To ensure a systematic and transparent approach in conducting this meta-review, we adhered to the PRISMA guidelines (Moher et al., 2009). The PRISMA protocol provides a structured framework for identifying, selecting, and critically appraising relevant studies, as well as for collecting and analyzing data from these studies. This protocol enhances the rigor and reproducibility of systematic reviews by providing a standardized reporting methodology. Following these guidelines, we systematically collected articles from the Scopus database on 23rd January 2024 (Page et al., 2021; Rama et al., 2023; Raman et al., 2022). Scopus was chosen due to its comprehensive coverage and high-quality indexing of peer-reviewed literature. The study period spans from 2014 to 2023, with the search terms “((artificial intelligence” OR “AI” OR “machine learning” OR “deep learning” OR “neural network*” OR “supervised learning” OR “unsupervised learning” OR “reinforcement learning” OR “natural language processing” OR “NLP” OR “computer vision” OR “cognitive computing”) AND (biblio* OR scientome* OR “literature review” OR “systematic review”). The document types included were articles, conference papers, reviews, and book chapters, leading to a final dataset of 3767 articles for analysis.

In our scientometric analysis, we used a comprehensive set of metrics to scrutinize the performance, collaboration dynamics, and impact of scholarly publications, as reported in previous reviews (Kokol et al., 2021; Pattnaik et al., 2021, 2023, 2024). The approach undertaken for the design of this research focuses on a range of indicators to fully explore reviews on the applications of AI. The metric total reviews (TRs) showcased our overall research. By distinguishing reviews that are solo-authored (SA) and coauthored (CA), we identify the collaboration patterns that are crucial for knowledge dissemination (Baker et al., 2020). While CA places more emphasis on teamwork, SA reflects individual contributions. The level of collaboration evident in the former reviews is further investigated by analyzing the number of contributing authors (NCA), which captures the range of networks and academic involvement. Furthermore, the average number of authors per coauthored article (AACA), collaboration index (CI), and collaboration coefficient (CC) provide nuanced insights into the shifting intensity and patterns of collaboration over time (Donthu et al., 2021).

In addition to reviewing the number of articles, we analyzed citations to assess the impact of review articles. The number of cited reviews (NCR) indicates the number of review articles frequently referred to, while total citations (TCs) provide an overview of the overall impact. To standardize for variations in publication age, we calculate average citations per cited review (TC/CR), which offers an adjusted impact measure. Conversely, various indices, including the h-index, g-index, and i-index, are utilized to deepen our understanding of citation influence. The h-index focuses on highly cited reviews, representing the number of reviews with at least h citations. The g-index emphasizes productivity by indicating the number of top-cited reviews with at least g2 citations. Simultaneously, the i-indices (i-10, i-100, and i-200) reveal the number of reviews cited at least 10, 100, and 200 times, respectively. Additional metrics such as the number of active years (NAY) reveal the duration of review publications in AI applications. Combining this with productivity per active year (PAY) gives us a better sense of sustained scholarly output over time.

The All Science Journals Classification (ASJC) subject categories, a classification system used by Scopus for indexing source titles within a structured hierarchy spanning various disciplines and subdisciplines, serves as the framework for cross-disciplinary thematic analysis (Haddawy et al., 2017; Hassan et al., 2017). We employed VOSviewer, a software application crafted for constructing and visualizing bibliographic networks (van Eck & Waltman, 2010). The basis of our analysis lies in the co-occurrence of ASJC subject categories for each publication. Each node represents a distinct ASJC publication, with lines connecting nodes indicating the frequency of co-occurrence. The color of a node often denotes the cluster or group to which a publication belongs, and each color signifies a different thematic cluster (Goodell et al., 2021; R. Raman et al., 2024). This clustering is grounded in the similarity of co-occurrence patterns, implying frequent discussion together in the literature. The distance between nodes in the visualization is also significant; a shorter distance indicates a stronger or more frequent co-occurrence, suggesting closer relationships or a higher degree of topic relevance.

