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The Association of Oral Health Status, demographic characteristics and socioeconomic determinants with Oral health-related quality of life among children: a systematic review and Meta-analysis

Abstract

Background

Health-related quality of life (HQoL) indicators are considered valid measures of patient assessment in physical, mental and oral healthcare. This study aimed to examine the evidence on the relationship of oral health status, demographic and socioeconomic characteristics with oral health-related quality of life (OHRQoL) in children.

Methods

Studies in English published up to December 2019 were searched on PsycINFO, PubMed, SciELO, Scopus, and Web of Science databases. Epidemiological studies simultaneously assessing sociodemographic factors related to oral health (age, income, gender, maternal education), oral health measures (orthodontic treatment needs, dental caries and periodontal disease) and OHRQoL in children aged 3–12 years were included. Methodological quality was assessed using a Critical Appraisal Checklist. Meta-analysis was used to estimate pooled measures between sociodemographic factors and oral health measures with OHRQoL.

Results

Eleven articles were included. Lower children’s age (3–5 years vs > 5), gender (girls vs boys), lower income (< 70$ vs ≥ $70), low maternal education (≤ 6 vs > 6 years) were associated with poor OHRQoL among children. Orthodontic treatment needs, dental caries and periodontal diseases were also associated with poor children’s OHRQoL. Meta-regression showed that Human Development Index, sample size, year of publication and participant’s age were relevant aspects that influenced the above mentioned relationships.

Conclusions

Our findings suggest that oral health promotion strategies to improve children’s OHRQoL should consider the social and environmental where they live as well their oral health status. Further longitudinal studies are needed to explore the determinants of OHQoL in children.

Peer Review reports

Background

The use of oral health-related quality of life (OHRQoL) in healthcare along with clinical assessment reflects a shift from normative approach to a patient-centred care perspective in the evaluation of oral health and the efficacy of dental treatment [1, 2]. OHRoL indicators assess different dimensions of oral health status of the impact of oral conditions on physical, emotional, social and psychological aspects on a person’s subjective well-being [1, 3]. Previous research showed that OHRQoL may be influenced by oral health conditions, demographic and socioeconomic characteristics, and contextual factors such as political and cultural aspects [4]. Furthermore, children’s oral health status can affect their well-being and quality of life as well as that of their parents.

Dental caries and periodontal disease are relevant public health problems that account for a considerable proportion of the global burden of oral diseases [5]. The etiology of oral diseases are multifactorial and their distribution and severity of oral diseases in children may vary according to family’s socioeconomic condition [6]. Fisher-Owens and colleagues developed a theoretical framework involving relevant predictors of children’s oral health that were grouped into community- family- and child-level influences [7]. They have shown the importance of socio-behavioral and environmental factors on children’s oral health. Of them, family environment plays a central role in children’s oral health [8].

Environmental and sociodemographic factors can influence OHRQoL in children and other age groups [8, 9]. Age [10], sex [11], socioeconomic status [12,13,14], socio-cultural factors [10, 15, 16], psychosocial factors [17,18,19] were associated with OHRQoL. For instance, income and family structure were significant predictors of children’s OHRQoL, independently of oral diseases [20]. Several studies suggest that oral diseases can impact on children and adolescents OHRQoL [21,22,23,24]. Locker (2007) showed that children from low-income families and those with only one adult in the household were more likely to poor OHRQoL [25]. Children from low-income families also have poor general and oral health than those from better off families [26]. This study aimed to analyze the evidence on the association of oral health conditions (orthodontic treatment needs, dental caries and periodontal disease), demographic and socioeconomic characteristics (age, gender, income, maternal education) with oral health-quality of life in children.

Methods

The present systematic review was performed in accordance with Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) [27, 28].

Eligibility criteria and PECO terms

Epidemiologic studies concomitantly assessing sociodemographic factors related to oral health, oral health measures and children’s OHRQoL in children were included. The PECO tool using the following terms were used: (a) Participants: children aged 3–12 years; (b) Exposures: orthodontic treatment needs, dental caries and periodontal disease, children’s age, gender, family income, maternal education; (c) Comparison: non-children groups; (d) Outcomes: oral health-related quality of life. Only studies reporting quantitative measures and/or dental indices to assess oral health status (e.g. number of decayed, missing, and filled teeth [DMFT] for dental caries) [29], studies assessing OHRQoL through validated questionnaire, those reporting measures of association and published in English were included. In addition, only studies reporting data on severe oral health conditions, such as malocclusion, dental caries and periodontal disease, were considered. Investigations regarding temporomandibular disorders, erosion, or xerostomia were excluded. Studies comparing OHRQoL measures between genders, those considering the family income threshold of 70 $ and maternal education of 6 years of education were included. Only articles reporting coefficients and odds ratios were included. The methodological quality of the studies was also considered as inclusion criteria. Only studies considered of medium or high quality (at least three points on the Critical Appraisal Checklist for observational studies) were included [30].

