Hostname: page-component-586b7cd67f-tf8b9 Total loading time: 0 Render date: 2024-11-24T01:07:30.689Z Has data issue: false hasContentIssue false

Un-Meetings as tools for translational idea generation: A semantic content analysis of an Opioid Crisis Un-Meeting

Published online by Cambridge University Press:  09 November 2022

Reza Yousefi Nooraie*
Affiliation:
Department of Public Health Sciences, University of Rochester Medical Center, Rochester, NY, USA Center for Leading Innovation and Collaboration (CLIC), Clinical and Translational Science Program National Coordinating Center, University of Rochester Medical Center, Rochester, NY, USA
Robert J. White
Affiliation:
Center for Leading Innovation and Collaboration (CLIC), Clinical and Translational Science Program National Coordinating Center, University of Rochester Medical Center, Rochester, NY, USA
Scott Steele
Affiliation:
Department of Public Health Sciences, University of Rochester Medical Center, Rochester, NY, USA Center for Leading Innovation and Collaboration (CLIC), Clinical and Translational Science Program National Coordinating Center, University of Rochester Medical Center, Rochester, NY, USA
Erika F. Augustine
Affiliation:
Kennedy Krieger Institute, Baltimore, MD, USA
Deborah J. Ossip
Affiliation:
Department of Public Health Sciences, University of Rochester Medical Center, Rochester, NY, USA Center for Leading Innovation and Collaboration (CLIC), Clinical and Translational Science Program National Coordinating Center, University of Rochester Medical Center, Rochester, NY, USA
Martin S. Zand
Affiliation:
Department of Public Health Sciences, University of Rochester Medical Center, Rochester, NY, USA Center for Leading Innovation and Collaboration (CLIC), Clinical and Translational Science Program National Coordinating Center, University of Rochester Medical Center, Rochester, NY, USA Division of Nephrology, Department of Medicine, University of Rochester Medical Center, Rochester, NY, USA
*
Address for correspondence: R. Yousefi Nooraie, PhD, MD, Department of Public Health Science, University of Rochester, 265 Crittenden Blvd, Rochester, NY 14642, USA. Email: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Background:

Team development and idea generation are key intertwined steps in translational science that need a framework to accommodate unstructured, participatory interactions. To this end, we introduced Un-Meetings to the Clinical and Translational Science Awards (CTSA) Program, innovative events that facilitate cross-disciplinary idea generation and informal discussions between translational scientists, policy makers, community members, advocates, and public health professionals. Here we describe a mixed methods study to characterize the conceptual diversity and clusterization of ideas generated through an Opioid Crisis Un-Meeting.

Methods:

An Un-Meeting targeting translation science approaches to the opioid crisis were hosted at the University of Rochester Center for Leading Innovation and Collaboration (CLIC). We used semantic analysis and conceptual mapping of keywords to analyze how attendee-led idea generation sessions identified topics for breakout discussions.

Results:

One hundred and two individuals from 40 institutions proposed 150 unique ideas that were grouped into 23 breakout sessions. Network analysis showed that diverse pools of experts were bridged by topics addressing the complexities of the opioid crisis. Two clusters emerged: (1) systems, contexts, and community engagement, and (2) technologies, innovations, and treatment advancements.

Conclusions:

The cross-disciplinary nature of topic areas that bridge across thematic communities provide opportunities for CTSA programs to engage and support development of diverse translational teams. Potential opportunities for team building include technological advancements of opioid prevention, treatment, surveillance, systems approaches, and studies focusing on special populations and health disparities. The analysis method here may be useful in identifying naturally emerging teams of experts and community gaps when addressing large problems.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2022. Published by Cambridge University Press on behalf of The Association for Clinical and Translational Science

Introduction

Translational research involves bridging between different stages of the translational spectrum (e.g. laboratory, clinic, community) to find, test, and implement solutions that address complex biomedical and health problems [Reference Austin1]. Innovative ideas are created by teams of multi-disciplinary researchers and stakeholders. There are only a few reports on the impact of scientific retreats [Reference Ranwala, Alberg, Brady, Obeid, Davis and Halushka2,Reference Ranwala, Alberg, Brady, Obeid, Davis and Halushka3], conferences, and other participatory activities [Reference Arevian, Bell and Kretzman4] designed to motivate and facilitate idea generation and team building. Despite conceptual advances in understanding determinants of successful translational collaboration [Reference Gilliland, White and Gee5], little has been done to intentionally create environments that facilitate development of translational ideas and creation of translational research teams, especially at the level of large research consortia.

