Team science as interprofessional collaborative research practice: a systematic review of the science of team science literature.

The National Institute of Health's concept of team science is a means of addressing complex clinical problems by applying conceptual and methodological approaches from multiple disciplines and health professions. The ultimate goal is the improved quality of care of patients with an emphasis on better population health outcomes. Collaborative research practice occurs when researchers from >1 health-related profession engage in scientific inquiry to jointly create and disseminate new knowledge to clinical and research health professionals in order to provide the highest quality of patient care to improve population health outcomes. Training of clinicians and researchers is necessary to produce clinically relevant evidence upon which to base patient care for disease management and empirically guided team-based patient care. In this study, we hypothesized that team science is an example of effective and impactful interprofessional collaborative research practice. To assess this hypothesis, we examined the contemporary literature on the science of team science (SciTS) produced in the past 10 years (2005-2015) and related the SciTS to the overall field of interprofessional collaborative practice, of which collaborative research practice is a subset. A modified preferred reporting items for systematic reviews and meta-analyses (PRISMA) approach was employed to analyze the SciTS literature in light of the general question: Is team science an example of interprofessional collaborative research practice? After completing a systematic review of the SciTS literature, the posed hypothesis was accepted, concluding that team science is a dimension of interprofessional collaborative practice.

Little has been written about team science as interprofessional collaborative research practice.

Team science has led to the science of team science (SciTS) which is a meta-analysis or meta-understanding of team science including the understanding, management, and evaluation of team science conditions, collaborative processes, and outcomes to enable translation of research findings into new scientific knowledge, advances, clinical practices, and policies.

Interprofessional collaborative research practice occurs when disciplinarians or practitioners from more than one health-related profession engage in scientific inquiry to jointly create and disseminate new knowledge to health professionals in order to provide the highest quality of patient care to improve patient-level and population-level health outcomes.

To date, interprofessional collaborative research practice and team science have developed along separate paths rather than an integrated one even though team science in many ways is interprofessional collaborative research practice.

After completing a systematic review of the SciTS literature, we accepted the hypothesis that team science is an example of effective and impactful interprofessional collaborative research practice.

Team science is a dimension of the larger domain of interprofessional collaborative practice.

There currently is a paucity of interprofessional and/or interdisciplinary team-based research training for health professional students who are training to become researchers.

After completing a systematic review of the SciTS literature, we accepted the hypothesis that team science is an example of effective and impactful interprofessional collaborative research practice, concluding that team science is a dimension of the larger domain of interprofessional collaborative practice.

For team science to actually gain long-term traction in successfully translating the findings from interprofessionally generated science into team-based clinical care, scientific and research training must change to incorporate a meaningful interprofessional dimension to it.

Very little research training is team based or interprofessionally based.

Just as health professions students (pharmacy, medicine, nursing, dentistry, etc) need interprofessional training for team-based clinical practice, health-related professional students who are training to become researchers need interprofessional and/or interdisciplinary team-based research training.

Introduction

The term team science has been used in multiple and diverse contexts.1–3 The National Institutes of Health's (NIH) concept of team science entails team members with training and expertise in different health profession fields working together to combine and integrate their knowledge, skills, and perspectives into single research projects that are clinically focused.1–3 Some have argued that clinical and translational science, grounded in NIH's concept of team science, is the gold standard for team science.4 It is NIH's conceptualization of team science that we abide by in this review paper.