Search strategy and selection of studies

The search strategy was based on MeSH terms according to PECO terms. Papers published up to December 2019 on PsycINFO, PubMed, SciELO, Scopus, Web of Science, and Cochrane electronic databases were screened for inclusion. Table 1 presents the search strategy, including the combination of key words used in the different electronic libraries. Exclusion of duplicate papers was conducted using EndNote X7 software (Thomson Reuters, New York, NY, USA).

Table 1 search strategy

Initially two researchers (A.B. and B.A.) screened the titles and abstracts of the retrieved papers independently according to the inclusion and exclusion criteria. Any disagreements between the two reviewers were resolved by discussion with a third reviewer (A.M.B.). Potential eligible studies were then assessed in full for inclusion according to eligibility criteria. Additionally, manual searches on the reference list of the selected articles were carried out for identification of additional studies.

Data extraction and quality assessment

The following information was recorded from the selected articles: first author, year of publication, sample size, country, study design, and quality assessment. The authors of the selected papers were contacted to provide further details when necessary.

Five researchers recorded the data independently using predefined excel sheets. First, duplicated titles and abstracts of the selected papers were initially omitted after revision. Second, manuscripts were selected based on titles and abstracts for further review using the full texts. The duplicate papers were identified using “find duplicate” option on endnote software and were deleted. The selection of full text articles was conducted by 5 authors according to the eligibility criteria.

Disagreements between the researchers were resolved by discussion. The Unweighted Kappa used to assess the consistency between the two researchers (B.A. and A.B.) during the selection of studies was 0.86.

Quality assessment

Quality assessment was performed by the same two researchers using the Critical Appraisal Checklist for observational studies proposed by The Joanna Briggs Institute (JBI) to assess the internal validity and risk of bias of the studies [31]. The checklist for cohort, case-control studies and cross-sectional studies are made of 10, 10 and 8 items, respectively. Each item may score one point for the answer “yes” of each study and the score may vary from 0 to 10 (cohort and case-control studies) or 0 to 8 (cross-sectional studies). The papers were categorized as follows: low quality (0–3 scores), medium quality (4–6 scores); and high quality (7–10 scores).

Data synthesis and statistical analysis

The meta-analysis was conducted to estimate pooled Odds Ratios (ORs) and 95% confidence intervals (95% CI) on the relationship of oral health conditions, demographic and socioeconomic characteristics with OHRQoL in children. Heterogeneity between studies was assessed using I2 statistics that is percentage of variation studies [32]. According to I2 index Random and fixed-effect methods were used for estimation pooled effect size in defined subgroups [33]. When I2 indexed is lower than 50%, the fixed effect model but if I2 index is higher than 50%, random effect model used for estimation pooled effect size [33].

The trend of pooled ORs according to country’s Human Development Index [34] (range = 0.761–0.939), sample size (range = 260–1134), year of study and age of participants (range = 3–12 years) was calculated by cumulative regression analysis. HDI data was obtained from World Bank data [35]. Potential publication bias was tested using the rank correlation of Begg’s test and Egger’s test [36, 37]. Publication bias among studies was statistically significant (P < 0.05). Therefore, Meta Trim test was performed to estimate pooled OR to eliminate the publication bias. The level of significance established for all analyses was 5% (P ≤ 0.05). Stata version 13.0 was used in all analyses (Stata Corporation, College Station, TX, USA).

Results

Study selection

Initially, 12,266 papers were identified through database searching and reference lists. Of them, 7428 studies were retained after removing duplicate references using “find duplicate” tool of endnote software. All titles and abstracts were reviewed, and 2586 were considered irrelevant and were excluded. The remaining 4842 articles were evaluated and further 1765 studies were excluded. The full text of the remaining 3077 articles was analysed for inclusion. Of them, 3066 studies were thereafter excluded according to the inclusion criteria. In the end, a total of 11 studies were included in this systematic review and meta-analysis [6, 38,39,40,41,42,43,44,45,46,47].

