ABSTRACT
This bibliometric analysis investigates technological solutions for fall prevention in older adults by examining 105 articles from 1996-2024 in the Web of Science database. Utilizing advanced techniques, it maps publication trends, contributors, research hotspots, themes, influential works and emerging topics. Findings reveal increasing research output after 2012, led by the U.S., U.K. and Australia. Prominent hotspots include virtual reality, digital health tools and multidisciplinary interventions. Highly cited works highlight virtual reality, wearable devices and fall prevention education. Emerging areas focus on virtual reality, wearable technologies, mHealth solutions and gait biomarkers. These findings inform geriatric fall prevention research and clinical translation.
INTRODUCTION
Falls among older adults represent a significant public health concern, with far-reaching implications for individual well-being and healthcare systems worldwide. According to the World Health Organization (WHO), falls are the second leading cause of unintentional injury-related deaths globally, with an estimated 646,000 fatal falls occurring each year (United Nations, 2015). Additionally, falls are the leading cause of injury-related deaths and non-fatal injuries among individuals aged 65 and older. These alarming statistics underscore the urgent need for effective fall prevention strategies in rehabilitation settings.
As the global population ages, the prevalence of falls among older adults continues to rise, posing substantial challenges for healthcare providers, caregivers and society at large. Recent estimates suggest that approximately one-third of community-dwelling adults aged 65 and older experience at least one falls each year (Shankaret al., 2017). Beyond the immediate physical injuries they cause, falls often may result in long-term functional decline, loss of independence and increased healthcare utilization. Rehabilitation plays a pivotal role in mitigating these consequences by restoring mobility, strength and balance in older adults recovering from falls.
Despite the growing recognition of the importance of fall prevention in rehabilitation, there remains a notable gap in the literature regarding the role of technology-based interventions in this context. While traditional rehabilitation approaches, such as exercise programs, environmental modifications and assistive devices have shown efficacy in reducing fall risk technological innovations offer promising opportunities to enhance outcomes and optimize the delivery of care for older adults at risk of falls (Moratet al., 2023). These innovations encompass a wide range of solutions, including wearable sensors, Virtual Reality (VR) training, robotic assistance and smart home technologies (Souzaet al., 2024). In light of this gap, our study seeks to address the following key research questions through a comprehensive bibliometric analysis of the existing literature on technological solutions for fall prevention in older adults:
RQ1: What are the publication trends and yearly distribution of research output related to technological solutions for fall prevention in older adults between 1996 and 2024?
RQ2: Which countries and journals have been the key contributors to this research?
RQ3: What are the research hotspots and highly explored areas within this domain?
RQ4: What are the major thematic areas and sub-domains covered in this research?
RQ5: Which articles have had a significant impact, in terms of citations and influence, on this field?
RQ6: What are the emerging research topics and future directions in the development of technological solutions for fall prevention in older adults?
By leveraging bibliometric techniques, we aim to uncover publication trends, key contributors, research hotspots, thematic areas, impactful articles and emerging topics in this domain. Our objective is to comprehensively examine the current state of technology-based interventions for fall prevention in rehabilitation for older adults, synthesize existing knowledge, identify trends, evaluate efficacy and highlight significant contributions. Ultimately, we aim to provide valuable insights to inform future research directions and enhance clinical practice in fall prevention and rehabilitation for older adults.
LITERATURE REVIEW
Numerous interventions and strategies have been proposed and studied to avoid falls in older individuals. Technological advances have led to promising fall prevention methods in rehabilitation settings.
Current Landscape of Technology-Based Interventions
In recent years, researchers have explored a wide range of technology-based interventions for fall prevention in older adults. These interventions leverage various technological advancements, including wearable devices, sensor-based systems, VR environments and smart home technologies. Wearable devices, such as accelerometers and gyroscopes, have been utilized to monitor gait patterns, detect falls and provide real-time feedback to users (Rodgerset al., 2019). Sensor-based systems, incorporating cameras, pressure sensors and radar technology, have been employed for fall risk assessment and environmental monitoring (Wanget al., 2024). VR environments have been used for balance training, simulating challenging scenarios and improving postural control (Rezaeiet al., 2023). Additionally, smart home technologies, such as home automation systems and assistive robots, have been explored to create safer living environments and provide support for older adults (Sawiket al., 2023).