Team science is a means of attending to complex clinical problems by applying conceptual and methodological approaches from multiple scientific disciplines and health professions.2 3 The evolution of team science has until recently been a missed opportunity for the field of interprofessional clinical practice and education (IPE). IPE has historically focused on educational interventions for prelicensure health profession students (eg, pharmacy, nursing, and medicine) in order to influence future clinical practice.5–8 Continuing professional education on interprofessional team-based care has also achieved some IPE traction, again with the focus on influencing clinical practice directly. With the focus on education interventions, team science has largely been overlooked as an example of interprofessional and interdisciplinary collaborative practice essential to the health professions and care of patients. The nature of the collaborative practice of team science is the creation of new knowledge through interdisciplinary research that is translatable to clinical practice. It has become increasingly clear that the ability of different health professionals to provide optimal care is dependent on the sharing of expertise, knowledge, and peer learning.9

One example of the importance and use of team science is the domain of evidence-driven patient care that entails integrating clinical expertise with current best available clinical evidence from well-designed systematic research. Such research often informs clinical guidelines that can then be transformed into effective evidence-based clinical practice. Ultimately, effective patient care results from the combination of interprofessional medical practice and transdisciplinary scientific knowledge. Traditionally, clinical guidelines have been driven by evidence (science) produced by unidisciplinary teams or by an individual researcher.10 11 Additionally, clinical guidelines rarely provide direction for team-based care.12 13 As clinical and health-related problems become more complex, there is an increasing need to rely on team science as the nidus to produce evidence for the best possible care of patients that integrates the knowledge from multiple disciplines14–16 and emphasizes the importance of team-based care.17–19

Team science has given rise to the field of the science of team science (SciTS). SciTS is the understanding, management, and evaluation of team science conditions, collaborative processes, and outcomes to enable translation of research findings into new scientific knowledge, advances, clinical practices, and policies. In contrast, team science is an initiative to promote collaborative and frequently cross-disciplinary approaches to scientifically answer clinically related research questions.

A 2008 special issue of the American Journal of Preventive Medicine was dedicated to the nascent field of the SciTS. In this issue, Stokols et al15 noted that the SciTS had not as yet amalgamated as a recognized paradigm. They also distinguished between the SciTS and team science by noting that team science referred to research initiatives by collaborating scientists from multiple disciples or fields, whereas the SciTS studied the effectiveness and characteristics of team science. A 2008 article by Hall et al20 referenced a conference held by NIH's National Cancer Institute (NCI) in 2006 on the SciTS that focused on assessing the value of transdisciplinary research. The objectives of the NCI conference were to address ambiguities and gaps in the SciTS literature, promote greater integration of knowledge in the field, and identify key issues for future investigation. Team science, as referred to in these instances,15 20 is grounded in the same definition that we are using in this research study.

IPE is interrelated and forms an essential nexus where at the very least two or more professions learn about, from, and with each other to enable effective clinical collaboration to improve patient and population health outcomes5 by delivering the highest quality of care.6 In the IPE nexus, interprofessional education will lead to collaborative clinical practice which will in turn inform interprofessional education over time. To date, the IPE nexus and team science have developed along separate paths rather than an integrated one. Team science in many ways is collaborative research practice and belongs in the IPE nexus.

Collaborative research practice occurs when disciplinarians or practitioners from more than one health-related profession engage in scientific inquiry to jointly create and disseminate new knowledge to health professionals in order to provide the highest quality of patient care to improve patient-level and population-level health outcomes.21 Research produces the evidence that guides empirically grounded clinical practice or evidence-based care.22

The four features that characterize collaborative research practice can be converted into questions that can be answered. These questions are as follows:

Is team science comprised of persons from more than one health-related profession who collaborate on research that leverages the perspectives and knowledge of the different health professions or disciplines?

Does team science foster sound scientific inquiry that takes into account, without compromising, the knowledge and expertise of multiple health professions?

Does team science create and disseminate new knowledge to health professionals from many disciplines?

Does team science provide a knowledge base/foundation for the highest quality of patient care and improved health outcomes incorporating interprofessional team-based care?

This paper answers each of these questions by examining the contemporary literature on the SciTS produced in the past 10 years (2005–2015) and relates the SciTS to the overall field of IPE, of which collaborative research practice is a subset. The central research question of this review paper was: Is team science an example of interprofessional collaborative research practice? In this regard, we hypothesized that team science is an example of effective and impactful interprofessional collaborative research practice.