Although a number of topic modeling approaches have been utilized within the literature, studies that have developed an empirical analysis of various approaches, such as nonnegative matrix factorization (NMF), To2Vec, and latent Dirichlet allocation (LDA), have identified BERTopic as “being able to generate novel insights using its embedding approach” (Egger & Yu, 2022). At its core, BERTopic is a modeling technique that leverages the powerful contextual embeddings within BERT and the class-based term frequency-inverse document frequency (c-TF-IDF) algorithm to compare the importance of terms within a dense cluster and develop term representation (Sánchez‐Franco & Rey‐Moreno 2022). Postdata extraction, a thorough preprocessing step involving text-cleaning procedures, NLP techniques, and tokenization, enhanced the quality and uniformity of the dataset. The utilization of sentence embeddings generated using the “all-mpnet-base-v2” model from the Sentence Transformer and dimensionality reduction using uniform manifold approximation and projection (UMAP) further generated the dataset for meaningful topic extraction and visualization (McInnes et al., 2020). The BERTopic model was fitted to the preprocessed text content, extracting distinct topics and corresponding probabilities for each article within a topic. The generated topics were scrutinized for coherence, and the distribution of articles across topics was examined, providing insights into the degree of association between articles and identified topics. This comprehensive and advanced approach in our topic modeling analysis ensures the reliability and robustness of our study findings.

As shown in Table 1, our study thoroughly examined the 3767 reviews that were cited 63,577 times. Such statistics underscore the extensive scholarly engagement and influence within the specialized field of research. The high h-index of 109 and g-index of 176 suggest a substantial impact, emphasizing the significance and relevance of the former reviews.

Moving to the coauthorship insights in Panel B, our study unveils a collaborative landscape with 18,189 contributing authors, reflecting a robust network of researchers engaged in synthesizing state-of-the-art research on AI applications. A collaboration index of 3.83 indicates a considerable degree of teamwork, fostering a rich environment for knowledge exchange created and disseminated through reviews. Additionally, the data illustrate that the average number of authors per coauthored article is 5, emphasizing the collective effort in producing the reviewed content. This collaborative spirit likely contributes to the field's diversity and depth of perspectives. In Panel C, the paper categorizes the types of reviews on AI applications, revealing a predominant focus on systematic reviews and bibliometric analyses, with 2707 and 651 instances, respectively. This signifies a methodological inclination toward the comprehensive synthesis of literature. Moreover, including other review types, such as topic modeling and meta-analysis, showcases the methodological diversity in understanding the dynamics of AI applications. Overall, the inferential summary highlights a multidimensional exploration of the literature, encompassing collaboration patterns, impact metrics, and methodological approaches within the AI domain.

The findings in Table 1 are further extended in Fig. 2, which maps the evolution of the various forms of reviews between 2014 and 2023. The substantial increase in systematic reviews (SLRs) over the years, reaching 1061 in 2023, reinforces our previous finding of a sustained interest in comprehensive literature synthesis. Scientometric reviews also gained prominence, reaching 281, indicating a growing focus on quantitative analysis within the domain.

Fig. 2.

Temporal evolution of the types of reviews on AI applications.

(0.27MB).

Building on these insights, we delve more deeply into specific aspects of AI research in the subsequent subsections. We explore the fields of research analysis to identify key areas of focus and emerging trends. This will be followed by an examination of thematic clusters, providing a detailed discussion on the major themes and topics that have shaped the AI research landscape. Additionally, we analyze BERT-enabled topics to uncover nuanced patterns and insights derived from advanced natural language processing techniques. Together, these discussions aim to provide a holistic understanding of the current state and future directions of AI research.

