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Background:
Systematic Review

The Correlation between Oral Health and Air Pollution: A Systematic Review

by
Bruna Sinjari
1,*,†,
Manlio Santilli
1,†,
Piero Di Carlo
2,
Eleonora Aruffo
2 and
Sergio Caputi
1
1
Unit of Prostodontics, Department of Innovative Technologies in Medicine and Dentistry, University “G. d’Annunzio” Chieti-Pescara, 66100 Chieti, Italy
2
Center of Advanced Studies and Technology (CAST), University of “G. d’Annunzio” Chieti-Pescara, 66100 Chieti, Italy
*
Author to whom correspondence should be addressed.
These authors contributed equally as first author to this work.
Dent. J. 2024, 12(7), 215; https://doi.org/10.3390/dj12070215
Submission received: 12 June 2024 / Revised: 3 July 2024 / Accepted: 10 July 2024 / Published: 11 July 2024
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Abstract

:
This systematic review assessed to evaluate the potential correlation between oral health and air pollution. To the best of the authors’ knowledge, this is the first systematic review endeavoring to compare air pollution and oral health. A systematic search was performed according to the PRISMA (Preferred Reporting Items for Systematic Reviews and Meta-analyses) statement and employed the PICO(S) approach (Patient or Population, Intervention, Control or Comparison, Outcome, and Study types). The search was limited to English-language articles, and publications within a 15-year timeframe were included in the electronic search. A comprehensive search was conducted across PubMed, Scopus, Embase, and Web of Science databases, spanning the years 2008 to 2023, resulting in a total of 4983 scientific articles. A final selection of 11 scientific papers was made based on their study type and the specific air pollutants examined. The selected papers analyzed various air pollutants associated with health-related diseases, including Ozone, Nitrogen Dioxide, Nitrogen Monoxide, Carbon Monoxide, sulfur dioxide, and particulate matter. Three out of eleven of the reviewed studies assert a strong correlation between air pollutants and oral diseases, specifically periodontitis. However, the exact biological mechanisms underlying this correlation do not seem to be fully understood, indicating the need for further comprehensive investigation in this regard. Dentists can contribute to the collective effort by educating their patients about the oral health implications of air pollution, thereby supporting initiatives aimed at promoting environmental and health sustainability.

1. Introduction

Environmental pollution refers to the release or production of harmful substances or contaminants into the natural environment, such as air, water, or soil, which can have detrimental effects on living organisms and ecosystems. Air pollution, specifically, is a complex mixture of particles and gases that can pose significant risks to human health [1]. It arises from various sources, including industrial emissions, transportation activities, and household practices. The World Health Organization (WHO) estimates that air pollution contributes to approximately 7 million premature deaths worldwide annually [2]. Unfortunately, the European Environment Agency shares this concerning perspective, highlighting the substantial impact of air pollution on the health of the population, particularly in urban areas [3]. Despite notable progress in reducing the emission of primary air pollutants and improving air quality over the past two decades in Europe, thanks in part to the collective efforts toward achieving the 17 Sustainable Development Goals (SDGs) by 2030 [4], many regions still face inadequate air quality. In the previous year, air pollution led to a significant number of premature deaths across the 27 EU Member States (EU-27). Exceeding the World Health Organization’s guideline for the inhalation of fine particulate matter with an aerodynamic diameter of ≤2.5 μm (PM2.5) resulted in 238,000 premature deaths, and exposure to nitrogen dioxide (NO2) levels beyond the recommended limit led to 49,000 premature deaths. Additionally, acute exposure to ozone caused 24,000 premature deaths [2,3]. The gravity of the issue is further emphasized when considering the morbidity effects [2,3].
The WHO has identified PM, NO2, sulfur dioxide (SO2), and ground-level ozone (O3) as the air pollutants with the greatest potential to harm human health [2]. These pollutants have been linked to various health complications, including respiratory and cardiovascular diseases, negative birth outcomes, and neurological disorders [1,5,6]. PM, in particular, is considered highly hazardous in air pollution due to its ability to penetrate deep into the lungs, causing inflammation and tissue damage [1]. Nitrogen oxides (NOx) and SO2, among other pollutants, also have detrimental effects on human health [1,7], contributing to respiratory issues, exacerbating cardiovascular diseases, and even increasing the risk of premature mortality. Moreover, long-term exposure to air pollution has been associated with the development of chronic health conditions such as asthma, lung cancer, and heart disease [1,5,7,8]. These chronic illnesses further highlight the serious implications of sustained exposure to air pollutants. The impact of air pollution on health is particularly significant in vulnerable populations, including children, the elderly, and individuals with pre-existing health conditions [8]. Given the substantial effects of air pollution on health, there is a growing imperative for effective policies and interventions aimed at reducing pollution levels and safeguarding public health. Numerous studies have been conducted over the years to investigate the impact of air pollution on health, focusing on the associated risks [5,7,8,9].
However, there is a noticeable lack of research on the correlation between air pollution and oral health-related pathologies. This represents an intriguing finding that warrants further exploration, considering that inhalation and ingestion are the primary routes of exposure to these air pollutants. It is therefore reasonable to assume a close connection between these pollutants and the oral cavity. However, there is currently a dearth of studies, and notably, no systematic review has been conducted on this specific topic. In this context, dentists can contribute to the collective effort by educating their patients about the oral health implications of air pollution, thereby supporting initiatives aimed at promoting environmental and health sustainability. Consequently, the aim of this literature review is to examine the potential relationship between air pollution and oral health. To the best of the authors’ knowledge, this is the first systematic review endeavoring to compare air pollution and oral health.

