- 1Dental Education Program, Faculty of Dentistry, Universitas Padjadjaran, Bandung, Indonesia
- 2Department of Pediatric Dentistry, Faculty of Dentistry, Universitas Padjadjaran, Bandung, Indonesia
Objective: This review aims to determine the two-way relationship between stunting and ECC in developing countries worldwide.
Methods: The procedure in this study was carried out using the Preferred Reporting Items for Systematic Reviews and Meta-Analysis-Rapid Review protocol. Article searches were carried out using databases Cochrane and PubMed. In addition, searches were also carried out using backward and forward snowballing techniques to identify articles that were not detected through database searches.
Results: Nine observational epidemiological articles were found in children aged six months to six years, published in 2015–2020. Five articles discussed the features of ECC in stunted children, and the other five discussed stunting in children with caries in their primary teeth.
Conclusion: Several studies found associations between severe ECC and stunting, with ECC and stunting as both independent and dependent variables, suggesting a bi-directional relationship, also supported by literature on the physiological relationship between oral health and nutrition.
1 Introduction
Currently, malnutrition is a formidable global challenge, directly or indirectly linked to mortality and disability (1). Various forms of malnutrition, such as wasting, underweight, and stunting, afflict populations worldwide. Among these, stunting is most prevalent among children under five, especially in developing nations, where approximately 80% of cases occur (2, 3). In 2018, the global tally of stunted children under five reached a staggering 149 million, with most cases concentrated in Asia, accounting for 81.7 million instances (4).
In this global concern, it is essential to zoom in on Indonesia. According to the 2021 Indonesia Nutrition Status Study, there has been a notable decrease in the stunting rate, from 27.7% in 2019 to 24.4%, which is a promising trend despite the challenges posed by the COVID-19 pandemic (5). However, this figure, though improving, remains significantly high, necessitating continued efforts for reduction, particularly in alignment with the initial two targets of the Sustainable Development Goals (SDGs) aimed at eradicating poverty, hunger, and malnutrition. The Indonesian government has undertaken several commendable initiatives to combat extreme poverty, setting a target of 0 % by 2024. While many of these programs have yielded positive results in the context of malnutrition, few have addressed oral health concerns, which also bear significant importance in the fight against malnutrition (6, 7). In Indonesia, child oral health remains a neglected aspect of child health and malnutrition programs. Remarkably, comprehensive Lancet series reports in 2003, 2008, 2013, and 2021 did not include oral health and dental caries discussions. This underscores the urgent need for child health and malnutrition initiatives to incorporate oral health promotion and caries treatment into their strategies, ultimately enhancing child nutrition status.
Stunting, a distinct manifestation of malnutrition in children, is characterised by chronic and inadequate growth in height and length. Unlike wasting, which primarily affects weight and muscle mass, or underweight, which focuses on low body weight for age, stunting is related explicitly to linear growth retardation. This condition has several clinical symptoms, including reduced body mass, weakened muscles, inhibited intellectual development, impaired wound healing, increased susceptibility to infections, and compromised immune function (8–10).
Furthermore, the repercussions of stunting are not confined to physical health alone. They extend to oral health, with stunted children often presenting with dental caries on their primary teeth. This multifaceted impact underscores the importance of understanding and addressing stunting within the broader context of child malnutrition.
Early Childhood Caries (ECC), or primary tooth caries, is a condition characterized by one or more decayed teeth or tooth surfaces, tooth loss resulting from decay, or teeth restored in children under six (11). According to Global Burden of Disease 2017 data, it is estimated that over 530 million children worldwide are affected by caries in their primary teeth (12, 13). Research indicates that ECC is more prevalent among malnourished children than those with adequate nutrition. This is primarily because chronic malnutrition can impede proper tooth development, leading to reduced enamel thickness and a weaker tooth structure due to disrupted ameloblast activity during the amelogenesis process (6, 14–16).
In addition to malnutrition, the lack of evidence-based oral hygiene habits also plays a significant role in the development of ECC. Inadequate tooth brushing with fluoride toothpaste, infrequent dental check-ups, and suboptimal oral hygiene practices contribute to the accumulation of plaque and bacteria on teeth, which can lead to the onset and progression of caries in primary teeth. Therefore, promoting evidence-based oral hygiene habits from an early age, such as regular brushing with fluoride toothpaste, is crucial in preventing ECC and ensuring the overall oral health of young children (6, 14–16).