The Scopus database further uses the Australian and New Zealand Standard Classification of Occupations (ANZSCO, 2013) to categorize publications into fields of research (FoRs). Fig. 3 categorizes the study articles under the field of research (FoR). Most notably, information and computing sciences dominate the landscape regarding total reviews and citations, underscoring their pivotal role in the synthesis of AI research. This trend is not surprising given the technical nature of AI. Therefore, biomedical and clinical sciences and health sciences have presented a significant volume of AI reviews, which indicates the growing importance of AI applications in these fields. The high citation counts in these areas suggest that the reviews generated are prolific and impactful, influencing further studies and developments. Although having fewer publications in comparison, other fields, such as engineering, commerce, management, tourism, services, and education, still have a notable presence, reflecting AI technologies’ interdisciplinary and wide-reaching impact. Fields such as built environment and design, biological sciences, psychology, mathematical sciences, and human society, while contributing less in number, reveal the diverse application of AI across a broad spectrum of research areas. This diversity in application areas highlights the versatility and broad applicability of AI technologies in various aspects of scientific and technological research.

Fig. 3.

Classification of AI reviews based on FoRs (ANZSRC 2020 code).

(0.3MB).

The FoRs based on the ANZSRC classification system reveal the distribution of AI across broad academic and research disciplines. In contrast, subject categories based on the ASJC system revealed more granular interconnections via four distinct clusters within AI research (Fig. 4).

Fig. 4.

Clustering of cross-disciplinary subjects of AI research.

(0.7MB).

The transformative impact on healthcare from the adoption of AI, incorporating ethical considerations. This theme includes the topics of intelligent diagnostics, wearable technology in rehabilitation, AI in cancer diagnosis, and AI in brain health analysis. The cluster of Intelligent Diagnostics reviews investigates the application of ML in diverse healthcare domains (Christodoulou et al., 2019; Fleuren et al., 2020). By examining clinical prediction models, sepsis detection, COVID-19 diagnosis, depression therapy outcomes, heart disease diagnosis, diabetic retinopathy detection, and blood glucose control in diabetes patients, this review highlights both the potential and challenges of utilizing ML. Despite varied applications, the consensus is that methodological improvements and standardized reporting are crucial for reliable and effective integration of ML in diagnostic and predictive healthcare models.

These reviews collectively highlight the significant role of wearable technology in rehabilitation (Budrionis et al., 2022; McInnes et al., 2020). They explored diverse applications, from estimating biomechanical time series using regression algorithms to aiding blind and visually impaired individuals through smartphone-based computer vision. ML-driven controllers on locomotion assistive devices, commercial wearable sensors for gait monitoring, and the validation of wearable sensors using ML for physical ergonomics are discussed. The combination of AI and extended reality has been explored for applications such as autonomous cars, robotics, medical training, and entertainment. Additionally, the reviews delve into the use of AI and wearable sensors for remote rehabilitation, physical ergonomics, and socially assistive robotics, emphasizing the potential for personalized, data-driven interventions and improved patient monitoring.

The subject of “AI in Cancer Diagnosis” collectively affirms the efficacy of AI in medical applications (Brinker et al., 2018; Liu et al., 2019). The diagnostic accuracy of AI is equivalent to that of healthcare professionals, particularly in medical imaging. AI has shown promise across diverse domains, from skin cancer classification to the integration of electronic health records. While acknowledging the potential, the reviews emphasize challenges, such as the need for standardized benchmarks, improved reporting, and addressing biases. These findings underscore the transformative role of AI in cancer diagnosis, urging further research and standardization for robust and reliable applications in healthcare.

The reviews constituting this theme cluster highlight the transformative potential of AI, particularly deep learning and ML, in advancing brain health analysis (Ebrahimighahnavieh et al., 2020; Roy et al., 2019). Covering diverse areas such as electroencephalogram (EEG) interpretation, Alzheimer's disease detection, sleep apnea diagnosis, and autism spectrum disorder research, these reviews highlight the progress made in leveraging AI for comprehensive insights. Despite these achievements, challenges such as reproducibility, dataset availability, and optimization complexities persist within the reviewed studies. The findings underscore the imperative for further research, emphasizing robust feature representation multimodal data integration and addressing challenges to fully harness AI's capabilities in improving diagnostics and understanding of brain-related disorders.