Efficacy of Technology-Based Interventions
While the number of studies investigating technology-based interventions for fall prevention has increased, it is crucial to evaluate their effectiveness in reducing fall risk and improving functional outcomes in older adults. A meta-analysis by Nishchyket al., (2021) found that technology-assisted interventions, such as exergames and virtual reality training, significantly improved balance and gait parameters in older adults, potentially reducing fall risk. However, the authors noted considerable heterogeneity in study designs and outcome measures, highlighting the need for more standardized research protocols. Several randomized controlled trials have reported promising results for wearable sensor-based interventions in reducing fall rates and improving functional mobility (Yuet al., 2024), while others have questioned the long-term benefits and user acceptance of such technologies (Visvanathanet al., 2022).
METHODS
This study employed a comprehensive bibliometric analysis approach to examine the research landscape and trends related to technological solutions for fall prevention in older adults.
Bibliometric analysis
This study employed two main analysis techniques: performance analysis and science mapping (Azizan and Fadzil, 2024). The performance analysis provided a descriptive examination of various research performance indicators and contributions, including overall publication count, annual publication trends, leading countries in publishing activities, most prolific research areas, most productive academic journals and most highly cited academic papers. Science mapping utilized VOSviewer software to visually map the relationships and strengths between research items (Azizanet al., 2024). Specific methods included: bibliographic coupling analysis to identify related publications and content analysis of article titles, abstracts, author keywords and Keywords Plus using Biblioshiny and VOSviewer tools (Aria and Cuccurullo, 2017; Azizan, 2023).
Procedural analysis
The data collection process for this study was conducted on April 8th, 2024, using the Web of Science (WoS) database. The search query employed was as follows:
“twitter” OR “facebook” OR “whatsapp” OR “social media” OR “e-mail” OR “telehealth” OR “mobile app*” OR “cellphone” OR “online program” OR “computer-assisted” OR “computer tailored” OR “mobile phone” OR “technology-based” OR “digital” OR “e-health” OR “mobile health” OR “mhealth” OR “web-based” OR “telemedicine” OR “virtual reality” OR “electronic intervention*” OR “smartphone” OR “text messag*” OR “wearable device*” OR “gamification” OR “internet*based” OR “digital media” OR “digital program” OR “online system” (Title) and “older*” or “elder*” or “senior*” or “geriatric” or “age*” (Title) and “fall*” (Title). The primary data gathered from this search is summarized in Table 1 Figure 1 depicts the study flowchart employed in this investigation.

Figure 1.
The study flowchart.
Description | Results |
---|---|
Timespan | 1996:2024 |
Sources (Journals, Books, etc.,) | 73 |
Documents | 108 |
Annual Growth Rate % | 4 |
Document Average Age | 5.24 |
Average citations per doc | 16.02 |
References | 2452 |
Document Contents | |
Keywords Plus (ID) | 203 |
Author’s Keywords (DE) | 253 |
Authors | |
Authors | 450 |
Authors of single-authored docs | 10 |
Authors Collaboration | |
Single-authored docs | 10 |
Co-Authors per Doc | 5.46 |
International co-authorships % | 28.7 |
Document Types | |
article | 63 |
article; early access | 1 |
correction | 4 |
editorial material | 1 |
letter | 1 |
meeting abstract | 16 |
proceedings paper | 16 |
RESULTS
Annual Scientific Production
Figure 2 illustrates the annual scientific production related to technological solutions for fall prevention in older adults. From 1996 to 2004, there were no publications on technological solutions for fall prevention in older adults. In 2005, one publication marked the start of research interest in this area. Publication numbers fluctuated in subsequent years until 2013 when there were three publications. From 2014 to 2024, research output increased significantly, especially after 2016, peaking at 17 articles in 2023. However, only one article was published in 2024, suggesting potential fluctuation or slowdown. Overall, data indicates an increasing trend in research interest and output in this domain over the analyzed period, with notable fluctuations and peaks in recent years.

Figure 2.
The Annual Scientific Production.
Key Contributors in Terms of Country and Journals Ranked
Figure 3(a) illustrates the distribution of research output among countries contributing to the field of technological solutions for fall prevention in older adults. The United States led contributions to research on technological fall prevention solutions for older adults with 15 published articles, reflecting significant investment in this area. Sweden (8 articles) and Australia (7 articles) followed, with a notable proportion involving multiple authors, suggesting collaborative efforts within these countries. China, the United Kingdom and Korea each contributed 6 articles, highlighting their roles in advancing knowledge and innovation.

Figure 3a.
The Annual Scientific Production.
