https://orcid.org/0000-0001-6815-5162
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Abstract
Objective
This scoping review aims to identify complex health interventions (CHI’s) to prevent early childhood caries (ECC), explore the level of complexity of the identified CHI’s, and explore the details of their development, evaluation, and implementation.
Introduction
Many interventions to prevent ECC have multiple interacting components and can be seen as CHI’s. Recent reviews on these interventions have found inconclusive effects, which may be due to differences in the development, evaluation, and implementation of CHI’s.
Inclusion criteria
This scoping review will consider clinical trials reporting CHI’s to prevent ECC that starts during pregnancy or in the first year of life. Studies in the English language will be included regardless of the country of origin, sociocultural setting, or context.
Methods
This review will follow the Joanna Briggs Institute methodology for scoping reviews. An initial search of PubMed identified keywords and Medical Subject Headings terms. A second search of PubMed, Embase, Clarivate Analytics/Web of Science Core Collection, ClinicalTrials.gov, and the Wiley/Cochrane Library will follow. Two independent reviewers will perform title and abstract screening, retrieve and review full-text studies, and extract data. The reference lists of all included sources will be screened for additional CHI’s or relevant publications about a specific CHI. Data charting will be utilised based on study characteristics and intervention complexity. A 39-item instrument will be used to explore the details in the description of the CHI’s development, evaluation, and implementation. The results will be presented in tables, visual outputs, and a narrative summary in response to the review questions.
Citation: van Spreuwel PCJM, Munk-Overkamp MLC, Smit LC, Ziesemer KA, van Loveren C, van der Heijden GJMG, et al. (2022) Exploring the development, evaluation and implementation of complex health interventions to prevent early childhood caries in preschool children: A scoping review protocol. PLoS ONE 17(10): e0275501. https://doi.org/10.1371/journal.pone.0275501
Editor: Martina Ferrillo, University of Catanzaro, ITALY
Received: June 28, 2022; Accepted: September 16, 2022; Published: October 10, 2022
Copyright: © 2022 van Spreuwel et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Data Availability: No datasets were generated or analyzed during the current study. All relevant data from this study will be made available upon study completion.
Funding: The authors received no specific funding for this work.
Competing interests: The authors have declared that no competing interests exist.
Introduction
Early childhood caries (ECC) is defined as the presence of a primary tooth with one or more carious (non-cavitated or cavitated lesions), missing (due to caries), or filled surfaces in a child under the age of six years [1]. It is considered one of the most prevalent diseases in childhood, affecting almost half of preschool children worldwide [2]. ECC consequences often include a higher risk of new carious lesions in primary and permanent dentition, hospitalisations and emergency room visits, high treatment costs, loss of school days, diminished ability to learn, and diminished oral health-related quality of life for both children and parents [3]. Literature on ECC preventive strategies assumes that interventions initiated during pregnancy or within the first year of life have a good chance of success [4–6]. However, recently published reviews have concluded that evidence on the effectiveness of early interventions to prevent ECC is inconclusive and that well-designed studies that include more children are needed [7, 8]. This means that studies should take into account the fact that even simple behavioural interventions for the prevention of ECC are often influenced by complex interplays of individual characteristics, social determinants, the health care delivery system, and the interventions themselves and therefore need to be treated as a complex health intervention (CHI’s) [9].
A CHI is characterised by multiple components (intervention complexity), complicated/multiple causal pathways, feedback loops, synergies, mediators, and moderators of effect (pathway complexity). In addition, they may have population complexity (target multiple participants, groups, or organisational levels), implementation complexity (require multifaceted adoption, uptake, or integration strategies), and/or contextual complexity (work in a dynamic multidimensional environment) [9]. Due to interacting mechanisms and components, contradictory effects are often found when a CHI is implemented under various circumstances. Therefore, evaluating the effects of CHI’s is challenging, and a specific multifaceted approach is required. Recent systematic reviews on this topic have included studies that meet the definition of CHI but are relatively straightforward with a classic reductive approach that is efficacy-focused without considering the complex interplays of an intervention [7, 8]. Instead of focusing only on the effectiveness of interventions, more emphasis should be placed on “how”, “for whom”, and “under what conditions an intervention can work” [9]. For those interested in adopting published interventions from reviews, more details are necessary to understand whether an intervention is feasible and which components are likely to work in their context, with their population and at what cost [9].