2. Materials and Methods

2.1. Study Characteristics

The article selection process for this review followed the guidelines provided by the PRISMA flow diagram, as shown in Figure 1. A comprehensive search was conducted across PubMed, Scopus, Embase, and Web of Science databases, spanning 1 January 2008 to 31 December 2023 (a 15-year timeframe was included), resulting in a total of 4983 scientific articles. To eliminate duplicates, the references of the identified records were uploaded to the digital tool Rayyan (http://rayyan.qcri.org, accessed on 23 May 2023). The systematic review is registered in the International Prospective Register of Systematic Reviews, Prospero, under the identification CRD 42024559844. After duplicate removal, 3477 unique papers remained for further analysis. The titles of these articles were manually reviewed to include relevant references related to the correlation between air pollutants and oral health. Following this screening process, 20 studies were identified as relevant to the topic of air pollutants and their impact on oral health. After that, 9 studies were excluded (did not meet our inclusion criteria); a final selection of 11 scientific papers was made based on their study type and the specific air pollutants examined.

2.2. Search Strategy

This systematic review adhered to the guidelines outlined in the PRISMA (Preferred Reporting Items for Systematic Reviews and Meta-analyses) statement and employed the PICO(S) approach (Patient or Population, Intervention, Control or Comparison, Outcome, and Study types). Extensive literature research was conducted using the databases PubMed (Medline), Embase, Web of Knowledge, and Cochrane Library, focusing on the correlation between air pollution and oral health. The search strategy utilized various combinations of keywords, including “Air pollution” OR “environmental” OR “pollution” AND “dental health” OR “oral health”. The PICO question was formulated as follows: P-population: individuals exposed to air pollution; I-intervention: measures undertaken by dental practitioners to comprehend the relationship between air pollution and oral health; C-comparison: no intervention or standard care; and O-outcome: oral health outcomes associated with air pollution such as dental caries, periodontitis, and related conditions. This question specifically investigates the association between air pollution and oral health, as well as the role of dental practitioners in addressing this issue. The search was limited to English-language articles, and publications within a 15-year timeframe were included in the electronic search.
The research questions of this systematic review were:
  • How many studies have been published on the effects of air pollution on oral health?
  • What methodological characteristics did the paper publish?
  • Which air pollutants were commonly investigated?
  • Is it possible to consider a relation between oral health outcomes and air pollutants?

2.3. Inclusion and Exclusion Criteria

Articles were considered appropriate when satisfying the following inclusion criteria:
  • Articles with main topic regarding the correlation between air pollution and their impact on oral health;
  • Studies performed in vivo;
  • Full-text paper in English;
  • Retrospective study, case-control study, cross-sectional study were included.
Articles that did not have the above information were excluded from the review. Research letters and conference proceedings were excluded. Air pollutant exposure of workers in dental clinic/hospital were excluded.