This theme includes topics that discuss AI perspectives on sustainability issues as well as environmental factors related to sustainable energy, agricultural practices, traffic safety, and the design and development of smart cities. Specifically, the topics of AI in energy and agriculture, as well as AI in traffic safety, are included in this theme. Systematic literature reviews offer a comprehensive overview of the current state, challenges, and opportunities in flood prediction, predictive maintenance, crop yield prediction, energy systems, plant species identification, civil structural health monitoring, geotechnical engineering, industrial maintenance, and prognostics of rolling element bearings (Carvalho et al., 2019; Mosavi et al., 2018). By highlighting the effectiveness of ML models and emphasizing hybrid approaches, these reviews contribute to advancing and optimizing processes, systems, and decision-making in various domains, fostering informed innovation and sustainable practices. AI plays a significant role in revolutionizing various aspects of traffic safety and transportation systems (Noaeen et al., 2022; Sirohi et al., 2020). Topics include the application of convolutional neural networks (CNNs) in intelligent transportation systems (ITS), the use of reinforcement learning (RL) for traffic signal control and autonomous vehicles, the impact of AI on autonomous vehicle safety, motion planning for mobile robots with a focus on deep reinforcement learning, and the application of ML in surface transportation systems. These reviews provide insights into the advancements, challenges, and future directions in leveraging AI to enhance safety, efficiency, and decision-making in traffic-related domains.

This theme encompasses the many advancements in AI and deep learning and emerging applications in molecular science. The topics within this theme include deep learning for emotion analysis, deep learning for recommendations, deep learning in molecular science, and advances in NLP systems. Researchers employ deep learning across diverse fields (Bouwmans et al., 2018; Canedo & Neves, 2019). In video processing, convolutional neural networks (CNNs) excel in background subtraction, outperforming traditional methods. Facial expression recognition faces challenges in uncontrolled settings, and methods such as face detection and deep learning have been explored. Deep learning transforms single-object visual tracking, while human activity recognition (HAR) faces challenges and opportunities in spatiotemporal feature extraction. CNNs enhance accuracy in crowd counting for surveillance. Face liveness detection reviews AI techniques to combat spoofing threats. The impact of deep and ML on facial expression has been investigated, and a systematic review revealed advancements, challenges, and future directions in object detection. A comprehensive review of emotion recognition emphasizes the role of CNNs, datasets, applications, and open challenges.

Reviews on recommender systems highlight the extensive use of ML and deep learning techniques (Murad et al., 2018; Portugal et al., 2018). Researchers face challenges in selecting appropriate algorithms, but there is a growing trend in applying these technologies to diverse domains such as e-commerce, online learning, and entertainment. The reviews emphasize the increasing application of reinforcement learning for personalization, the effectiveness of deep learning in recommendation systems, and the exploration of new research opportunities. As these technologies continue to evolve, addressing challenges such as information overload, scalability, and accuracy remains crucial for the future development of recommender systems.

In the realm of molecular science and de novo drug discovery, generative ML models facilitate the efficient exploration of novel molecules, addressing challenges such as library homogeneity and synthesizability. Studies highlight that deep learning is pivotal in single-particle cryo-electron microscopy, enhancing structure determination in macromolecular studies. The application of DL in drug discovery extends to molecular similarity searching, where it proves effective in identifying compounds with similar functionalities. Furthermore, the integration of mechanistic modeling and ML in systems biology represents a hybrid approach for better understanding biological processes at different levels. In protein science, AI applications, including ML, contribute to protein structure prediction, design, and evolution. There are promising trends in the development of deep learning-based methods for identifying molecular similarities and predicting protein functions. In drug discovery against Plasmodium falciparum malaria, ML aids in predicting, classifying, and clustering not only bioactive compounds but also biological data, highlighting their roles in genomics and proteomics.