The Un-conference is an innovative meeting that shifts from traditional didactic lectures and presentations to a more participatory format that engages attendees from multiple disciplines to co-develop ideas and form collaboration networks [Reference Greenhill and Wiebrands6]. Un-conferences facilitate cross-disciplinary idea generation, informal conversation, and formation of professional collaboration networks. Un-conferences differ from frameworks designed to arrive at group consensus among experts (e.g. Delphi Method [Reference Vernon7]), which are designed to arrive at a consensus about an issue, rather than form teams and collaborations to address an issue using novel approaches. The agendas for sessions and new collaborations emerge from unstructured, organic, interest-based, group discussions. This format has been highly successful within the technology sector [Reference Battelle8,Reference Ballinger9].

The University of Rochester Center for Leading Innovation and Collaboration (CLIC), the National coordinating center for the National Institutes of Health Clinical and Translational Science Awards (CTSA) Program, adapted the methodology of Un-conferences [Reference Greenhill and Wiebrands6] to develop Un-Meetings, which are designed to intentionally foster translational innovation, idea generation, and spark team collaborations, as previously been reported in detail [Reference Jones, Lane, Shah, Carter, Lackey and Kolb10]. Several Un-Meetings have been hosted by CLIC during last few years, which provided opportunities for idea generation and free conversations by multi-disciplinary panels of investigators and research users, on different translational topics, including healthcare workforce development [Reference Jones, Lane, Shah, Carter, Lackey and Kolb10], rural health and equity, artificial intelligence, life course research, academic-community hospital partnership development, and climate change [Reference Solway, Kenyon and Berglund11]. Here we use the Un-Meeting framework [Reference Sugarwala, White, Steele, Ossip and Zand12], a vehicle to support cross-disciplinary team formation and innovation, and a semantic network analysis method for studying these processes in the clinical and translational science community.

The unstructured format of the Un-Meeting allows researchers to form social clusters that may lead to early transdisciplinary team formation. In addition to formal organizational affiliations (e.g. institutions and departments), invisible communities of research and collaboration can form based on shared interests, values, and scientific worldviews that cross traditional organizational structures. These “invisible colleges” [Reference Zuccala13], “invisible communities” [Reference Tuire and Erno14], or “epistemic communities” [Reference Amin and Cohendet15] are difficult to identify and often are only nascent or yet-to-be-formed communities waiting for a catalytic event. However, they are critical in knowledge creation and formation of new disciplines [Reference Cohendet, Grandadam, Simon and Capdevila16]. Thus, identifying invisible research communities is critical for translational research and for addressing inherently multi-factorial and complex research problems (e.g. obesity [Reference Weng, Gallagher, Bales, Bakken and Ginsberg17], addiction [Reference Edwards18], or implementation science [Reference Estabrooks, Derksen and Winther19]) that span across biological, preclinical, clinical, public health, and socio-cultural realms.

The data collected through an Un-Meeting provide a unique opportunity to study the emergence of translational ideas for future research from the perspective of investigators interested in developing emerging collaborations, and to identify potential invisible research communities. Previous efforts identifying such ideas and communities have been largely limited to semantic analysis of translational research topics, heavily focused on bibliometric analysis of research outputs to identify hot topics and emerging fields (e.g. cancer research, heart disease [Reference Blümel, Gauch, Hendriks, Krüger and Reinhart20]) or common research approaches (e.g. epidemiology, pharmacokinetics [Reference Zhang, Wang and Diao21]). By focusing on the products of collaborations, such efforts miss the opportunity to identify cross-disciplinary potential teams, collaborations, and factors influencing team formation.

In contrast, analytic clustering of dynamic Un-Meeting topic keyword data allows a multifaceted analysis of attendee interests, dominant fields, and common frameworks. Such keyword analysis may identify bridging topics and cross-disciplinary approaches for future scientific team formation to address urgent research problems. Network analysis can identify topics that connect attendees from disparate research areas, similar to identifying bridging keywords in research publications that cross scientific fields [Reference Jaewoo and Woonsun22Reference Cambrosio, Keating, Mercier, Lewison and Mogoutov24].

