3. According to the findings of Bradford’s law, Games for Health Journal occupies a larger share among the core sources compared to other journals and is positioned within the first core group of journals. It is followed by JMIR Serious Games and the International Journal of Environmental Research and Public Health. The findings for Bradford’s law are presented in Multimedia Appendix 4.

Figure 3 shows the publication performance of the most productive authors on exergaming over the years. Gao Zan (n=36) and Eling de Bruin (n=36) are the most productive authors in this field and continue to work on related studies. The analysis of author productivity based on Lotka’s law reveals that 79.74% (n=5226) of exergaming researchers have contributed with only 1 publication, 12.85% (n=842) have contributed with 2 publications, and 3.74% (n=245) with 3 publications. These findings do not fully align with Lotka’s law. The findings on Lotka’s law are presented in Multimedia Appendix 5.

Table 4 shows the most cited papers on exergaming, demonstrating the impact and importance of research in this area. The most cited paper (TC=386) by Biddiss and Irwin [35]. The second most cited paper (TC=345) by Ijaz et al [5].

Figure 4 presents the trending topics in exergaming research over time, showing how these topics have changed over the years. Topics such as “health,” “physical activity,” “exercise,” “virtual reality,” and “obesity” have typically been focal points in this field. In recent years, topics such as “medicine,” “information technology,” and “intention” have emerged.

Figure 5 illustrates the development and centrality degrees of exergaming research themes. Motor themes represent well-developed and highly relevant core topics in exergaming research. No specific terms were identified in this region.

Basic themes encompass topics with high centrality but low density. These themes are foundational to research and represent broadly discussed areas. Notable terms in this region include “randomized controlled trial,” “virtual reality,” “physical activity,” “active video,” and “pilot study.”

Niche themes refer to topics with low centrality but high density. These themes represent specific research topics and specialized subfields within the domain. Terms such as “autism spectrum,” “randomized crossover,” and “neurocognitive disorder” are prominent in this region.

Emerging or declining themes are characterized by low centrality and low density. These themes represent either emerging or diminishing areas of interest in exergaming research. Notable terms in this region include “Wii fit” and “physical education.”

Figure 6 shows the most productive countries, the most productive authors, the most productive institutions, and the connections between them in exergaming research. One of the largest nodes on the graph, Gao Zan, is seen to collaborate closely with Zeng Nan, indicating that they have conducted many studies together. In terms of collaborations between countries, the United States is at the center, showing a strong collaboration with China. Leading institutions include the Swiss Federal Institute of Technology (ETH Zurich) and the Karolinska Institute, which have been very active and show strong relationships between them.

Figure 7 presents a coword analysis based on the frequency of terms used in the titles, keywords, and abstracts of the 1626 included studies, highlighting the most prominent concepts in the field and the relationships between them. Using word cloud analysis in Bibliometrix, the main themes and concepts driving exergaming studies were identified, with PA (n=436), exercise (n=383), rehabilitation (n=218), and balance (n=213) ranking as the most prominent. The high frequency of these terms indicates their central role in exergaming research. Then coword analysis showed that the studies in the field are divided into 2 main clusters. Cluster 1 focuses on PA, exercise, performance, health, and health-related concepts, with these studies primarily targeting children and adolescents. Cluster 2, on the other hand, provides insights into studies focused predominantly on adults and older people, emphasizing rehabilitation, balance, and strength, highlighting the interconnectedness of these concepts.

This bibliometric analysis has revealed a significant increase in exergaming research since 2010, peaking during the 2020‐2021 period. Thematic analyses demonstrate that exergaming research is inherently interdisciplinary and spans areas such as health, rehabilitation, and behavior change. Collaboration patterns and trend analyses highlight the potential of exergaming to address broader health challenges, providing critical insights to guide future research directions.