This review highlights the versatility of NLP from clinical applications and systematic review enhancements to social determinants of health extraction, language classification, and surgical outcome assessment (Bannach-Brown et al., 2019; Kreimeyer et al., 2017). These studies underscore the transformative impact of NLP and ML. They revealed advancements in systematic review processes, healthcare decision-making, and surgical outcome research while indicating the potential for further exploration in areas such as Arabic text classification, cardiology, and efficient information extraction using AI techniques. Collectively, these contributions highlight the evolving landscape and promising future of NLP systems in diverse domains.

This theme includes the impact on supply chain optimization, education, and software development from AI, where the efficiency and innovative aspects are discussed. The topics covered are AI in software defect prediction, ML in supply chains and markets, and AI in education. These reviews indicate the growing significance of ML in software quality assurance, defect prediction, and reliability assessment (Li et al., 2020; Meiliana et al., 2017). These studies reveal the effectiveness of various ML techniques, including unsupervised learning, supervised learning, and soft computing, in predicting software defects, faults, bugs, and reliability issues. Despite this progress, challenges such as inconsistent reporting, insufficient detail, and the need for more business-focused research persist. The findings emphasize the importance of comprehensive reporting, continued research, and a practical understanding of business aspects to bridge the gap between academic advancements and industrial applications in software development.

The reviews on ML in supply chains and markets collectively present a comprehensive landscape of applications, challenges, and potentials (Goodell et al., 2021; Toorajipour et al., 2021). They identify prevalent and potential AI techniques in supply chain management and reveal emerging trends in finance, banking, stock market forecasting, and marketing. Insights into logistics, sustainable manufacturing, and ML product innovation are highlighted. This review offers a holistic understanding of the evolving role of ML in optimizing operations, enhancing decision-making, and fostering innovation across diverse sectors, guiding future research directions in these dynamic domains.

Systematic literature reviews on “AI in Education” collectively highlight the transformative impact of AI on the educational landscape (Tahiru, 2021; Xu & Ouyang, 2022). By analyzing opportunities, benefits, and challenges, these reviews delve into diverse aspects. By integrating AI technologies within STEM education to predict student performance using ML, studies have showncase the potential to enhance learning outcomes. The reviews contribute valuable insights by addressing issues such as ethical concerns and the need for standardized evaluation in student performance prediction. Overall, AI's role in education is dynamic, offering possibilities for improved teaching methods, adaptive learning, and efficient exam management systems.

This theme includes the exploration of the intersection of AI with blockchain and cybersecurity, focusing on the enhancement of data integrity, security, and privacy. The topics included are AI-driven blockchain, edge computing and cybersecurity. The integration of AI and blockchain emerged as a pivotal aspect of the Fourth Industrial Revolution, as noted in the former reviews constituting the cluster (Ekramifard et al., 2020; Kumar et al., 2023). This synergy, explored in various studies, transforms industries with potential applications in business, supply chains, healthcare, secure transactions, and finance. This research analyses trends, benefits, and intellectual structure; highlights key clusters such as supply chains, healthcare, secure transactions, finance, accounting, and challenges; and emphasizes the potential of decentralized AI, applications for edge computing, and ethical considerations. Bibliometric analyses across diverse sectors, including education, higher education institutions, and attendance systems, showcase the expanding landscape and implications of AI-driven blockchain technologies.