Methods

We employed a modified preferred reporting items for systematic reviews and meta-analyses (PRISMA) approach,23 which is organized by five distinct elements or steps: beginning with a clearly formulated question, using the question to develop clear inclusion criteria to identify relevant studies, an approach to appraise the studies or a subset of the studies, a summary of the evidence using an explicit methodology, and interpreting the findings of the review. The details of these five steps are described below.

Step 1: formulating the research question. Prior to conducting the literature search, the purpose of the study and a specific question were established, leading to the clarification of the inclusion criteria. Our question was: Is team science an example of interprofessional collaborative research practice? We refined the research question into the following hypothesis: team science is an important example of effective and impactful collaborative research practice.

Step 2: identifying the relevant work. The inclusion criteria emerged directly from the question guiding this review and were specified a priori. We chose to limit our literature search and subsequent analyses to published, peer-reviewed articles, from the time span of 2005–2015. We chose 2005 as the floor year because it was 1 year before the NCI conference, and we chose 2015 as the ceiling because that was the year we began our study. Unpublished literature was excluded from this review. Moreover, we chose to focus on the SciTS literature because that would assist in establishing the criteria of team science in order to compare it to our working definition of interprofessional collaborative research practice. Our literature search was further limited to papers written in English as well as only those that were health related. The identification of relevant literature was grounded by our adoption of NIH's definition of team science and SciTS.

PubMed and Google Scholar were queried in our literature search. Our search terms were different combinations of team science, interprofessional collaborative practice, the science of team science, and SciTS (the accepted acronym for the science of team science). The literature search was initiated using the terms ‘team science as interprofessional collaborative practice’. It was subsequently refined to team science alone. We then searched using the terms ‘science of team science’, which was narrowed or refined to SciTS. The final search was conducted using the terms ‘team science SciTS’. Patents and citations were explicitly excluded from our searches of the literature. For clarity purposes, a glossary of terms is provided in table 1.

Table 1

Glossary of terms

Terms	Definitions
Team science	Entails team members with training and expertise in different health profession fields working together to combine and integrate their knowledge, skills, and perspectives into single research projects that are clinically focused
IPE	Occurs when learners of professionals from two or more health professions learn about, from and with each other to enable effective clinical collaboration to improve health outcomes by delivering the highest quality of care
Continuing professional education	Structured educational activity(ies) designed and intended to support the ongoing development of health professionals to maintain and enhance their competence in providing the best quality of care
Evidence-driven patient care	Entails integrating clinical expertise with current best available clinical evidence from well-designed systematic research
Transdisciplinary scientific knowledge	Scientific research collaboration that entails the exchange of information, altering discipline-specific approaches, sharing resources, and integrating disciplines to generate new knowledge
SciTS	Is the understanding, management, and evaluation of team science conditions, collaborative processes, and outcomes to enable translation of research findings into new scientific knowledge, advances, clinical practices, and policies
Collaborative research practice	Occurs when researchers from more than one health-related profession engage in scientific inquiry to jointly create and disseminate new knowledge to clinical and research health professionals in order to provide the highest quality of patient care to improve population health outcomes

IPE, interprofessional clinical practice and education; SciTS, science of team science.

Step 3: an approach to appraise the studies. To assess the selected papers, we created a table that included the full paper citation along with the four components of collaborative research practice. Two authors reviewed each article and a total of six authors reviewed the papers. In order to eliminate inter-rater bias as much as possible, the six authors were paired to each of the papers using a random pairing generator. Each author reviewed the paper individually to determine which, if any, of the four defining criteria were present and the overall inclusion criteria (defined in step 2). The authors reviewing each paper made a decision as to whether or not the manuscript should be included in the review. In total, 14 author pairs were generated, and each author reviewed between 6 and 18 papers each. Whenever there was consensus between both reviewers for all four categories, the paper was either included or excluded. When there was disagreement between the author pairs, the article was reviewed and discussed by all six reviewing authors and a final determination of inclusion or exclusion was made.