In this exploratory study, we describe content analysis of topics generated by participants in an Un-Meeting on the “opioid crisis” at University of Rochester. We investigated the clustering patterns and bridging action words, as indicators of dominant fields and bridging opportunities.

Methods

Un-Meeting Planning and Data Collection

The Center for Leading Innovation and Collaboration (CLIC), housed at the University of Rochester, hosted the first CTSA-wide “Un-Meeting” on June 2, 2018 addressing the opioid crisis. The Un-Meeting is a participatory event focused on engaging translational scientists, policy makers, community members, advocates, and public health professionals in a dynamic process of idea generation and translational conversation [25]. The Un-Meeting began with an introduction to the objectives and event rules, followed by a series of lightning talks (“4×4s”; 4 minutes, 4 slides) by scientists and decision-makers, aiming to provide a primer for potential topics related to the opioid crisis for subsequent small group breakout sessions [Reference Sugarwala, White, Steele, Ossip and Zand12].

After the talks, attendees used sticky notes to write topics of interest, questions, or ideas for breakout sessions and placed them on an idea generation board. Assisted by the organizing team, conference participants were encouraged to group the ideas into common themes that would determine the eventual topics for the subsequent concurrent small group breakout sessions. Facilitators and participants re-arrange and aggregate these notes into small group session topics in specific rooms and time slots. Attendees then self-select which sessions they would like to join. The resulting breakout sessions were 45 minutes long, unmoderated, and included between 8 and 25 participants. A second round of 4×4 talks, topic generation, and breakout sessions occurred in an afternoon session.

Topic Mapping

Photographs of the notes posted on the grid were used to collect the final clustering, and were transcribed into machine-readable format by hand. Each note was treated as a separate unit of text and was pre-processed by removing stop words (e.g. the, and, has) and common terms using the Automap program [Reference Carley, Columbus and Azoulay26]. The resulting keyword list was manually examined, and obvious synonyms were merged.

We used two analytical techniques to explore the patterns of topic clusterization:

Keyword cluster analysis: We clustered keywords based on their co-occurrence in notes and linked them with their corresponding breakout sessions using a density-based spatial clustering (DBSCAN) algorithm [Reference Ester, Kriegel, Sander and Xu27] with a centroid cluster dissimilarity function (Mathematica version 10.1; Wolfram, Indianapolis IN). The algorithm grouped together keywords on a two-dimensional surface based on commonality of their neighbors. The resulting clusters had keywords that were used together and shared similar neighboring keywords. In order to visualize the extent to which these clusters resemble the resulting breakout sessions, we developed a heatmap showing the commonality of keywords in clusters and breakout sessions.

Keyword-to-session network mapping: To identify keywords that bridged across fields and disciplines, we performed a separate analysis on keywords that were assigned to more than one breakout session. We expected that this analysis would provide clues to translational opportunities to address the opioid crisis and opportunities for cross-disciplinary team formation. We developed a keyword-to-session two-mode matrix and map, with nodes representing keywords and breakout sessions, and edges representing the relation between keywords and sessions. The nodes (keywords and sessions) were arranged in a two-dimensional graph using multi-dimensional scaling (MDS) of geodesic distances between nodes [Reference Jaworska and Chupetlovska-Anastasova28] and plotted using NetDraw [Reference Borgatti29].

Results

Participant Characteristics

In total, 102 individuals from 40 institutions (47% academic, 27% CTSA hub affiliate, 3% NIH, 11% other government agencies, 5% community organizations, 1% foundation, and 6% other) participated in the Un-Meeting. A third of participants came from within a 100-mile radius of the Un-Meeting location, the remainder represented 16 states and the District of Columbia.

Keyword Cluster Analysis

The goal of this analysis was to visualize the conceptual distance between and within breakout sessions. Such a mapping can show the conceptual diversity of the conference, grouping of words within the breakout sessions, provide an unsupervised clustering window into the breadth or focus of a particular breakout, and cross-connections between breakouts.