Since the introduction of the Medical Research Council framework in 2000 [10], there has been increasing interest in developing and evaluating CHI’s. In the meantime, several frameworks and guidelines have become available for the development, evaluation, implementation and reporting of CHI’s to enhance replication and reduce research waste [11–13]. While the field of CHI matures, this is still a relatively unknown domain in preventive oral health care. Given the inconclusive findings and recommendations of recent reviews, it would be highly relevant to assess the details of the development, evaluation, and implementation of interventions to prevent ECC and provide a direction for future study designs. A preliminary search of PubMed, Embase, PROSPERO, JBI Evidence Synthesis, and Open Science Framework revealed no current or underway systematic reviews or scoping reviews regarding the prevention of ECC that combine insights from frameworks and guidelines on the development, evaluation, implementation, and careful reporting of interventions. Therefore this scoping review aims to map CHI’s to prevent ECC that starts during pregnancy or in the first year of life, explore its complexity and the description of relevant aspects of the development, evaluation, and implementation. Outcomes of this scoping review may provide a direction for better design of studies on complex health interventions to prevent ECC and complete information for those who want to adopt successful interventions.
Material and methods
The proposed scoping review will be conducted following the Joanna Briggs Institute (JBI) methodology for scoping reviews and reported using the Preferred Reporting Items for Systematic Reviews and Meta-analysis extension for Scoping Reviews (PRISMA-ScR) [14, 15].
Review questions
The Population-Concept-Context framework was used to identify the main concepts in the primary review question and inform the search strategy (Table 1). The primary review question is:
“Which complex health interventions to prevent early childhood caries are described in the literature, how complex are they and what is known about their development, evaluation and implementation?” A sub-question to this will be, “Are there similarities in described and non-described aspects of the development, evaluation, and implementation of complex health interventions to prevent ECC?”
Inclusion criteria
Population.
This review will consider CHI’s to prevent ECC, including pregnant women, parents, and/or primary caregivers. The CHI’s must have started during pregnancy or in the first year of the child’s life and must not be a one-time intervention.
Concept.
The central concept of this scoping review is to explore the development, evaluation, and implementation of the identified CHI’s to prevent ECC. Therefore this review will extract descriptive data on items regarding the development (i.a., the problem definition, the underlying theory of the intervention, need identification of interventionists or receivers and pilot/feasibility tests), evaluation (i.a., the description of primary and secondary outcomes, cost-effectiveness analysis, process evaluation and intervention fidelity), and implementation (i.a., the reporting on modification and adaptations, training of interventionists and the materials used). For all items, the description level will be examined (i.e. fully described, partially described or non-described), and similarities in described and non-described aspects will be sought in relation to particular study or intervention characteristics, such as the level of intervention complexity. To identify and select suitable CHI’s to be included in this review, the consolidated definition of complex interventions will be used as proposed by Guise et al. (2017) [9].
Context.
This review will consider interventions from all settings and contexts in which a CHI to prevent ECC is implemented and evaluated. Studies will be included regardless of country of origin or sociocultural setting. The comparison conditions for CHI’s can be usual oral healthcare, no oral healthcare, standard oral health advice (e.g. educational flyers, providing toothbrushes, watching short films), or other interventions with pregnant women or primary caregivers of infants in the first year of life.
Types of sources.
The first step is identifying CHI’s to prevent ECC initiated during pregnancy or in the first year of life. Only CHI’s evaluated in clinical trials will be included in the screening and selection process. Clinical trials are defined as clinical studies in which participants are assigned to receive one or more interventions so that researchers can evaluate the interventions in terms of biomedical or health-related outcomes [16]. In order to avoid missing any relevant information, all “sibling” publications (i.e. multiple publications on the study or intervention) of an included CHI that describe the development, evaluation, or implementation will be incorporated. These publications can be of all types of study methodology (e.g. qualitative, quantitative, or mixed methodology). However, only the studies published in English will be included.