Regarding journals, BMC Geriatrics, Gerontology, JMIR mHealth and uHealth and the Journal of the American Geriatrics Society were key contributors, each publishing 5 articles. These outlets facilitated the dissemination of findings and scholarly discourse on fall prevention interventions for older adults. Innovation in Aging (4 articles), Age and Ageing (3) and Clinical Interventions in Aging (3) also significantly advanced understanding through publishing impactful research in this domain. Figure 3(b) presents the distribution of research output among journals publishing articles on technological solutions for fall prevention in older adults.

Figure 3b.
The Annual Scientific Production.
Research hotspots
The co-occurrence analysis of author keywords provided insights into research hotspots related to technological fall prevention solutions for older adults, as depicted in Figure 4, three distinct clusters.

Figure 4.
Co-occurrences of Author Keywords by Network Visualization. [minimum number of occurrences of a keyword: 5; Out of 253 keywords, 18 meet the threshold].?
Cluster 1 (red) highlighted hotspots like digital health applications, self-management strategies and exercise for fall prevention. Keywords such as “accidental falls,” “eHealth,” “fall prevention,” and “self-management” indicated a focus on understanding and mitigating fall risks through technological interventions.
Cluster 2 (green) emphasized balance training, virtual reality interventions and preventive measures targeting fall risk factors. Keywords like “balance,” “fall risk,” and “virtual reality” suggested research on improving balance and reducing falls through immersive technologies.
Cluster 3 (blue) focused on technology-based fall detection and monitoring solutions. “Fall detection,” “falls,” and “technology” signified developing tools for detecting falls and exploring technology’s role in prevention strategies.
The occurrence data across these clusters underscored the frequency and relevance of the identified keywords in research publications within this domain.
Thematic areas
Figure 5 presents the term co-occurrences map using full counting with title and abstract fields, where the minimum number of occurrences of a keyword is set at 20. Out of 253 keywords, 34 meet the threshold and are included in the analysis. These keywords represent recurring themes and concepts found in the titles and abstracts of research articles related to fall prevention interventions for older adults.

Figure 5.
Term Co-occurrences Map using Full counting with title and abstract fields.[minimum number of occurrences of a keyword:20; Out of 253 keywords,34 meet the threshold].
Impactful articles
Table 2 lists the top 10 fall prevention strategies for older individuals, along with their authors, article titles, source titles and citation counts from the Web of Science Core Collection and all databases. These papers have advanced fall risk reduction and older adult safety and well-being techniques. These papers’ citation counts indicate their scientific impact.
Ranks | Article Title (Authors) | Times Cited, WoS Core | Times Cited, All Databases |
---|---|---|---|
1 | Addition of a non-immersive virtual reality component to treadmill training to reduce fall risk in older adults (V-TIME): a randomised controlled trial (Mirelmanet al., 2016). | 267 | 286 |
2 | A High Reliability Wearable Device for Elderly Fall Detection (Pierleoni et al., 2015). | 176 | 191 |
3 | Effects of balance training using a virtual-reality system in older fallers (Duque et al., 2013). | 135 | 150 |
4 | V-TIME: a treadmill training program augmented by virtual reality to decrease fall risk in older adults: study design of a randomized controlled trial (Mirelmanet al., 2013). | 105 | 113 |
5 | A Randomized Trial Comparing Digital Video Disc with Written Delivery of Falls Prevention Education for Older Patients in Hospital (Hillet al., 2009). | 86 | 96 |
6 | Smartphone technology can measure postural stability and discriminate fall risk in older adults. (Hsiehet al., 2019). | 61 | 61 |
7 | Balance training using virtual reality improves balance and physical performance in older adults at high risk of falls (Phuet al., 2019). | 51 | 57 |
8 | E-health Standing Tall balance exercise for fall prevention in older people: results of a two year randomised controlled trial (Delbaereet al., 2021). | 49 | 49 |
9 | The effectiveness of virtual reality training in reducing the risk of falls among elderly people (Kamińskaet al., 2018). | 47 | 52 |
10 | Comparison of the effects of virtual reality-based balance exercises and conventional exercises on balance and fall risk in older adults living in nursing homes in Turkey (Yeşilyapraket al., 2016). | 42 | 47 |
Emerging Research Topics and Future Research
Based on the database provided of 108 papers related to technological solutions for fall prevention in older adults, the emerging research topics can be summarized in Table 3.