As a result of the idea generation session, 150 unique ideas were documented and grouped into 23 breakout sessions (Supplementary table 1). Unsupervised clustering of the 248 keywords in 150 sticky note ideas resulted in 18 clusters (Fig. 1A). The heatmap in Fig. 1B represents how frequently keywords within each cluster overlapped between breakout sessions. For example, the keywords in Cluster 4 were widely distributed across almost all sessions (Fig. 1B). This likely reflects the general medical theme of the keywords in this cluster, including ‘opioid’ (n = 39 occurrences), ‘treatment’ (n = 27), ‘pain’ (n = 15), ‘research’ (n = 8), ‘medication’ (n = 8), and ‘community’ (n = 8). Many less frequent, but conceptually distinct, keywords were also included in this cluster. Examples include ‘dissemination’ (n = 1), ‘outreach’ (n = 1), ‘workforce’ (n = 1), and ‘translate’ (n = 2). Similarly, cluster #2 keywords occurred broadly across 11 sessions, and included topics related to adoption/implementation/quality and evaluation: ‘access’ (n = 12), ‘implementation’ (n = 4), ‘context’ (n = 3), and ‘quality’ (n = 2). On the other hand, clusters with unique or limited multi-session occurrences included keywords such as ‘neonatal’ (n = 1), ‘prenatal’ (n = 1), ‘discrimination’ (n = 1), ‘disparity’ (n = 1), ‘racism’ (n = 1), ‘payment’ (n = 1), and ‘policy’ (n = 2).

Fig. 1. Keywords cluster analysis. (A): the clustering map; (B): keyword cluster to breakout session heat map; (C): the list of keywords in each cluster.

We next examined the linkage between breakout sessions and keyword clusters. Breakout sessions also varied in terms of the breadth of the distribution of their keywords across clusters. Six sessions with highest between-cluster breadth shared keywords with five or six clusters. They included Disparities in Addiction, Access to Treatment (Session 17), Criminal Justice (Session 2), Clinical trials (Session 3), Community Engagement (Session 8), Special Populations (Session 11), and Health Insurance/Policy (Session 23). Most sessions addressed systemic and cross-disciplinary issues, involving community, governmental, and policy sectors.

Most interestingly, we found that the content of breakout sessions rarely corresponded with keyword clusters, as the content of clusters usually referred to multiple breakout sessions. Thus, clusters related to general medical aspects of addiction and systemic and organizational themes distributed across breakout sessions. Themes related to special populations and disparities did not appear in many sessions and were more specific to the sessions corresponding to these topics.

Keyword-to-Session Network Mapping

We next analyzed the relationship between keywords and sessions, based on their distribution in a network map, aiming to identify meaningful regions and distinct communities. Figure 2 shows the distribution of keywords (red circles) that were shared between sessions (blue diamonds) in the keyword-to-session network. As expected, given the MDS layout method, keywords shared by broader sessions concentrated around the center of the network map (e.g. “treatment,” “OUD,” “doctor”), while others that prominently bridged across various regions of the map appeared at the periphery.

Fig. 2. The shared keyword-to-session map with MDS algorithm. Blue nodes: breakout sessions; red nodes: keywords; blue text: thematic regions; node size corresponds to the number of connections.

After reviewing, the common features of keyword clustered in different regions of the map and sessions that they bridged. We labeled seven main regions, denoted by the large blue labels in Fig. 2. The labeling process was a subjective activity to find labels that meaningfully describe the main themes of keywords and sessions in each region, and to identify thematic regions of the map. These regions were labeled as ‘community engagement’ (including keywords such as ‘engagement’, ‘partnership’, ‘network’), ‘technologies and innovations’ (including keywords such as ‘intervention’, ‘innovative’, ‘science’, ‘why’, and ‘methods’), ‘treatments and medications’ (including: ‘drug’, ‘pharmacology’, ‘development’, ‘prescribe’, ‘overdose’, ‘abuse’, ‘pain’), ‘clinical and best practice’ (including ‘guideline’, ‘clinical’, ‘best/better’, ‘practice’, ‘primary care’), ‘prevention and education’ (including ‘education’, ‘harm reduction’, ‘assist’), ‘special populations and disparities’ (including ‘recently-released’, ‘children’, ‘women’), and ‘system/context/complexity’ (including ‘structural’, ‘implementation’, ‘context’, ‘translate’, ‘population’, ‘data’).

In summary, we identified thematic regions in the map that can indicate to potential/invisible communities among researchers with common interests and approaches in opioid research. The main clusters included clinical research, translational research using technologies, population health, community engagement, special populations and disparities, and systemic and structural approaches to opioid disorders.