The annual production of scientific publications on exergaming has shown significant growth since 1997, following the release of the Dance Dance Revolution. A prior bibliometric study focusing on VR, AR, and PA observed a similar growth trend, consistent with our findings [26,43]. A significant increase in publication volume has been observed since 2015, with scientific production peaking in 2020‐2021. This growth reflects advancements in VR and AR technologies as well as increased investments in health-focused gaming applications and the growing role of technology-assisted interventions in health care services [21,44]. Furthermore, this rise can also be attributed to the COVID-19 pandemic, which highlighted the need for home-based solutions to maintain PA, thereby amplifying the significance of exergaming research [45,46]. After 2002, the average citation rate dropped sharply and did not follow a trajectory parallel to the increase in the number of publications. A possible explanation for this is that the growth in the number of studies within the exergaming field led to citations being distributed across a broader range of research. As the field expanded, citations may have been spread among a larger body of work, diminishing the citation impact of earlier studies.

Games for Health Journal, International Journal of Environmental Research and Public Health, and JMIR Serious Games are leading journals for exergaming research in health and education. These leading journals are essential platforms that facilitate the dissemination of innovative studies, promote interdisciplinary collaboration, and shape the applications of exergaming in improving health and PA outcomes [12,47,48]. According to Bradford’s law, this finding indicates that most of the exergaming research is concentrated in a few core journals, while the remaining publications are distributed across a broader range of sources [49].

When examining the publication performance of the most prolific authors in the field of exergaming, a few notable names stand out, such as Gao Zan and Eling de Bruin. The continued production of relevant research by these authors, along with their numerous publications and high citation frequency, highlights their significant roles in the field of exergaming. According to Lotka’s law, about 60% of researchers are expected to contribute with a single publication, 15% with 2 publications, and 6.67% with 3 publications [50]. Considering Lotka’s law, which reveals the scientific productivity of authors in the field of exergaming, it can be concluded that researchers generally prefer to conduct a single study on this topic, and the number of authors specializing in the field remains limited. This shows that the literature in this field still has room for improvement.

The most cited on exergaming is Biddiss and Irwin’s paper [35], which received 386 citations in total. This paper reviews the potential of exergaming to promote PA among children and adolescents and possibly lays the groundwork for further studies by emphasizing the positive effects of exergaming on child health [35]. Another influential paper is the paper by Ijaz et al [5], which received 345 citations and had the highest annual citation rate of 57.5. This study investigates how VR exergaming increases participants’ motivation and enjoyment [5]. The high citation counts of these papers demonstrate their important contributions to the field of exergaming and their role as key reference points for other researchers.

In the analysis of trending topics, early studies primarily concentrated on terms such as “obesity,” “childhood,” and “video games,” whereas more specific topics like “virtual reality,” “physical activity,” and “rehabilitation” have gained prominence over time. This shift reflects the integration of advanced technologies and broader health applications into the field [51]. Furthermore, the rising frequency of terms such as “adolescents” and “adults” indicates a widening demographic focus, extending beyond children to include populations of different age groups. This evolution demonstrates the expanding scope of exergaming research, moving from a niche focus on childhood health to a broader application in preventive health care [52], rehabilitation [15], and lifestyle improvement. Finally, terms such as “intention” and “medicine” have more recently started to receive increasing attention, indicating that exergaming is being increasingly explored for behavior change and clinical interventions. Future studies could further enhance its impact by addressing less-explored topics and demographic groups.

Thematic analysis results reveal that fundamental themes, such as “virtual reality,” “randomized controlled trials,” and “physical activity,” constitute the main research topics in exergaming, particularly focusing on health and rehabilitation applications.

Niche themes, including “crossover trials” and “autism spectrum disorders,” delve into specialized research areas, allowing for in-depth studies on specific disease groups and research methods [53]. Themes such as “Wii Fit” and “physical education” efforts for school children represent topics that once gained popularity in exergaming research but have lost attention due to technological advancements and shifting research priorities. Future studies could explore niche themes in greater depth to discover new application areas and diversify basic themes to expand the potential of exergaming to broader audiences.