Search strategy
The search strategy for this scoping review follows the three-step search strategy recommended by JBI [14]. First, an initial limited search was undertaken in 2019 in PubMed to identify relevant articles. Then, text words contained in the titles and abstracts of relevant articles, the MeSH terms describing the articles, and a search hedge for children (0–4 years) drafted by Ket [17] were used to develop a complete search strategy in consultation with a medical information specialist (KAZ) (S1 File). The databases to be searched include PubMed, Embase, Clarivate Analytics/Web of Science Core Collection, ClinicalTrials.gov, and Wiley/Cochrane Library. The search strategy will be adapted for these databases and other information sources, including all the identified keywords and index terms. No methodological search filter on study design or date that would limit the results will be used in the search strategy. Finally, the reference list of all included studies will be screened for additional CHI’s or sibling publications with additional information about the CHI’s development, evaluation, or implementation. The sources of grey literature to be searched include the registration of included CHI’s in clinical trial registers (e.g. ClinicalTrials.gov).
Study selection
Following the search, all identified citations will be collated and uploaded into EndNote v.X20.01 (Clarivate Analytics, PA, USA). Duplicates will be removed using the Amsterdam Efficient Deduplication and Bramer methods [18, 19]. Two independent reviewers will perform screening and selection procedures (MLCMO and PCJMvS). ASReview will be used to rank potentially relevant titles and abstracts using an active learning algorithm to determine the threshold for manual screening [20]. Simultaneously, this is the initial pilot test and norm-finding of the title and abstract screening criteria. Subsequently, potentially relevant titles and abstracts will be screened independently by MLCMO and PCJMvS for eligibility using Rayyan [21]. Full-text articles will be screened when judging eligibility criteria based on the title and abstract is impossible. Following a pilot test and norm-finding for the full-text selection criteria of at least two publications, the full text of the selected citations will be assessed in detail against the inclusion criteria by two independent reviewers. The scoping review will record and report the reasons for excluding sources of evidence at the full-text stage that do not meet the inclusion criteria. During the selection process, any disagreements between the reviewers will be resolved through discussion or by an additional reviewer (LCS). The search results and study inclusion process will be reported in the final scoping review and presented in a PRISMA-ScR flow diagram [15].
Data extraction
Two reviewers (MMCMO and PCJMvS) will perform data charting of the papers included in the scoping review. The reviewers adapted, and pilot tested the JBI data charting template to record essential information about the source (S2 File). The charted data will include specific details about the study, participants, concepts (e.g. type of intervention and control), context (e.g. study setting), methods, and key findings relevant to the review questions. Charting these results may lead to unforeseen but valuable data. Therefore, charting the results will be an iterative process whereby the charting table can be continually updated. Descriptive data will be extracted based on the Intervention Complexity Assessment Tool for Systematic Reviews [22] to describe the complexity of the included CHI’s. In addition, this study will use a 39-item scoring instrument composed of several frameworks for developing and evaluating CHI’s. This scoring instrument covers the phases of the Medical Research Council framework. It will be used to explore the development (including feasibility and piloting), evaluation, and implementation of the included interventions in more depth. This 39-item instrument is based on the scoring instrument developed by Smit et al. (2018) [23]. In recent years, the implementation phase has gained more attention within intervention research, and items covering this phase were lacking in the instrument of Smit et al. (2018) [23]. Therefore, items regarding implementation theories, models, and frameworks used to develop and evaluate CHI’s are added to the instrument [24–28]. A draft extraction form is provided for the adapted instrument (S3 File). The reviewers (MMCMO and PCJMvS) will pilot the draft extraction form with two interventions and modify and revise it as necessary while extracting descriptive data on each of the 39 items from the included evidence sources. It is then assessed whether all items are fully, partially or non-described. The modifications will be detailed in the scoping review. Any disagreements between the reviewers (MMCMO and PCJMvS) will be resolved through discussion or by an additional reviewer (LCS).
Data analysis and presentation
The presentation of the results will include at least an overview of the identified CHI’s alongside study characteristics and the level of complexity. Furthermore, according to common frameworks, the extent to which CHI’s development, evaluation, and implementation are described according to common frameworks will be visually presented per phase in a co-occurrence matrix. This matrix helps identify gaps and similarities in described and non-described aspects in the description of CHI’s development, evaluation, and implementation. In addition, other visual outputs will be considered during the analysis. Finally, all tables and visual outputs will complement the narrative summary in response to the review questions.