The reviews within this theme illustrate the critical role of ML in bolstering cybersecurity across diverse domains (Manzoor et al., 2019; Martins et al., 2020). This review covers topics such as adversarial ML in intrusion and malware detection, fake news detection, DL-based intrusion detection systems, botnet detection in software-defined networks, Android malware detection, defensive and offensive cybersecurity, NLP approaches to fake news, ML methods in predicting court decisions, and AI in crime prediction. The findings underscore the significance of adopting advanced ML techniques and shed light on potential challenges, providing valuable insights for researchers and practitioners aiming to fortify digital security measures. The cluster's systematic reviews collectively showcase the effectiveness and challenges of leveraging ML techniques to enhance cybersecurity across various domains.

This theme incorporates the critical elements of AI ethics and AI bias mitigation, particularly in healthcare and decision-making systems. The topics covered are Ethical Dimensions of AI in Healthcare and Mitigating Bias in Decision Systems. This review highlights the ethical dimensions of AI in healthcare through a series of systematic reviews (Loh et al., 2020; Milne-Ives et al., 2020). The reviews cover a spectrum of AI applications, from conversational agents supporting health-related activities to explainable AI (XAI) techniques addressing the black-box nature of AI models. Topics include the effectiveness of AI conversational agents, the application of XAI in healthcare, the role of chatbots in promoting physical activity and weight loss, and the integration of AI-based technologies in nursing. The overarching theme underscores the potential benefits of AI in healthcare while emphasizing the need for transparency, user trust, and ethical considerations in its implementation. The significant advancements in applying AI to healthcare decision-making, medical diagnosis, and other domains have raised concerns about the ethical dimensions, fairness and bias of AI systems (Ferrara 2023). The implementation of ethical guidelines and bias mitigation in the use of AI requires a strategic multifaceted approach.

The reviews collectively emphasize the pervasive issue of bias in AI systems, particularly about gender (Pagano et al., 2023; Sun et al., 2019). They delve into the challenges, consequences, and potential solutions for mitigating biases in various domains, such as natural language processing, ML models, decision-making systems, and AI algorithms. The literature reviews address biases at different levels—societal, technical, and individual—highlighting the need for diverse perspectives, transparency, and responsible AI practices. The strategic implementation of ethical guidelines and bias mitigation policies in AI systems requires a rigorous comprehensive approach. This begins with the establishment of clear ethical standards that outline the principles and practices necessary for responsible AI development and deployment and should cover crucial issues such as data privacy, consent, transparency, accountability, and fairness. Ensuring adherence to these standards through regular audits and compliance checks is vital (Dwivedi et al. 2021; Giovanola & Tiribelli 2023). Future research directions are suggested to enhance fairness, inclusivity, and ethical considerations in developing and deploying AI systems.

This theme covers the current landscape of AI research as well as its practical applications, emphasizing the integration of AI into urban environments and smart city infrastructure. The topics included are AI integration in smart cities and the AI research landscape. This theme underscores the diverse and impactful applications of AI across various sectors (Darko et al., 2020; Di Vaio et al., 2020). AI has emerged as a transformative force from its role in shaping sustainable business models, contributing to smart cities, and influencing human resource management to its applications in marketing, consumer research, and psychology. The reviews also highlight the need for multidisciplinary research, systematic exploration of AI implications, and continued discourse, emphasizing both the opportunities and challenges associated with integrating AI in different domains. Furthermore, the intersection of AI with Industry 4.0, as seen in the context of robotic process automation (RPA), presents a promising avenue for enhancing organizational processes and leveraging the potential of automation.

In pursuant to our findings, we highlight several significant areas where AI and generative AI applications hold potential for future research and practical implementation. These implications address current gaps and propose directions for comprehensive and equitable advancements across various domains.

First, there is a critical need to address intersectional bias in AI systems. Traditional approaches to bias mitigation have predominantly focused on single-axis biases such as gender or race. However, these methods fail to account for the complexities of intersectional bias, where multiple, overlapping sources of bias intersect. Future research should develop AI models that can identify and mitigate these intersectional biases, ensuring that AI systems are more equitable and fair. By incorporating multiple dimensions of identity and their interactions, such models could significantly reduce discriminatory outcomes and enhance the inclusivity of AI technologies.