Step 4: summarizing the presented evidence. Each of the 32 papers selected for final appraisal were coded by the four collaborative research practice criteria indicated by the codes MD, KE, CD, and IPTC (see table 2 for code definitions). Each article was coded according to which of the four defining criteria of interprofessional collaborative research were present. At least one of the criteria needed to be present for the paper to be included in the final analysis and this led to some of the articles being excluded from the analysis. During the coding process, disagreement occurred in over 50% of the papers. Disagreements were resolved by discussion and all six reviewers came to consensus.

Table 2

Codes for defining criteria of interprofessional collaborative research practice

Code	Criteria description
MD	Multiple disciplinarians from more than one health-related profession who collaborate on research that leverages the perspectives and knowledge of the different health professions or disciplines
KE	Sound scientific inquiry that takes into account, without compromising, the knowledge and expertise of multiple health professions
CD	Create and disseminate new knowledge to health professionals of many stripes and disciplines
IPTC	Provide a knowledge base/foundation for the highest quality of patient care and improved population health outcomes incorporating interprofessional team-based care

Step 5: interpreting the findings. In the Discussion section, the findings of this review are interpreted. In addition, a summary of the current focus on the SciTS and interprofessional collaborative research practice is presented. We also offer suggestions for incorporating team science as interprofessional collaborative research practice into interprofessional health professions education and clinical practice.

Results

The literature search was conducted in Google Scholar and PubMed. The initial search using the terms ‘team science as interprofessional collaborative practice’ yielded no articles. Selecting for ‘no citations’ and ‘no patents’ and searching for the term ‘Team Science’, 3420 items were returned. Refining the search term to the ‘science of team science’, 676 items were found. Using the acronym ‘SciTS’ as the search term, reduced the items to 291. An examination of these items quickly revealed that the acronym is used by other entities to represent information other than the examination of team science. This led to the use of our final search terms ‘team science SciTS’. Using these final terms yielded 67 articles. Once duplicates, non-English papers, reviews of websites or tool kits, non-health-related papers, editorials and descriptions of tool kits were removed, 32 articles were included for review. Figure 1 displays a flow chart of this selection process. Table 3 provides information on the 32 SciTS articles included in this review. Also displayed in this table are the criteria of interprofessional collaborative research practice that was met by each article reviewed.

Figure 1

Science of team science article selection flow chart by reviewer inclusion criteria. SciTS, science of team science. *Inappropriate refers to website and tool kit review papers, non-health-related papers, editorials, and descriptions of tool kits.