Discussion
The proposed scoping review aims to map CHI’s to prevent ECC that start during pregnancy or in the first year of life, explore its complexity and the description of relevant aspects of the development, evaluation, and implementation. The outcomes of this scoping review should provide an overview of published complex oral health interventions to prevent ECC, including their level of complexity. Furthermore, gaps may be identified by exploring the development, evaluation and implementation details. Finally, similarities in described and non-described aspects can be made visually in a co-occurrence matrix.
Getting more insight into apparently simple interventions’ level of complexity may create more awareness of the difficulties it brings with them. In addition, the outcomes of this scoping review may provide a direction for the future design of studies on complex interventions to prevent ECC and complete information for those who want to adopt successful interventions.
Supporting information
S1 File. Initial search strategy developed for Pubmed.
https://doi.org/10.1371/journal.pone.0275501.s002
(DOCX)
S3 File. Data extraction form for the 39-item scoring instrument.
https://doi.org/10.1371/journal.pone.0275501.s004
(DOCX)
References
- 1. Early childhood caries: IAPD Bangkok declaration. Int J Paediatr Dent. 2019;29(3):384–386. pmid:31099129
- 2. Uribe SE, Innes N, Maldupa I. The global prevalence of early childhood caries: A systematic review with meta‐analysis using the WHO diagnostic criteria. Int J Paediatr Dent. 2021 Nov;31(6):817–30. pmid:33735529
- 3.
American Academy of Pediatric Dentistry. Policy on early childhood caries (ECC): Consequences and preventive strategies. The Reference Manual of Pediatric Dentistry. Chicago, III.; American Academy of Pediatric Dentistry; 2021:81–4.
- 4. Jamieson L, Smithers L, Hedges J, Parker E, Mills H, Kapellas K, et al. Dental disease outcomes following a 2-year oral health promotion program for Australian aboriginal children and their families: A 2-arm parallel, single-blind, randomised controlled trial. EClinicalMedicine. 2018 Jul;1:43–50. pmid:31193658
- 5. Jamieson LM, Smithers LG, Hedges J, Aldis J, Mills H, Kapellas K, et al. Follow-up of an intervention to reduce dental caries in indigenous Australian children: A secondary analysis of a randomised clinical trial. JAMA Network Open. 2019 Mar 1,;2(3):e190648.
- 6. Åstrøm AN, Smith ORF, Sulo G. Early‐life course factors and oral health among young Norwegian adults. Community Dent Oral Epidemiol. 2021 Feb;49(1):55–62. pmid:32918289
- 7. Soares RC, Rosa SV, Moysés ST, Rocha JS, Bettega PVC, Werneck RI, et al. Methods for prevention of early childhood caries: Overview of systematic reviews. Int J Paediatr Dent. 2021 May;31(3):394–421. pmid:33263186
- 8. Riggs E, Kilpatrick N, Slack‐Smith L, Chadwick B, Yelland J, Muthu MS, et al. Interventions with pregnant women, new mothers and other primary caregivers for preventing early childhood caries. Cochrane Database Syst Rev. 2019 Nov 20;2019(11):CD012155. pmid:31745970
- 9. Guise J, Chang C, Butler M, Viswanathan M, Tugwell P. AHRQ series on complex intervention systematic reviews-paper 1: An introduction to a series of articles that provide guidance and tools for reviews of complex interventions. J Clin Epidemiol. 2017 Jul;90:6–10. pmid:28720511
- 10. Campbell M, Fitzpatrick R, Haines A, Kinmonth AL, Sandercock D, Spiegelhalter P, et al. Framework for design and evaluation of complex interventions to improve health. BMJ. 2000 Sep;321(7262):694–696. pmid:10987780
- 11. Möhler R, Köpke S, Meyer G. Criteria for reporting the development and evaluation of complex interventions in healthcare: Revised guideline (CReDECI 2). Trials. 2015 May;16(1):204. pmid:25935741
- 12. Craig P. A new CONSORT extension should improve the reporting of randomised pilot and feasibility trials. J Clin Epidemiol. 2017;84:30–32.