Not only does research suggest that stunting impacts the severity of caries in children, but several other studies have also shown that the relationship between stunting and ECC is bidirectional. This statement means that the severity of caries can increase the risk of children experiencing malnutrition (17). This rapid review aims to analyze this two-way relationship between stunting and early childhood caries to provide valuable information for relevant government agencies when formulating policies related to stunting and oral health.
2 Materials and methods
Rapid reviews, while not bound by the strict protocols of traditional systematic reviews like PICOS and PRISMA, should nonetheless uphold transparency and rigour. To achieve this, we have adopted a modified approach, incorporating elements from PRISMA-RR and adhering to the essence of the PICOS framework (18–20). By doing so, we aim to maintain the quality and clarity of our rapid review, despite its inherent constraints.
In defining our review objectives more clearly, our primary aim is to inform and contribute to health policy development in Indonesia. To address this, we have laid out specific inclusion criteria that reflect the uniqueness of our research focus. Our Population (P) encompasses children aged 0–5 years in early childhood. The Intervention (I) examines the relationship between two conditions, where one condition serves as an “exposure.” In this context, exposure pertains to growth stunting, akin to an “intervention” in traditional terms. The Comparison (C) is drawn from children without growth stunting or, conversely, those without early childhood caries. Our Outcome (O) is centred on the development of early childhood caries or growth stunting. Finally, we have specified that our Study design (S) will involve observational studies, including cohort, case–control, and cross-sectional studies.
Furthermore, to provide a more comprehensive rationale for our choice of rapid review methodology, we have emphasised that our objective is to facilitate specific policy recommendations for Indonesia. This thematic approach serves as a unifying thread throughout our research. In light of this, we will ensure that this theme is prominently featured in the discussion section, reinforcing the connection between our rapid review and its policy implications for Indonesia.
2.1 Study selection
This study’s inclusion criteria were articles with an analytical epidemiological study design, including all type of observational studies, that discussed the relationship between stunting and ECC in developing countries. These articles had to be published in English between 2012–2020 and use the def-t index to assess caries in children’s teeth. Descriptive studies, review articles and grey literature were excluded from this review. Grey literature refers to published and unpublished materials and is typically found in higher education institutions/libraries such as university libraries, institutes, high schools, academies, and polytechnics.
2.2 Search strategy
Search using the PRISMA-RR protocol (Preferred Reporting Items for Systematic Reviews and Meta-Analysis-Rapid Review) (18, 21), an article search strategy through databases such as Scopus and PubMed. The keywords used are “Malnutrition,” “Undernutrition,” “Nutritional Status,” “Stunting,” “Early Childhood Caries,” “Caries,” “Tooth Decay,” “Children,” “Child,” and “Preschool Children” which are then combined using the boolean operators “AND” and also “OR.” In addition, a list of articles that cite selected articles (forward snowballing) and a list of references (backwards snowballing) (22) also checked for articles that needed to be detected when searching through the database using the boolean operator.
2.3 Data extraction
After obtaining articles that match the inclusion criteria, data such as title, author, year of publication, research objectives, country, and research methodologies such as study design, sample, variable measurement indicators, research results and research conclusions are extracted and presented in tabular form.
2.4 Quality assessment
The quality of the selected articles was assessed by two reviewers using the NIH Quality Assessment Tools (23), of which the assessments were in the form of a questionnaire. Each assessment question is answered using the code ‘Y’ for yes, ‘N’ for no, ‘CD’ for cannot determine, ‘NR’ for not reporting, or ‘NA’ for not applicable. For the final assessment, each article is assessed using a rating category such as “good,” “average,” or “poor.” The differences of opinion between reviewers will be discussed further until a mutual agreement is reached.
2.5 Data synthesis
The quantitative narrative review approach is applied as a data synthesis strategy. A more intuitive systematic review refers to a summary and then includes a synthesis of the results of various studies with quantitative data using words (24). In this review, the presentation of data is grouped into two: articles with stunting as the independent variable and articles with ECC as the independent variable.
3 Result
3.1 Search result through the database
After an initial search through two databases, 286 articles were found in PubMed, and another 394 were from Scopus. These articles were then removed by duplication so that there were 442 articles remaining. Furthermore, screening was carried out based on the title and 140 articles, which were then examined by abstracts. One hundred twenty-two articles had to be extracted because they did not meet the inclusion criteria, leaving 21 eligible for the overall review process. Of the 21 articles that have been reviewed as a whole, 12 articles did not meet the requirements, leaving nine articles for further review (Figure 1).