Discussion

In this report, we describe the use of unsupervised clustering based on semantic analysis of concepts and keywords to identify bridging concepts across expert domains and hidden communities of interest within an Un-Meeting involving investigators and research users interested addressing the opioid crisis. We used two complementary approaches to identify clusters of keywords and illustrated the overlap between sessions and keyword clusters, and areas that bridged across potential communities of research. We found that keywords related to treatment, pain, medication, access, and communities span across many breakout sessions that represented focused areas of investigation, while important concepts such as disparity, discrimination/racism, and policy were less frequent and were limited to few focused communities. The network analysis showed that focused communities were bridged by topics pertaining to the complexities of the opioid crisis, including systems, contexts, and community engagement, on one hand, and technologies, innovations, and treatment advancements on the other hand. These bridging concepts represent translational opportunities in opioid research that connect disciplines and research groups.

Results of the thematic analysis confirmed the conceptual diversity, with a majority of breakout sessions related to more than one topic area/disciplinary field, and spanning socio-political, technological, and clinical disciplines. This supports the translational nature of opioid research, similar to many other complex fields, in which, the expertise and research focus could not be easily classified by traditional departmental and disciplinary boundaries [Reference Andersen30]. This underscores the importance of identification and support of invisible/epistemic communities focusing on different aspects of this research, and development of strategies to bridge across them to facilitate knowledge translation and cross-disciplinary collaboration.

The opioid crisis affects several aspects of healthcare systems, spanning from prevention and public health to emergency care, and from primary care to specialties. The opioid crisis is even more complicated by a gradual change in the demographics of those most affected, and emergence of new behavioral trends [Reference Hohmann31,Reference Rouhani, Park, Morales, Green and Sherman32]. These complexities underscore the need for transdisciplinary collaboration between researchers and knowledge users (e.g. policy makers, community-based organizations, healthcare providers) at different stages of translational spectrum [Reference Humensky, Abedin and Muhammad33,Reference Jones, Varshneya, Hudzik and Huhn34], providing a much-needed and fertile opportunity for CTSA researchers and their institutions to promote translational scientific collaborations and innovations [Reference Cottler, Green, Pincus, McIntosh, Humensky and Brady35]. Major bridging topics identified in our analysis could be mapped to areas of current CTSA Program emphasis (e.g. community engagement, methods and processes, informatics, and clinical trials) [Reference Liverman, Schultz, Terry and Leshner36] and the emerging area of dissemination and implementation [Reference Dolor, Proctor, Stevens, Boone, Meissner and Baldwin37] and health equity [Reference Yousefi Nooraie, Kwan and Cohn38]. The bridging regions of the keyword map in our analysis are also consistent with the major areas of capacity building by CTSA hubs to address the opioid crisis, identified by Cottler et al. who classified them into preclinical, clinical research, community engagement, computational science and data informatics, and workforce development and implementation science [Reference Cottler, Green, Pincus, McIntosh, Humensky and Brady35]. While it is likely that this reflects the fact that over 75% of the conference attendees came from the CTSA consortium, this also provides an opportunity to identify potential areas for scientific team formation.

Inspection of the bridging concepts in the keyword-to-session map provides clues for translational opportunities in opioid research to be fostered by CTSA programs. These opportunities include:

  • Collaboration between clinical and basic sciences researchers to develop new medications and treatments. This is a dominant area in the center of Fig. 2, that involves themes related to innovative treatments, use of technologies to develop innovative methods of research and evaluation, and data science.

  • Collaboration between health researchers and community members as well as community-based institutions, to engage stakeholders in research and to address disparities. The Community engagement region in Fig. 2 connects themes related to treatment, prevention, education.

  • Collaboration between clinical researchers, system scientists, dissemination & implementation scientists, and sociologists to study the complexities of social systems and organization of care. The region labeled System/Context/Complexity in Fig. 2 is located adjacent to Special populations/Disparities, which underscores the role of systemic approaches to improve health equity in this area.

While the results of our study at a minimum provide a potential roadmap of opportunities for translational advancement in opioid research among this core subgroup of scientists, there are several limitations to be acknowledged. The keywords used in the mapping are based on limited content provided on sticky notes and might miss the complexities and breadth of subject matters to which they correspond. This may affect the richness of conceptual clusters and resulting interpretations. The assignment of topics to breakout sessions was moderated by a facilitator and hence does not reflect a completely unsupervised process of clustering. The topics also reflect the areas of expertise of this particular group of attendees and may not be generalizable. Nevertheless, this method of semantic analysis with thematic network analysis and keyword clustering may be useful for analyzing Un-Meetings with the aim of identifying hidden communities, areas of potential collaboration, and potential gaps in a research network’s ability to impact a chosen translational research problem. The value of these clustering techniques in identifying emerging communities and future collaboration potentials could be assessed using mixed methods studies to incorporate the perspectives and reflections of investigators involved in idea generation activities into the analysis.