In the realm of healthcare, the development of AI systems for holistic health monitoring presents a promising avenue. Future AI systems could transcend the current focus on specific diseases by integrating diverse data sources such as wearable technology, genetic information, alternative medicine practices, lifestyle factors, and electronic health records. This integrative approach would enable a comprehensive view of an individual's health, facilitating personalized and preventive healthcare strategies. Such holistic AI systems could revolutionize healthcare by providing tailored health insights and recommendations, ultimately improving patient outcomes and promoting overall well-being.

Additionally, the role of AI in mental health care is an emerging field with substantial potential. Despite the expanding applications of AI in healthcare, there remains a paucity of research on integrative platforms specifically designed for mental health. Future research should focus on developing AI systems that utilize data from various sources to offer personalized mental health services. These systems could include functionalities for early detection, intervention, and continuous monitoring of mental health conditions such as stress, anxiety, and depression. AI-driven innovations in mental health diagnostics, treatment, and monitoring could transform public health by providing accessible and effective mental health care solutions.

Environmental resilience and sustainability represent another crucial area where AI-driven innovations could have a significant impact. Future research should prioritize the development of comprehensive AI applications for environmental monitoring and management. For instance, AI could enhance predictive analytics for biodiversity monitoring by leveraging satellite imagery and sensor networks to proactively manage ecosystems. Improved climate models powered by AI could offer localized climate change predictions, guiding adaptive strategies for vulnerable communities and ecosystems. Real-time AI systems for detecting environmental hazards such as forest fires and oil spills could be integrated with emergency response mechanisms to mitigate their impacts more effectively. Additionally, AI and blockchain technologies could be utilized for transparent and sustainable natural resource management, engaging communities through AI-enhanced citizen science platforms for environmental monitoring. Moreover, employing deep learning techniques to map and autonomously address plastic pollution could significantly contribute to global conservation efforts.

The generalisability of the transformative potential of AI across geographic regions, cultures, and socioeconomic contexts depends on several factors: technological readiness, cultural adaptability, economic viability, regulatory environments and government policy. In developed nations with robust technology infrastructure, AI can drive innovation and deliver change. Within developing economies, regions are likely to be limited by access to technology and may face barriers to adoption, impacting the effectiveness of AI. AI applications in marketing, consumer research, and psychology must consider local cultural contexts. AI models trained on culturally specific data may not perform well in different cross-cultural contexts. Developed economies can invest heavily in AI technologies, facilitating integration into various sectors. Lower-income regions may struggle to adopt and scale AI solutions due to economic constraints, affecting areas such as human resource management and industry automation (Dwivedi et al. 2021). Supportive regulatory frameworks can accelerate AI adoption, while stringent or unclear regulations may slow it. Ethical considerations around privacy and data protection also influence AI deployment, which varies globally and affects fields such as consumer research. The integration of AI with Industry 4.0 technologies, such as robotic process automation (RPA), varies across regions. Compared with developing regions, advanced economies with established industrial bases are more likely to benefit from these technologies.

Thus, the implications for practice derived from our study emphasize the transformative potential of AI and generative AI across various domains. Addressing intersectional bias, advancing holistic health monitoring, integrating AI in mental health care, and developing AI-driven solutions for environmental resilience and sustainability are pivotal areas for future research. AI solutions have a cultural and socioeconomic context requiring innovative and pragmatic solutions. These efforts will not only advance the state of AI technology but also ensure that its applications are equitable, comprehensive, and beneficial to society at large.

The comprehensive integration of scientometric analysis with BERTopic modeling in this study offers a unique dual approach for examining the artificial intelligence (AI) research landscape. This methodology combines quantitative insights from scientometric analysis, which delineates the structural and dynamic dimensions of AI research, with the qualitative depth provided by BERTopic modeling, pinpointing nuanced thematic trends and identifying specific research gaps. This combined approach yields a thorough comprehension of the current state and potential trajectories of AI research, thereby contributing significantly to theoretical frameworks within the field.