Table 3

SciTS papers reviewed

	Interprofessional collaborative research practice criteria coded
Full citation for paper included in the review (n=32)	MD*	KE†	CD‡	IPTC§
Baker B. The Science of Team Science An emerging field delves into the complexities of effective collaboration. BioScience 2015;65:639–44	✓	✓	✓
Begg MD, Crumley G, Fair AM, et al. Approaches to preparing young scholars for careers in interdisciplinary team science. J Investig Med 2014;62:14–25	✓	✓
Begg MD, Bennett LM, Cicutto L, et al. Graduate education for the future: new models and methods for the clinical and translational workforce. Clin Transl Sci 2015;8:787–92	✓	✓	✓	✓
Bennett LM, Gadlin H. Collaboration and team science. J Investig Med 2012;60:768–75	✓	✓	✓
Börner K, Contractor N, Falk-Krzesinski HJ, et al. A multilevel systems perspective for the science of team science. Sci Transl Med 2010;2:49cm24	✓	✓	✓
Disis ML, Slattery JT. The road we must take: multidisciplinary team science. Sci Transl Med 2010;2:22cm9	✓	✓	✓	✓
Falk-Krzesinski HJ, Börner K, Contractor N, et al. Advancing the science of team science. Clin Transl Sci 2010;3:263–6	✓	✓	✓
Falk-Krzesinski HJ, Contractor N, Fiore SM, et al. Mapping a research agenda for the science of team science. Res Eval 2011;20:145–58	✓	✓	✓
Fiore SM. Interdisciplinarity as teamwork how the science of teams can inform team science. Small Group Res 2008;39:251–77	✓	✓	✓
Gray B. Enhancing transdisciplinary research through collaborative leadership. Am J Prev Med 2008;35:S124–32	✓	✓
Hall KL, Feng AX, Moser RP, et al. Moving the science of team science forward: collaboration and creativity. Am J Prev Med 2008;35:S243–9	✓	✓	✓
Hall KL, Olster DH, Stipelman BA, et al. News from NIH: resources for team-based research to more effectively address complex public health problems. Transl Behav Med 2012;2:373–5	✓	✓	✓	✓
Hall KL, Stokols D, Moser RP, et al. The collaboration readiness of transdisciplinary research teams and centers: findings from the National Cancer Institute's TREC year-one evaluation study. Am J Prev Med 2008;35:S161–72	✓	✓	✓	✓
Hall KL, Stokols D, Stipelman BA, et al. Assessing the value of team science: a study comparing center-and investigator-initiated grants. Am J Prev Med 2012;42:157–63	✓	✓	✓
Hall KL, Vogel AL, Stipelman BA, et al. A four-phase model of transdisciplinary team-based research: goals, team processes, and strategies. Transl Behav Med 2012;2:415–30	✓	✓	✓
Holmes JH, Lehman A, Hade E, et al. Challenges for multilevel health disparities research in a transdisciplinary environment. Am J Prev Med 2008;35:S182–92	✓	✓	✓	✓
Klein JT. Discourses of transdisciplinarity: looking back to the future. Futures 2014;63:68–74	✓	✓	✓
Klein JT. Evaluation of interdisciplinary and transdisciplinary research: a literature review. Am J Prev Med 2008;35:S116–23	✓	✓	✓
Leischow SJ, Best A, Trochim WM, et al. Systems thinking to improve the public's health. Am J Prev Med 2008;35:S196–203	✓	✓	✓
Lotrecchiano GR. A dynamical approach toward understanding mechanisms of team science: change, kinship, tension, and heritage in a transdisciplinary team. Clin Transl Sci 2013;6:267–78	✓	✓	✓
Lotrecchiano GR. The science-of-team-science, transdisciplinary capacity, and shifting paradigms for translational professionals. Journal of Translational Medicine and Epidemiology 2013;1	✓	✓	✓	✓
Mabry PL, Olster DH, Morgan GD, et al. Interdisciplinarity and systems science to improve population health: a view from the NIH Office of Behavioral and Social Sciences Research. Am J Prev Med 2008;35:S211–24	✓	✓	✓	✓
Mâsse LC, Moser RP, Stokols D, et al. Measuring collaboration and transdisciplinary integration in team science. Am J Prev Med 2008;35:S151–60	✓	✓	✓
Puga F, Stevens KR, Patel DI. Adopting best practices from team science in a healthcare improvement research network: the impact on dissemination and implementation. Nurs Res Pract 2013;2013:814360	✓	✓	✓	✓
Ryan D, Emond M, Lamontagne ME. Social network analysis as a metric for the development of an interdisciplinary, inter-organizational research team. J Interprof Care 2014;28:28–33	✓	✓	✓	✓
Spring B, Hall KL, Moller AC, et al. An emerging science and praxis for research and practice teams. Transl Behav Med 2012;2:411–4	✓	✓	✓	✓
Stokols D, Hall KL, Taylor BK, et al. The science of team science: overview of the field and introduction to the supplement. Am J Prev Med 2008;35:S77–89.	✓	✓	✓	✓
Stokols D, Misra S, Moser RP, et al. The ecology of team science: understanding contextual influences on transdisciplinary collaboration. Am J Prev Med 2008;35:S96–115	✓	✓		✓
Vogel AL, Stipelman BA, Hall KL, et al. Pioneering the transdisciplinary team science approach: lessons learnt from national cancer institute grantees. J Transl Med Epidemiol 2014;2:pii:1027	✓	✓	✓
Weaver SJ, Rosen MA, Salas E, et al. Integrating the science of team training: guidelines for continuing education. J Contin Educ Health Prof 2010;30:208–20	✓	✓	✓	✓
Wildman JL, Thayer AL, Pavlas D, et al. Team knowledge research emerging trends and critical needs. Hum Factors 2012;54:84–111	✓	✓	✓
Winter SJ, Berente N. A commentary on the pluralistic goals, logics of action, and institutional contexts of translational team science. Transl Behav Med 2012;2:441–5	✓	✓	✓