Figure 1 demonstrates the review process.

Fig. 1
figure 1

PRISMA flow diagram

Study characteristics

The characteristics of the 11 selected studies are presented in Table 2. The sample size ranged from 103 to 1134 participants. Most studies were published between 2009 and 2013 and they predominantly conducted in Brazil. One cohort, one case-control and 9 cross-sectional studies were selected. Of the 11 studies, 6 were considered of high quality.

Table 2 Main characteristics of the studies selected

Meta-analysis

Oral health status and OHRQoL

Orthodontic treatment need and OHRQoL

Three cross-sectional studies evaluated the relationship between orthodontic treatment need and OHRQoL among children [6, 39, 42]. All studies were conducted in upper middle-income countries between 2012 and 2019. The sample size ranged from 286 to 815 and two studies were of high quality. Children with orthodontic treatment need had 13% higher probability of poor OHRQoL than those without orthodontic treatment need (OR = 1.13, 95% CI = 1.07, 1.18) (Fig. 2).

Fig. 2
figure 2

Forest plot of effect of orthodontic treatment need on OHRQoL among children

Dental caries and OHRQoL

The relationship between dental caries and OHRQoL in children was assessed in six studies [41, 43,44,45,46,47]. Of them, five studies were cross-sectional design [43,44,45,46,47], and one used cohort design [41]. Five studies were carried out in upper middle-income country [6, 39, 40, 45, 47] and one was conducted in higher-income country [41]. The studies were published from 2011 to 2017, and the sample size ranged from 260 to 1134. Three studies were of high quality and the other three were of moderate quality. Higher levels of dental caries was associated with poor OHRQoL. Children with more dental caries were 1.66 times more likely to have poor OHRQoL than caries-free children (OR = 1.66, 95% CI = 1.43, 1.88) (Fig. 3).

Fig. 3
figure 3

Forest plot of effect of dental caries on OHRQoL among children

Periodontal disease and OHRQoL

Three cross-sectional studies conducted in upper middle-income countries assessed the association between periodontal disease and OHRQoL among children [39, 46, 47]. They were published from 2010 to 2014, and the sample size ranged from 286 to 1134. All three studies of high quality. Periodontal disease was significantly associated with poor OHRQoL in children (OR = 1.15, 95% CI = 1.12, 1.18) (Fig. 4).

Fig. 4
figure 4

Forest plot of effect of periodontal disease on OHRQoL among children

Demographic and socioeconomic characteristics

Children’s age and OHRQoL among children

Two cross-sectional studies conducted in upper middle-income evaluated the association between low children’s age (3–5 years vs. > 5 years) and OHRQoL [43, 44]. These studies were published from 2011 to 2012, and the sample size ranged from 260 to 638. The two studies were of high quality, and one research was categorized as poor quality. Children aged 3, 4 and 5 years were 2.00, 2.13 and 3.68 times more likely to have poor OHRQoL (OR = 2.00, 95% CI = 1.42, 2.57; OR = 2.13, 95% CI = 1.50, 2.76; and OR = 3.68, 95% CI = 2.20, 5.17) than children with 5 years-old (Figs. 5, 6 and 7).

Fig. 5
figure 5

Forest plot of effect of children aged 3 on OHRQoL among children

Fig. 6
figure 6

Forest plot of effect of children aged 4 on OHRQoL among children

Fig. 7
figure 7

Forest plot of effect of hildren aged 5 on OHRQoL among children

Gender and OHRQoL

Three cross-sectional studies conducted in upper middle-income countries [6, 39, 46] examined the association between gender and OHRQoL among children. The studies were published from 2010 to 2013, and the sample size ranged from 286 to 792. Two studies had high quality. There was a positive association between gender (girls vs. boys) and poor OHRQoL among children. Female children were 1.14 times more likely to have poor OHRQoL than male children (OR = 1.13, 95% CI = 1.09, 1.17) (Fig. 8).