Conclusions

Our case study of mapping the generated ideas in an Un-Meeting on the opioid crisis, an inherently translational issue, provided insights on the thematic clusters and topic areas that bridge across them. Our findings add to the scientific body of literature on using thematic mapping to reveal the complexities of inter-disciplinary research [Reference Wagner, Roessner and Bobb39] and provide clues about emergent themes to inform strategic planning in translational research [Reference Falk-Krzesinski, Contractor and Fiore40]. The dynamic process of grouping breakout session ideas into clusters is similar to other graphical approaches used to classify concepts and topics, such as Concept Mapping [Reference Falk-Krzesinski, Contractor and Fiore40Reference Trochim and Kane42]. The Un-Meeting format appears particularly suitable to study the dynamics of idea generation and team building in translational science, where transdisciplinary teams are critical to advance novel discoveries and innovative solutions to biomedical problems across multiple “translational barriers” via cross-disciplinary teams [Reference Gilliland, White and Gee5,Reference Sohn43].

The cross-disciplinary nature of topic areas that bridge across thematic communities provide opportunities for CTSA programs to engage and support diverse communities of researchers and users to develop translational teams. Potential opportunities to support translational collaborations include technological advancements of opioid prevention, treatment, and surveillance; studying systems, contexts, and complexities of the opioid crisis, and studies focusing on special populations and health disparities.

Supplementary material

To view supplementary material for this article, please visit https://doi.org/10.1017/cts.2022.490

Acknowledgements

The authors would like to thank Jeanne Holden-Wiltse, Raquel Ruiz, Melissa Trayhan, and Kate Fetherston from CLIC for their assistance with the Un-Meeting.

This work was funded in part by the University of Rochester Center for Leading Innovation and Collaboration (CLIC), under Grant U24TR002260 and the University of Rochester CTSA award number UL1 TR002001, both from the National Center for Advancing Translational Sciences of the National Institutes of Health. This work is solely the responsibility of the authors and does not necessarily represent the official views of the NIH.

Disclosures

None of the authors have any actual, potential, or perceived conflicts of interest to disclose.

Footnotes

Deborah J. Ossip and Martin S. Zand shared senior authorship.