*Multiple disciplinarians from more than one health-related profession who collaborate on research that leverages the perspectives and knowledge of the different health professions or disciplines.

†Sound scientific inquiry that takes into account, without compromising, the knowledge and expertise of multiple health professions.

‡Create and disseminate new knowledge to health professionals of many stripes and disciplines.

§Provide a knowledge base/foundation for the highest quality of patient care and improved population health outcomes incorporating interprofessional team-based care.

SciTS, science of team science.

Table 4 displays a description of interprofessional collaborative research practice criteria coded per final articles reviewed (n=32). The articles reviewed were classified according to the number of interprofessional collaborative research practice criteria identified in each article by the paired reviewers and after all disagreements were resolved. Articles containing at least three or at least four of the criteria together comprised the largest group (30 papers or 93.8% with 12 papers or 37.5% containing at least four criteria and 18 or 56.3% for at least three criteria). Two papers (6.3%) were classified as containing at least two of the criteria and no papers (0.0%) were classified as containing only one of the criteria.

Table 4

Frequency and per cent of interprofessional collaborative research practice criteria coded per article (n=32)

Interprofessional collaborative research practice components present	Frequency	Per cent
At least 4	12	37.6
At least 3	18	56.3
At least 2	2	6.3
At least 1	0	0

Table 5 displays the frequency and per cent of the papers reviewed by each of the interprofessional collaborative research practice criteria coded by the reviewers. The first three criteria (MD, KE, and CD) had high percentages of occurrence or code (100%, 100%, and 90.6%, respectively). The fourth criterion (IPTC) was coded the least by the reviewers (40.6%).

Table 5

Frequency and per cent of papers containing each interprofessional collaborative research practice criteria coded (n=32)

Code	Component description	Frequency	Per cent
MD	Multiple disciplinarians from more than one health-related profession who collaborate on research that leverages the perspectives and knowledge of the different health professions or disciplines	32	100
KE	Sound scientific inquiry that takes into account, without compromising, the knowledge and expertise of multiple health professions	32	100
CD	Create and disseminate new knowledge to health professionals of many stripes and disciplines	29	90.6
IPTC	Provide a knowledge base/foundation for the highest quality of patient care and improved population health outcomes incorporating interprofessional team-based care	13	40.6

Discussion

NIH's concept of team science is a means of addressing complex clinical problems by applying conceptual and methodological approaches from multiple disciplines and health professions.2 The ultimate goal is the improved quality of care of patients with an emphasis on better population health outcomes. We started this study hypothesizing that team science is an example of effective and impactful interprofessional collaborative research practice. After completing our systematic review of the SciTS literature, we believe that this hypothesis can be accepted, concluding that team science is a dimension of interprofessional collaborative practice. Specifically, interprofessional collaborative research practice allows disciplinarians or practitioners from more than one health-related profession to collaborate on research that leverages the perspectives and knowledge of different health professions or disciplines.24–26

We reviewed and analyzed the SciTS peer-reviewed articles because SciTS studies the effectiveness and characteristics of research teams engaged in scientific inquiry. Ultimately, SciTS was a better comparator to interprofessional collaborative research practice than was team science alone. Team science refers to research initiatives undertaken by collaborating scientists from multiple disciples or fields. Furthermore, we kept our focus on the realm of health professions and health-related clinical practice as initiated by the NIH in their team science approach. Accordingly, team science does foster sound scientific inquiry that takes into account the knowledge and expertise of multiple health professions.