Fig. 8
figure 8

Forest plot of effect of gender on OHRQoL among children

Family income and OHRQoL

Four cross-sectional studies carried out in upper middle-income countries (Brazil) evaluated the relationship between family income and OHRQoL among children. These studies were conducted between 2010 to 2014, and the sample sizes ranged from 286 to 1134 with a high-quality structured approach. All studies considered the threshold of $70 per month to classify the participants as low- (<$70) and high-family income (≥$70). Children from low-income families (< 70$) were 1.16 times more likely to have poor OHRQoL (OR = 1.16, 95% CI = 1.11, 1.21) (Fig. 9).

Fig. 9
figure 9

Forest plot of effect of family income on OHRQoL among children

Maternal education and OHRQoL

Four cross-sectional studies [6, 40, 46, 47] carried out in upper middle-income countries evaluated the association between maternal education and OHRQoL among children. The studies were published from 2010 to 2014, and the sample size ranged from 515 to 1134. Three studies were considered of high quality. Lower maternal education (≤ 6 years of schooling) was significantly associated with poor OHRQoL (OR = 1.12, 95% CI = 1.00, 1.23) (Fig. 10).

Fig. 10
figure 10

Forest plot of effect of maternal education on OHRQoL among children

Assessment of heterogeneity

Heterogeneity between studies was observed on the meta-analysis of dental caries (I2 = 83.5%, P < 0.001), family income (I2 = 51.1%, P = 0.046) and maternal education (I2 = 89.2%, P < 0.001) with OHRQoL. The meta regression analysis showed that country’s HDI (C = 1.45, p value = 0.03), study’s sample size (C = 2.32, p value < 0.001), year of study (C = 1.48, p value < 0.001) and age of children (C = 1.57, p value < 0.001) were significant characteristics that influenced the observed heterogeneities (Fig. 11).

Fig. 11
figure 11

Meta-regression analysis for determine association between poor quality of life with HDI (a), sample size (b) and year of implication (c), children age (d)

Publication bias

Begg’s test and Egger’s tests showed evidence of publication bias (Begg’s test: P < 0.001; Egger’s test: P < 0.001) (Fig. 12). According to publication bias test, a significant publication bias among studies was noted (C = 2.38; P-value = 0.001) (Fig. 12). Therefore, metatrim analysis was performed in order to remove the effect of publication bias on the pooled OR. The meta-trim analysis revolved that the pooled OR 0.17 (95%CI, 0.13–0.21) in the random effect model (Fig. 13).

Fig. 12
figure 12

Determine publication bias by Beggs (a) and Egger’s (b) tests

Fig. 13
figure 13

Meta trim plot for determine pooled OR without publication bias

Discussion

This study aimed to examine the possible relationship of oral health conditions, demographics and socioeconomic characteristics with OHRQoL in children.

Our findings suggest that poor oral health status, greater age, female gender and worse socioeconomic status were significantly associated with poor OHRQoL. These results are in accordance with previous research [43, 48, 49] that showed a correlation between socio-economic status, clinical status and OHRQoL in preschool children [25, 43]. In this study, children’s poor OHRQoL was strongly correlated with lower levels of maternal education (≤ grade 6). Piovesan et al. suggested that low household income was a risk factor for poor OHRQoL in children [46]. Besides, lower paternal and maternal educational level were associated with poor OHQoL of their children [46]. Female gender was also associated with poor OHRQoL, which is in agreement with previous studies [39, 46]. The possible explanation for this finding is the poor self-esteem and poor self-perception of oral health and body image among girls compared with boys [50,51,52]. According to Honkala et al. [53], female gender is significantly correlated with frequency of tooth brushing, and self-esteem among schoolchildren was also associated with a high socioeconomic status of the family. Foster Page et al. [52] reported that gender’s psychosocial characteristics can affect OHRQoL.

Moreover, a negative association between orthodontic treatment need and function limitation dimension of CPQ11–14 was reported. Functional limitation is composed of three items that assesses difficulty in eating and eating hot and cold foods; taken longer to eat a meal; difficulty in biting or chewing firm foods (e.g. apples, corn on the cob, steak); difficulty in opening the mouth wide; problems with pronouncing some words; difficulty with eating favorite foods; difficulty with drinking through a straw [50, 51]. Another research revealed that orthodontic treatment need was associated with poor OHRQoL and dental aesthetics [50].

Bleeding was also significantly related to emotional and social well-being domains of the CPQ11–14. These findings are consistent with those reported by Lopez and Baelum [54] on the association between periodontal disease and poor OHRQoL. Nevertheless, a different OHRQoL instrument (Oral Health Impact Profile OHIP) was used to assess the impact of periodontal diseases on OHRQoL.