Emerging Research Topics | Frequency (N) | Percentage (%) |
---|---|---|
Virtual Reality (VR) and Augmented Reality (AR) for Fall Prevention. | 25 | 23 |
Smartphone-based Fall Detection and Risk Assessment. | 20 | 19 |
Wearable Devices and Sensors for Fall Monitoring and Prevention. | 17 | 16 |
mHealth and Telehealth Interventions for Fall Prevention. | 13 | 12 |
Digital Feedback and Exergames for Balance and Mobility Training. | 12 | 11 |
Home-based and Multidisciplinary Fall Prevention Programs. | 11 | 10 |
Digital Biomarkers and Gait Analysis for Fall Risk Prediction. | 10 | 9 |
DISCUSSION
This bibliometric analysis provides a comprehensive overview of the rapidly evolving research landscape focused on technological solutions for fall prevention among older adults. The findings underscore the multidisciplinary nature of this field, driven by the integration of innovative technologies, data-driven approaches and collaborative efforts across diverse disciplines.
The notable increase in research output after 2012 aligns with the global recognition of the aging population and the urgent need for effective fall prevention strategies (Montero-Odassoet al., 2021). The leading contributions from the United States, the United Kingdom and Australia reflect their prioritization of initiatives aimed at reducing the substantial healthcare burden associated with falls (Meyeret al., 2022). The prominence of journals like BMC Geriatrics, Gerontology, JMIR mHealth and uHealth facilitates knowledge exchange and interdisciplinary collaboration, essential for addressing the multifaceted challenges of fall prevention (Muusseet al., 2023).
Three distinct research hotspots emerged: United Nation, (2015) virtual reality and balance training interventions, Shankaret al., (2017) digital tools for fall risk assessment and prevention and Moratet al., (2023) multidisciplinary approaches for overall well-being. Influential studies, such as those by Mirelmanet al., (2016) and Pierleoniet al., (2015), have advanced our understanding of virtual reality and wearable device interventions, shaping future research trajectories Duqueet al., (2013) and Mirelmanet al., (2013). The analysis of emerging topics revealed a strong focus on virtual reality, augmented reality and smartphone-based solutions for balance training, fall detection and risk assessment (Hillet al., 2009). Additionally, the integration of wearable devices, digital biomarkers and gait analysis highlighted the growing interest in personalized and data-driven approaches (Hsiehet al., 2019).
Furthermore, the emphasis on mHealth, telehealth, digital feedback, exergames and home-based interventions underscores the recognition of accessibility, engagement and holistic approaches as critical factors in fall prevention (Phuet al., 2019), (Kamińskaet al., 2018). These findings have implications for future research, clinical practice and policy decisions. The identification of research hotspots and emerging trends can guide the prioritization of efforts and resource allocation, while the recognition of influential studies can inform the development of novel methodologies and interventions (Yeşilyapraket al., 2016). By leveraging the insights from this analysis, healthcare professionals and policymakers can make informed decisions about integrating technology-based interventions into fall prevention programs and rehabilitation settings, potentially leading to improved patient outcomes and more efficient resource allocation. While the study was limited to articles indexed in the Web of Science database, this bibliometric analysis provides a comprehensive and data-driven perspective on the research landscape, offering a valuable resource for researchers, healthcare professionals and policymakers to navigate the complexities of this domain and identify promising avenues for future research and clinical practice.
CONCLUSION
This comprehensive bibliometric analysis sheds light on the rapidly evolving landscape of technological solutions for fall prevention in older adults. The findings highlight the multidisciplinary nature of this field and the potential for integrating cutting-edge technologies, data-driven approaches and collaborative efforts to enhance the effectiveness, accessibility and personalization of fall prevention strategies. Future research should focus on further exploring the promising avenues identified in this study, such as virtual reality, augmented reality, wearable devices, digital biomarkers and gait analysis, while also considering the importance of user acceptance, adherence and cost-effectiveness. Additionally, fostering multidisciplinary collaborations among researchers, healthcare professionals and policymakers is crucial to translate these findings into evidence-based clinical practice and inform the development of comprehensive fall prevention programs tailored to the diverse needs of older adults. By embracing technological innovations and adopting a holistic approach, the healthcare community can work towards improving the quality of life, independence and overall well-being of the aging population.
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Cite this article:
Azizan A, Sirada A, Samosir NR. Falling Forward: Tracing Technological Solutions for Fall Prevention in Older Adults (1996-2024). Info Res Com. 2024;1(2):74-82.