3.2 Search with the snowballing technique
Of the eight articles obtained through a database search, each was thoroughly examined, including the list of references and the articles cited. Following the search, we identified an additional 13 articles. Subsequently, we eliminated duplicate entries among these 13 articles, resulting in 11 unique articles. Of these 11 articles, only three met the criteria for a full-text review, and just one additional article met the inclusion criteria for further consideration in our research process.
3.3 Study characteristics
3.3.1 Country and study design
A summary of the research findings can be seen in Table 1. Based on the country where the research took place, the continent of Asia was the area that produced the most articles (25, 29–33), followed by the continent of South America (26, 28), and the African continent (27, 34). Out of ten articles, only three did not use cross-sectional as the study design but used longitudinal and quasi-experimental studies (28, 31). The longitudinal and quasi-experimental studies reported a two-way relationship between stunting and ECC.
3.3.2 Relationship of ECC in stunted children
Five articles discussed the relationship between ECC (the dependent variable) in children with stunting (the independent variable), with two statistical reporting estimates of the association between the two variables (27, 31). It is also known that four articles are cross-sectional studies, and one is longitudinal. In addition, the four articles show varying numbers for the number of samples, ranging from 82 to 1,575 children (25–28).
3.3.3 Stunting relationship with ECC
Three cross-sectional studies (30, 32, 33) and two longitudinal study (29, 31) investigated the description of stunting cases (the dependent variable) as measured using HAZ-scores in children with ECC cases (the independent variable), with a sample range from 273 to 1,307 children. Of the five articles, only one article reported statistical estimates regarding the relationship between stunting and ECC (31).
3.3.4 Quality of studies
From the assessment results of the two reviewers, it was found that six articles had good ratings (26–31), two articles had average ratings (32, 33), and one other article had a poor rating because of statistical methods, data collection methods, and confounding variables were not taken into account (Table 1) (25).
4 Discussion
This study is the first rapid review exploring the bidirectional relationship between stunting and Early Childhood Caries (ECC) in developing countries. The findings of our review reveal a compelling connection between stunting and ECC, with four articles demonstrating a significant relationship between these two variables (25, 27–29, 31). Malnutrition among children can reduce the intake of essential micronutrients, such as vitamins A and D, calcium, phosphorus, iron, and other crucial proteins. Both macro-and micronutrient deficiencies can impact the function of salivary glands, resulting in changes in saliva composition. These alterations can disrupt the remineralisation process and perpetuate the demineralisation process, ultimately leading to dental caries in children’s teeth (25, 27, 31). Additionally, socioeconomic factors and parental knowledge about nutrition and oral health also play a role in caries development among stunted children (25, 35, 36).
Study on the analysis that carried out by comparing specific categories of malnutrition (stunting, wasting, underweight, obesity) with children who did not experience any of these categories by Folayan et al. (27) resulted that there was no bidirectional relationship between stunting and ECC. Another study reports the results of Vieira’s research, which also states that stunting is not related to the occurrence of caries in children but is influenced by other confounding factors, which are risk factors for the two variables, both stunting and ECC (26).
In a cross-sectional study by Tsang et al. of children aged 6 months to 6 years in Nepal, the severity of caries assessed using the DMFT index has a relationship with the tendency of children to experience mouth pain and malnutrition, both chronic (stunting) and acute (wasting) (32). A quasi-experimental study of prevention intervention for early childhood caries in Ecuador by Sokal-Guiterrez et al. demonstrated reduction in caries and stunting, particularly in children who began the intervention in the first two years of life (28). This happens because several cases of malnutrition in this population are related to the target of the intervention factors, namely the frequency of consumption of junk food, S-ECC, which involves acute and chronic infection or inflammation, and also sore mouth. Of the three groups that had been given the intervention, the children with moderate caries development benefited the most from this intervention because children can experience caries-related malnutrition. Whereas in the children with low caries development, the prevalence of malnutrition was high from the start, and the average HAZ-score did not improve because children in this group may suffer from malnutrition unrelated to caries. An association between malnutrition and caries can occur even though the association is not statistically significant. S-ECC in children can affect the child’s ability to sleep, interfere with sleep quality, cause loss of appetite, and accelerate the adverse effects of other risk factors on nutritional status through infection or chronic inflammation (31).