In our analysis, three of our criteria defining interprofessional collaborative research practice—MD, KE, and CD—correlated highly (100%, 100% and 90.6%, respectively) with the content of SciTS papers reviewed; therefore, team science creates and disseminates new knowledge to health professionals from many disciplines. Intriguingly, it was also the case that in our analysis of SciTS focused papers using the lens of our four-part definition of interprofessional collaborative research practice, one of our criteria was not present in 40.6% of the 32 articles reviewed. This neglected criterion was to provide a knowledge base/foundation for the highest quality of patient care and improved population health outcomes incorporating interprofessional team-based care. This is not to say that team science has neglected this—only that SciTS did not incorporate it fully in its analysis of team science. This is ironic given that a prominent goal of Clinical and Translational Science Awards (CTSA) is to develop teams of investigators from various fields of research who can take scientific discoveries and turn them into treatments and strategies for patients.26

One reason heretofore that team science has remained distant and separate from interprofessional collaborative practice is that it emerged and became established with NIH's funding of CTSA. This initiative by NIH was grounded in the dual recognition that some of the most cutting edge health science research takes place at the borders between disciplines and professions but the siloed efforts of researchers have propagated uniprofessional and individual research endeavors.24–26 Translational science funding was established to dismantle these research boundaries but in so doing neglected to conceptually connect team science with the field of IPE. In turn, once team science and SciTS became more established, the field of IPE missed the opportunity to embrace SciTS as an example of interprofessional collaborative practice focusing on clinical knowledge production through research.

Clearly, the increasing complexity of morbidity and the management of associated diseases and conditions require that health science researchers move beyond the boundaries of their own disciplines and professions25 in order to produce sound scientific evidence for the best possible care of patients. In the field of IPECP, there has been a growing recognition that it is at the intersection of health professions education and clinical practice where population health outcomes will be most affected. The National Center for Interprofessional Practice and Education (NCIPE) at the University of Minnesota refers to this intersection as the nexus.27–30 There is a burgeoning recognition in the team science and SciTS literature19 24 that for team science to actually gain long-term traction in successfully translating the findings from interprofessionally generated science into team-based clinical care, scientific and research training must change to incorporate a meaningful interprofessional dimension to it. This approach is significant because research training is typically discipline specific (eg, epidemiology, pharmacy, medicine, nursing, etc) with some overlap in data collection, study design, and data analysis techniques. Very little research training is team based or interprofessionally based. Just as health professions students (pharmacy, medicine, nursing, dentistry, etc) need interprofessional training for team-based clinical practice, health-related professional students who are training to become researchers need interprofessional and/or interdisciplinary team-based research training.

IPE has focused on bringing interprofessional education and health professional training together with clinical practice. In contrast, team science has only recently started to merge interprofessional research training with translation into clinical practice. There are essentially two nexi that need to be integrated. The integration that we propose is depicted in figure 2. This is a modification of the depiction of the nexus currently used by the NCIPE. The nexus is expanded to bring together health professions education, clinical practice, and health sciences research training and practice. The long-term goal of this expanded nexus, then, is to impact the triple aim outcomes31 of improved population health, increased satisfaction with healthcare received, and reduced healthcare costs.

Figure 2

Modified nexus.

Conclusions

Our literature review of the SciTS clarified that team science itself is an essential dimension of interprofessional collaborative research practice. It is important going forward that team science be incorporated into an expanded understanding of the NCIPE's nexus in order to bring together health professions education, clinical practice, and health sciences research training and practice.