References

Austin, CP. Translating translation. Nature Reviews Drug Discovery 2018; 17(7): 455456.CrossRefGoogle ScholarPubMed
Ranwala, D, Alberg, AJ, Brady, KT, Obeid, JS, Davis, R, Halushka, PV. Scientific retreats with speed dating: networking to stimulate new interdisciplinary translational research collaborations and team science. Journal of Investigative Medicine 2017; 65(2): 382390.CrossRefGoogle ScholarPubMed
Ranwala, D, Alberg, AJ, Brady, KT, Obeid, JS, Davis, R, Halushka, PV. Retreats to stimulate cross-disciplinary translational research collaborations: Medical University of South Carolina CTSA Pilot Project Program Initiative. In: Strategies for Team Science Success. Cham: Springer, 2019, pp. 261265.CrossRefGoogle Scholar
Arevian, AC, Bell, D, Kretzman, M, et al. Participatory methods to support team science development for predictive analytics in health. Journal of Clinical and Translational Science 2018; 2(3): 178182.CrossRefGoogle ScholarPubMed
Gilliland, CT, White, J, Gee, B, et al. The fundamental characteristics of a translational scientist. ACS Pharmacology & Translational Science 2019; 2(3): 213216. DOI 10.1021/acsptsci.9b00022.CrossRefGoogle ScholarPubMed
Greenhill, K, Wiebrands, C. The unconference: a new model for better professional communication. In: LIANZA Conference 2008: Poropitia Outside the Box, 2008.Google Scholar
Vernon, W. The Delphi technique: a review. International Journal of Therapy and Rehabilitation 2009; 16(2): 6976.CrossRefGoogle Scholar
Battelle, J. When geeks go camping, ideas hatch. Techies pitch tents at Foo Camp to ponder the future. CNN com 2004; 10(Saturday, January 10, 2004).Google Scholar
Ballinger, J. Geeks gather to share, network and play. Computerworld February 13, 2008; 2008(Friday, February 10, 2012). (https://web.archive.org/web/20120210052054/http://computerworld.co.nz/news.nsf/news/1956694458963284CC2573E9000D8991)Google Scholar
Jones, CT, Lane, A, Shah, A, Carter, K, Lackey, R, Kolb, R. The Un-meeting approach to stimulate collaborative adult learning: an application for clinical research professionals. Journal of Clinical and Translational Science 2021; 5(1): e162.CrossRefGoogle ScholarPubMed
Solway, J, Kenyon, N, Berglund, L. Clinical and translational science and climate change: time for action. Journal of Clinical and Translational Science 2022; 6(1): e57. DOI 10.1017/cts.2022.9.CrossRefGoogle ScholarPubMed
Sugarwala, L, White, RJ, Steele, SJ, Ossip, D, Zand, MS. CLIC Un-Meeting Event Guide. Zenodo. DOI 10.5281/zenodo.6983868.Google Scholar
Zuccala, A. Modeling the invisible college. Journal of the American Society for Information Science and Technology 2006; 57(2): 152168. DOI 10.1002/asi.20256.CrossRefGoogle Scholar
Tuire, P, Erno, L. Exploring invisible scientific communities: studying networking relations within an educational research community. A Finnish case. Higher Education 2001; 42(4): 493513.Google Scholar
Amin, A, Cohendet, P. Architectures of Knowledge: Firms, Capabilities, and Communities. Oxford: Oxford University Press, 2004.CrossRefGoogle Scholar
Cohendet, P, Grandadam, D, Simon, L, Capdevila, I. Epistemic communities, localization and the dynamics of knowledge creation. Journal of Economic Geography 2014; 14(5): 929954.CrossRefGoogle Scholar
Weng, C, Gallagher, D, Bales, ME, Bakken, S, Ginsberg, HN. Understanding Interdisciplinary Health Sciences Collaborations: A Campus-Wide Survey of Obesity Experts. Rockville, MD: American Medical Informatics Association, 2008, p. 798.Google ScholarPubMed
Edwards, G. Addiction: a journal and its invisible college. Addiction 2006; 101(5): 629637.CrossRefGoogle ScholarPubMed
Estabrooks, CA, Derksen, L, Winther, C, et al. The intellectual structure and substance of the knowledge utilization field: a longitudinal author co-citation analysis, 1945 to 2004. Implementation Science 2008; 3(1): 122.CrossRefGoogle Scholar
Blümel, C, Gauch, S, Hendriks, B, Krüger, AK, Reinhart, M. In search of translational research. In: Report on the Development and Current Understanding of a New Terminology in Medical Research and Practice (iFQ-BIH-Report). Berlin: Berlin Institute of Health, 2015.Google Scholar
Zhang, Y, Wang, L, Diao, T. The quantitative evaluation of the Clinical and Translational Science Awards (CTSA) program based on science mapping and scientometric analysis. Clinical and Translational Science 2013; 6(6): 452457.CrossRefGoogle ScholarPubMed
Jaewoo, C, Woonsun, K. Themes and trends in Korean educational technology research: a social network analysis of keywords. Procedia-Social and Behavioral Sciences 2014; 131: 171176.CrossRefGoogle Scholar
Kim, K, Lee, K-S. Identification of the knowledge structure of cancer survivors’ return to work and quality of life: a text network analysis. International Journal of Environmental Research and Public Health 2020; 17(24): 9368.CrossRefGoogle ScholarPubMed