Authors such as Gao Zan and Zeng Nan are notable for their extensive collaborations, which may stem from their shared interest in studying the effects of exergaming on health and PA. Furthermore, 26.88% (n=437.07) of the 1626 studies in the field of exergaming had international author collaborations, indicating that more than 1 researcher worked together.

The United States stands out as the most productive country, maintaining strong collaborations with many other nations. China also plays a crucial role, collaborating closely with the United States. These collaborations have facilitated extensive research on exergaming, supported by substantial scientific research funds, robust research infrastructures, and leading technological advancements. Our findings are consistent with bibliometric studies focusing on technologies like VR and AR, commonly used in exergaming applications [26,27].

Leading institutions like the Swiss Federal Institute of Technology (ETH Zurich) and Karolinska Institute are at the forefront of this field. ETH Zurich, recognized for its expertise in technology and engineering, contributes considerably to the development and application of exergaming devices [54], while Karolinska Institute is prominent in medical research and clinical applications [55]. These institutional collaborations result in extensive and impactful studies investigating various applications of exergaming in fields such as health care and rehabilitation.

First, previous literature has shown that group-based exergames enhance motivation, promote sustained play, and improve self-efficacy. Family-friendly games like Ring Fit Adventure have the potential to increase PA while strengthening parent-child bonds. Future research should investigate the impact of these games on family dynamics and address critical issues such as “adherence,” “sustainability,” and “transfer effects.” Second, significant increases in energy expenditure as a result of exergaming might be of little importance if one compensates by increasing energy intake. Therefore, promoting exergaming as an obesity prevention tool also requires the quantification of energy intake to adequately assess overall energy balance. Without considering both sides of the equation, energy expenditure and intake, it is difficult to determine the true effectiveness of exergaming in managing or preventing obesity. Future studies should incorporate both metrics to provide a clearer understanding of exergaming’s potential health benefits. Third, exergaming has not been widely used in young children such as preschoolers; thus, it needs more research in this population. Fourth, with the advancement of technology and the introduction of new active video games, it is important to explore how these new games can promote PA and other health-related outcomes. Fifth, research could examine how exergaming can be integrated with technological advances and the potential benefits of this integration in health and education. Sixth, more research is needed on the social impacts and community-based applications of exergaming. Finally, further research on the economic issues and financial sustainability of exergaming is critical to assess its cost-effectiveness, economic benefits, and investment opportunities.

This study has various limitations. First, only the WoS database was used because the robust analytical capabilities of the Bibliometrix R package with WoS data enhanced the reliability of our results, and WoS’s “Keyword Plus” feature identified contextually significant keywords, thereby broadening the scope of the study. However, relying on a single database may exclude relevant sources from other databases, which is considered a limitation. Second, the R-based Bibliometrix tool was used for the analysis and visualization processes in this study, as it provided a sufficient platform aligned with the study’s scope without incurring additional software costs. However, the exclusion of additional features offered by alternative software is considered a limitation of this study. Third, the metrics and indicators used, such as citation counts, journal impact factors, and authors’ h-indexes, may not fully capture the quality of the research and potentially overestimate the impact of particular studies [56]. Finally, bibliometric methods provide an overview of a research field; however, this study does not offer an in-depth analysis of influential papers and authors. To gain a more comprehensive understanding of research impact and trends, bibliometric analyses should be complemented with other evaluation methods.

This study highlights the growing importance of exergaming research as a key indicator of the increasing integration of technology into the health domain. The COVID-19 pandemic has especially highlighted the value and relevance of home-based solutions in this field. The interdisciplinary nature of exergaming offers significant potential for the development of innovative approaches by bringing together technology and health applications. The thematic evolution of research demonstrates that exergaming has progressed beyond being merely a tool for children’s entertainment or PA promotion, expanding into broader health contexts such as rehabilitation, behavior modification, and applications for diverse age groups. This trend suggests that exergaming could play a more active role in public health policies in the future. Future research focusing on underexplored demographic groups, emerging technologies, and niche health applications is likely to further enhance the impact of exergaming.