This investigation unveils the extensive reach of AI across various sectors, including healthcare, education, energy, and agriculture, synthesizing pivotal insights to outline a narrative of technological innovation's evolving frontiers. Notably, the integration of AI within healthcare and life sciences is a testament to its ability to refine diagnostics and treatment protocols, as evidenced through thematic clusters and the examination of highly cited literature. Furthermore, the use of the Fields of Research (FoR) classification system unveils a research domain predominantly situated within information and computing sciences, highlighting the foundational role of this field in AI development. The impactful penetration of AI into practical domains is evidenced through its translational impact across biomedical, clinical, health sciences, and intersecting areas such as commerce and management. Lesser represented yet critical fields such as education, psychology, and human society signify the burgeoning recognition of AI's capacity to influence a wider array of sociocultural facets. The generalizability of AI depends on a context-specific approach that considers cultural factors, economic conditions, and regulatory environments. Tailored multidisciplinary research ensures the effective, equitable, and culturally sensitive integration of AI, fostering global innovation and sustainable development.

The introduction of generative AI into this discourse has amplified the scope of AI applications, especially in generating novel content, designing advanced models, and simulating complex systems across these domains. Generative AI, with its ability to create new data, images, texts, and simulations reflecting real-world scenarios, promises to greatly increase research depth (Dwivedi et al., 2023; Ooi et al., 2023). This is especially true in areas where there is a lack of data or a strong need for innovative solutions. This technology's potential to revolutionize sectors such as healthcare through the generation of synthetic patient data for research and education by producing personalized learning materials is particularly noteworthy. However, the application of generative AI also necessitates rigorous theoretical considerations regarding ethics (Raman et al., 2023; R. Raman et al., 2024), bias mitigation, and the integrity of generated content, thus opening new avenues for theoretical exploration and methodological innovation.

Moving forward, reviews on AI applications could benefit from addressing several potential gaps identified in the data. First, there is an opportunity to investigate the adoption and impact of emerging methodologies, such as topic modeling and meta-analysis, given the rising trend in systematic and quantitative reviews. Additionally, a more detailed temporal analysis could uncover trends and shifts in research foci over time, helping to identify temporal gaps and guide future investigations. Moreover, the high level of collaboration among authors suggests the potential for exploring the interdisciplinary nature of collaboration and understanding how different disciplines contribute to various review types. Investigating the quality assessment of reviews, including methodological rigor, transparency, and impact in different categories, can inform improvements and standardization in research practices.

The evolving landscape of AI, coupled with the exploratory potential of generative AI, calls for a heightened focus on interdisciplinary collaboration and the sharing of knowledge and innovations to address global challenges. Innovations in infrastructure development underscore the potential of predictive analytics to inform robust, ethical frameworks that address technological reliance and data biases. In the context of education, personalized learning experiences through generative AI promise enhanced engagement and accessibility. This necessitates further research on quality control to ensure that these AI-driven educational tools meet high standards. Similarly, energy optimization has emerged as a critical area where AI's predictive maintenance capabilities can lead to sustainable and efficient energy policies and practices.

Furthermore, the urgent need for climate action can be addressed through AI's capabilities in environmental modeling and impact analysis. As AI continues to redefine the boundaries of technology and its applications, the imperative for international cooperation and the exchange of ideas becomes increasingly critical. This global collaboration will be essential in ensuring that AI's influence transcends geographical and disciplinary limits, fostering a future where AI contributes positively to society.

Finally, it is important to acknowledge the limitations of this work. Our reliance on reviews collected from Scopus means that the scope may be constrained by the publications available in this database. Consequently, the findings and insights presented may reflect the coverage and emphasis present in Scopus, potentially limiting the comprehensiveness and diversity of perspectives in the broader landscape of AI research.