In a cross-sectional study by Zahid et al. of children aged 6 months to 12 years in Nepal, S-ECC shows no statistically significant association with the risk of malnutrition in the group of children under six years as measured by the dmft index, but a relationship is found in the group of children aged 6–12 years whose caries is measured using the SiC index (Significant Caries Index) and in the entire population (age six months to less than 12 years) as measured by the pufa+PUFA index (30). The average HAZ score did not have a significant difference based on the severity of dental caries measured using the dmft index. The relationship between low HAZ-score was only found in children with caries depth that reached the pulp compared to children who did not have caries. Their research also found that caries severity was unrelated to stunting; caries had a significant relationship with wasting and being underweight. According to the authors, stunting is related to maternal malnutrition and malnutrition in children under two years of age. Meanwhile, wasting is associated with malnutrition at all ages, including in children over two years old (33).
In Renggli et al. 1-year longitudinal follow-up study of children under age 2 at baseline in Cambodia, 14.4% had severe dental caries, and 25.6% presented with stunted growth. After a year follow-up, 17.6% of the children transitioned from healthy to low height-for-age over the observation period. Children with severe dental caries had nearly double the risk (OR = 1.8; CI 1.0–3.0) of making that transition. Severe caries experience was associated with poorer childhood growth and, as such, could be an underinvestigated contributor to stunting. The study highlights the need to prevent and treat early childhood tooth decay as a vital part of programs to prevent child undernutrition and NCDs and promote optimal growth and development during a critical stage of life (29).
5 Strength and limitation
The same goes for this rapid review, which has some limitations. First, almost the entire review process is performed by a single reviewer, which increases the risk of bias. Literature may be ignored when searching for articles using only two databases. Furthermore, introducing language restrictions limited to English also risks overlooking essential lessons to be learned from articles published in other languages. Despite its limitations, the review has the strength of meeting high methodological standards as it assessed the quality and risk of bias of the studies. In addition, this review provides essential information on the relationship between developmental delay and ECC, which can serve as input for dentists and health system policymakers in developing strategies to improve children’s dental and oral health and nutritional status. Implications for future research: The study is hoped to be conducted with more detailed and precise methods and longitudinal study designs involving large populations.
6 Conclusion
The literature review reveals substantial evidence supporting a bidirectional relationship between severe Early Childhood Caries (ECC) and stunting in children. This complex interplay is evident in both longitudinal and cross-sectional studies, although it’s important to note that most of the included studies are cross-sectional, limiting the establishment of definitive causal relationships. The observed bidirectional relationship aligns with existing research on the physiological mechanisms connecting poor oral and nutritional health.
In summary, this review concludes that there is a compelling basis to consider a bidirectional relationship between severe ECC and stunting in children. It underscores the need for further research employing rigorous study designs to investigate causation more definitively. Additionally, interventions addressing both oral and nutritional health are warranted to mitigate the potential adverse effects of this relationship on child development and well-being.
Data availability statement
The raw data supporting the conclusions of this article will be made available by the authors, without undue reservation.
Author contributions
AS conceived the research idea, designed the study, and was responsible for coordinating the data collection process. She played a key role in revising and editing the manuscript for intellectual content. RI contributed to the refinement of the study design, performed statistical analyses on the collected data, and assisted in interpreting the results. RA conducted an extensive literature review to provide a theoretical background for the study. She also contributed to data analysis, created data visualisations, and helped to shape the paper’s discussion section. She conducted mindfulness meditation sessions with participants and wrote the initial draft of the manuscript. All authors contributed to the article and approved the submitted version.
Acknowledgments
The authors would like to express their sincere gratitude to the Directorate of Research and Community Engagement (DRPM) at Universitas Padjadjaran for their invaluable support in facilitating the submission of this manuscript. The assistance provided by DRPM in coordinating the administrative aspects of the submission process has been instrumental in bringing this research work to fruition. We acknowledge their commitment to promoting academic excellence and research advancement within the university community.
Conflict of interest
The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
Publisher’s note
All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article, or claim that may be made by its manufacturer, is not guaranteed or endorsed by the publisher.
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Keywords: growth stunting, malnutrition, caries, children, bidirectional relationship
Citation: Aulia RN, Indriyanti R and Setiawan AS (2023) The bi-directional relationship between growth stunting and early childhood caries: a rapid review. Front. Public Health. 11:1234893. doi: 10.3389/fpubh.2023.1234893
Edited by:
Santosh R. Patil, Saveetha Medical College & Hospital, IndiaReviewed by:
Karen Sokal-Gutierrez, University of California, Berkeley, United StatesBathsheba Turton, Boston University, United States
Copyright © 2023 Aulia, Indriyanti and Setiawan. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
*Correspondence: Arlette Suzy Setiawan, arlette.puspa@unpad.ac.id