- 13. Hoffmann TC, Glasziou PP, Boutron I, Milne R, Perera R, Moher D, et al. Better reporting of interventions: Template for intervention description and replication (TIDieR) checklist and guide. BMJ. 2014 Mar 7;348:g1687. pmid:24609605
- 14.
Peters MDJ, Godfrey C, McInerney P, Munn Z, Tricco AC, Khalil H. Chapter 11: Scoping Reviews. In: Aromataris E., Munn Z, editors. JBI Manual for Evidence Synthesis [internet]. Adelaide, JBI; 2020 [cited 2022 March 1].
- 15. Tricco AC, Lillie E, Zarin W, O’Brien KK, Colquhoun H, Levac D, et al. PRISMA extension for Scoping Reviews (PRISMA-ScR): checklist and explanation. Ann Intern Med 2018;169(7):467–73. pmid:30178033
- 16.
National Institutes of Health. NIH’s definition of a clinical trial. [Internet]. National Institutes of Health. [cited 2022 March 1]. Available from: https://grants.nih.gov/policy/clinical-trials/definition.htm#.
- 17.
Ket JCF. Search hedge for children (0–4 years). [Internet] Koninklijke Nederlandse Vereniging voor Informatieprofessionals. [cited 2021 Nov 2]. Available from: https://blocks.bmi-online.nl/catalog/58.
- 18. Otten R, Vries RD, Schoonmade L. Amsterdam efficient deduplication (AED) method (Version 1).[Internet] 2019.[cited 2021 Nov 2]. Available from: https://search.datacite.org/works/10.5281/zenodo.4544315.
- 19. Bramer WM, Giustini D, de Jonge GB, Holland L, Bekhuis T. De-duplication of database search results for systematic reviews in EndNote. J Med Libr Assoc. 2016;104(3):240–243. pmid:27366130
- 20. van de Schoot R, de Bruin J, Schram R, Zahedi P, de Boer J, Weijdema F, et al. An open source machine learning framework for efficient and transparent systematic reviews. Nat Mach Intell. 2021;3(2):125–133.
- 21. Ouzzani M, Hammady H, Fedorowicz Z, Elmagarmid A. Rayyan-a web and mobile app for systematic reviews. Syst Rev. 2016;5(1):210. pmid:27919275
- 22. Lewin S, Hendry M, Chandler J, Oxman AD, Michie S, Shepperd S, et al. Assessing the complexity of interventions within systematic reviews: Development, content and use of a new tool (iCAT_SR). BMC Med Res Methodol. 2017;17(1):76. pmid:28446138
- 23. Smit LC, Schuurmans MJ, Blom JW, Fabbricotti IN, Jansen APD, Kempen GIJM, et al. Unravelling complex primary-care programs to maintain independent living in older people: A systematic overview. J Clin Epidemiol. 2018;96:110–119. pmid:29289764
- 24. Wiltsey Stirman S, Baumann AA, Miller CJ. The FRAME: An expanded framework for reporting adaptations and modifications to evidence-based interventions. Implement Sci. 2019;14(1):58. pmid:31171014
- 25. Nilsen P. Making sense of implementation theories, models and frameworks. Implement Sci. 2015;10:53. pmid:25895742
- 26. Skivington K, Matthews L, Simpson SA, Craig P, Baird J, Blazeby JM, et al. A new framework for developing and evaluating complex interventions: Update of medical research council guidance. BMJ. 2021;374:n2061. pmid:34593508
- 27.
Craig P, Di Ruggiero E, Frohlich KL, Mykhalovskiy E, White M, Campbell R, et al. Taking account of context in population health intervention research: Guidance for producers, users and funders of research. [Internet] Canadian Institutes of Health Research (CIHR)–National Institute for Health Research (NIHR) Context Guidance Authors Group. Southampton: National Institute for Health Research. [cited 2022 March 1]. Available from: https://doi.org/10.3310/cihr-nihr-01.
- 28. O’Cathain A, Croot L, Duncan E, Rousseau N, Sworn K, Turner KM, et al. Guidance on how to develop complex interventions to improve health and healthcare. BMJ open. 2019;9(8):e029954. pmid:31420394