Previous studies suggested the poor correlation between dental caries and oral symptoms and functional limitations domains of CPQ [6, 55]. Furthermore, orthodontic treatment need was the only clinical variable associated with OHRQoL [46, 56]. As a result, the orthodontic treatment need was mediated by the individual and socio environmental characteristics.

The reported data highlight the possible significant impact of social interventions and health promotion strategies. Such interventions could be beneficial to support the development of supportive environments for this population. They can also improve their health-related skills to enhance their health status and to decrease health inequalities [4, 25, 46]. Oral symptoms and functional limitations had the most significant impact on oral health conditions in terms of adolescents’ social relationships. (Agou et al.) [51]. According to Marmot and Bell, tackling the social determinants of health, including improving individual living status and structural drivers (e.g. laws, policies, economic conditions and cultural norms that shape and influence patterns of behaviour and individual capacities) are paramount. Furthermore, socio-environmental characteristics significantly affected children’s daily living status [57, 58]. As a result, promoting health status should be conducted for planning health promotion interventions in all social environments in which children live their lives, in order to promote supportive environments for them [59]. Policymakers of the health sector should address oral health at population level by reducing social inequalities.

Limitations

This study has limitations that should be acknowledged. First, the included studies assessed OHRQoL using different questionnaires. Second, OHRQoL instruments might be considered generic questionnaires to assess the relationship between dental clinical measures and children’s OHRQoL, including periodontal disease. Third, articles published in non-English languages were excluded, which may have influence our results. Fourth, the selected articles investigated different predictors of OHRQoL and have used distinct analytical approaches, including univariate and multivariable regression methods. In addition, the categories of the predictors varied significantly between the selected papers, such as those employed to assess maternal education and family income. Therefore, specific inclusion criteria were necessary to include studies with similar methodological approaches in order to perform the meta-analysis. Fifth, some of the papers initially selected were thereafter excluded due to lack of information, as the corresponding author of those articles did not reply our contact to provide the information needed, such as the measures of association (e.g. odds ratio). Finally, the included studies did not inform the validity of the OHRQoL instruments.

Conclusion

In conclusion, socioeconomic conditions, demographic characteristics and dental clinical measures might differently affect oral health-related quality of life among children. Our findings suggest that children aged 3–5 years, female children, those whose families earned less than 70 dollars per month, whose mothers had low education were more likely to poor OHRQoL. In addition, orthodontic treatment need, dental caries and periodontal disease were significantly associated with poor OHRQoL in children.

Considering the need to design and develop oral health strategies to improve children’s oral health, social and environmental conditions where the children live should be considered in planning, implementation and evaluation of oral health promotion activities. Also, further longitudinal studies should be conducted to determine causal relationships between the investigated predictors and OHRQoL.

Availability of data and materials

The datasets used and/or analyzed during the current study are available from the corresponding author on reasonable request.

Abbreviations

QoL:

Quality of life

DMFT:

Decayed, missing and filled teeth

OHRQoL:

Oral health-related quality of life

PRISMA:

Preferred for systematic reviews and meta-analyses

PPD:

Pocket probing depth

CAL:

Clinical attachment level

JBI:

The Joanna Briggs institute

OR:

Odds ratio

CI:

Confidence interval

PSI:

Periodontal screening index

BOP:

Bleeding on probing

TD:

Tooth decay

ECOHIS:

Early childhood oral health impact scale

MT:

Missing teeth

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Acknowledgments

The authors would like to acknowledge the contributions of Mehdi Noroozi to the work of this review of evidence.

Funding

This research did not receive any specific grant from funding agencies in the public, commercial, or not -for -profit sectors. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

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Study design: BA and AB. Database searched, data extraction and data synthesis: BA, AHB, and YF. Initial manuscript draft: BA, EA, and AHB. Critical revision of the manuscript: YF, MVV, M H, AB and LFM. All authors read and approved the final version of the manuscript.

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Correspondence to Bahram Armoon.

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Moghaddam, L.F., Vettore, M.V., Bayani, A. et al. The Association of Oral Health Status, demographic characteristics and socioeconomic determinants with Oral health-related quality of life among children: a systematic review and Meta-analysis. BMC Pediatr 20, 489 (2020). https://0-doi-org.brum.beds.ac.uk/10.1186/s12887-020-02371-8

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