Cambrosio, A, Keating, P, Mercier, S, Lewison, G, Mogoutov, A. Mapping the emergence and development of translational cancer research. European Journal of Cancer 2006; 42(18): 31403148.CrossRefGoogle ScholarPubMed
The Center for Leading Innovation and Collaboration. Un-Meeting Event Guide. (https://clic-ctsa.org/sites/default/files/2019-08/Un-Meeting%20Event%20Guide_2019.pdf)Google Scholar
Carley, KM, Columbus, D, Azoulay, A. Automap User’s Guide 2012, 2012. (https://apps.dtic.mil/dtic/tr/fulltext/u2/a563083.pdf)CrossRefGoogle Scholar
Ester, M, Kriegel, H-P, Sander, J, Xu, X. Density-based spatial clustering of applications with noise. In: Proceedings of the Second International Conference on Knowledge Discovery and Data Mining, 1996, p. 6.Google Scholar
Jaworska, N, Chupetlovska-Anastasova, A. A review of multidimensional scaling (MDS) and its utility in various psychological domains. Tutorials in Quantitative Mmethods for Psychology 2009; 5(1): 110.CrossRefGoogle Scholar
Borgatti, SP. NetDraw: Graph Visualization Software. Harvard: Analytic Technologies, 2002.Google Scholar
Andersen, H. Collaboration, interdisciplinarity, and the epistemology of contemporary science. Studies in History and Philosophy of Science Part A 2016; 56: 110. DOI 10.1016/j.shpsa.2015.10.006.CrossRefGoogle ScholarPubMed
Hohmann, L. An untapped potential in addressing the opioid epidemic. Journal of the American Pharmacists Association 2019; 59(5): 625627.CrossRefGoogle Scholar
Rouhani, S, Park, JN, Morales, KB, Green, TC, Sherman, SG. Trends in opioid initiation among people who use opioids in three US cities. Drug and Alcohol Review 2020; 39(4): 375383.CrossRefGoogle ScholarPubMed
Humensky, JL, Abedin, Z, Muhammad, K, et al. Promoting interdisciplinary research to respond to public health crises: the response of the Columbia University CTSA to the opioid crisis. Journal of Clinical and Translational Science 2020; 4(1): 2227.CrossRefGoogle Scholar
Jones, JD, Varshneya, NB, Hudzik, TJ, Huhn, AS. Improving translational research outcomes for opioid use disorder treatments. Current Addiction Reports 2021; 8(1): 113.Google Scholar
Cottler, LB, Green, AI, Pincus, HA, McIntosh, S, Humensky, JL, Brady, K. Building capacity for collaborative research on opioid and other substance use disorders through the Clinical and Translational Science Award Program. Journal of Clinical and Translational Science 2020; 4(2): 8189.CrossRefGoogle ScholarPubMed
Liverman, CT, Schultz, AM, Terry, SF, Leshner, AI. The CTSA Program at NIH: Opportunities for Advancing Clinical and Translational Research. Washington, DC: National Academies Press, 2013.Google Scholar
Dolor, RJ, Proctor, E, Stevens, KR, Boone, LR, Meissner, P, Baldwin, L-M. Dissemination and implementation science activities across the Clinical Translational Science Award (CTSA) Consortium: report from a survey of CTSA leaders. Journal of Clinical and Translational Science 2020; 4(3): 188194.CrossRefGoogle Scholar
Yousefi Nooraie, R, Kwan, BM, Cohn, E, et al. Advancing health equity through CTSA programs: opportunities for interaction between health equity, dissemination and implementation, and translational science. Journal of Clinical and Translational Science 2020; 4(3): 168175.Google ScholarPubMed
Wagner, CS, Roessner, JD, Bobb, K, et al. Approaches to understanding and measuring interdisciplinary scientific research (IDR): a review of the literature. Journal of Informetrics 2011; 5(1): 1426. DOI 10.1016/j.joi.2010.06.004.Google Scholar
Falk-Krzesinski, HJ, Contractor, N, Fiore, SM, et al. Mapping a research agenda for the science of team science. Research Evaluation 2011; 20(2): 145158.CrossRefGoogle ScholarPubMed
Trochim, WM. Hindsight is 20/20: reflections on the evolution of concept mapping. Evaluation and Program Planning 2017; 60: 176185.CrossRefGoogle ScholarPubMed
Trochim, W, Kane, M. Concept mapping: an introduction to structured conceptualization in health care. International Journal for Quality in Health Care 2005; 17(3): 187191.CrossRefGoogle ScholarPubMed
Sohn, E. The future of the scientific conference. Nature 2018; 564(7736): S80S82. DOI 10.1038/d41586-018-07779-y.CrossRefGoogle ScholarPubMed
Figure 0

Fig. 1. Keywords cluster analysis. (A): the clustering map; (B): keyword cluster to breakout session heat map; (C): the list of keywords in each cluster.

Figure 1

Fig. 2. The shared keyword-to-session map with MDS algorithm. Blue nodes: breakout sessions; red nodes: keywords; blue text: thematic regions; node size corresponds to the number of connections.

Supplementary material: File

Yousefi Nooraie et al. supplementary material

Appendix

Download Yousefi Nooraie et al. supplementary material(File)
File 18.1 KB