2.4. Data Extraction and Analysis of the Data

All the relevant data were extracted, including the author’s name, publication year, type of study, pollutants measured, and country and impact of oral health. Specifically, a data abstraction sheet was used, and the accuracy of the information was verified by both B.S. and M.S. (in accordance with all the authors). The investigated pollutants were classified as follows:
Gaseous/air pollutants (such as O3 = Ozone; NO = Nitrogen Monoxide; NO2 = Nitrogen Dioxide; SO2 = Sulfur Dioxide; CO = Carbon Monoxide) and particulate matter (i.e., PM10, PM2.5).

3. Results

The 11 selected papers analyzed various air pollutants associated with health-related diseases, including Ozone, Nitrogen Dioxide, Nitrogen Monoxide, Carbon Monoxide, sulfur dioxide, and particulate matter. Notably, particulate matter with an aerodynamic diameter of ≤10 μm diameters (PM10) and PM2.5 were included in the analysis, as outlined in Table 1. The studies underwent quality assessment utilizing the QUADAS-2 tool, as outlined in Table 1. All publication were classified as having a high risk of bias (Table 2).
How many studies have been published on the effects of air pollution on oral health?
Upon conducting a systematic review, it was found that the initial study exploring the association between oral health and air pollution was published in 2008 in Taiwan. That study specifically investigated the correlation between oral cleft lip, either with or without palate and air pollution. Out of the total of eleven studies reviewed, a significant association between maternal exposure to air pollution and oral clefts was observed in seven studies. However, the primary focus of the authors was to primarily examine pathologies directly related to the oral cavity and within the domain of dental expertise. The first study establishing a relationship between periodontitis and air pollution was published in 2014. Among the eleven studies analyzed, three studies demonstrated an association between periodontitis and air pollution. This finding is summarized in Table 1, indicating an increasing over the past five years in publications suggesting a correlation between periodontitis and air pollution within the last decade. Only one out of the eleven studies reviewed addressed the correlation between oral cancer and air pollution.
What methodological characteristics did the paper publish?
The methodological characteristics are presented in Table 3.

Geographical Distribution

Concerning the geographical distribution, data pertaining to the correlation between air pollution and oral health have been published by institutions in various countries across the globe. The studies included in this systematic review specifically originate from Taiwan (n = 4), the United States (n = 3), China (n = 3), and South Korea (n = 1), as illustrated in Figure 2.
Which air pollutants were commonly investigated?
The air pollutants investigated in the current study are presented in Table 4.

4. Discussion

Is there a relationship between oral health outcomes and air pollutants?
This systematic review is the first to examine the association between common air pollutants (CO, O3, NO, SO2, and PM) and oral health, highlighting that these pollutants primarily enter the body through inhalation, causing various respiratory and cardiovascular problems [30,31,32,33,34,35,36,37,38,39,40,41,42,43,44]. Notably, particulate matter (PM) can deeply penetrate the lungs and bloodstream, leading to severe health issues like premature death, non-fatal heart attacks, and aggravated asthma [45,46,47,48,49]. The available literature consistently demonstrates that inhalation and ingestion are the primary routes of exposure to air pollutants [46,47,48,49]. As a result, it is reasonable to assume a strong correlation between these pollutants and their impact on the oral cavity. Nevertheless, it is important to note that there is a scarcity of studies specifically focusing on this association, hence the idea to investigate this possible relationships. Three out of eleven studies selected in this review support the existence of an association between oral health and air pollution. In the last 15 years, there was an increase in publications that support this assumption. Specifically, the first study was published in 2014 by Tsung-Han Yang et al., who investigated via a cross-sectional study the association between particulate matter (PM2.5) and high-sensitivity C-reactive protein (hs-CRP), assuming that patients with periodontal diseases had higher CRP levels compared to periodontally healthy subjects. The researchers reached the conclusion that this correlation is feasible since both periodontal diseases and particulate air pollution have been associated with a higher likelihood of experiencing systemic inflammation and oxidative stress. Moreover, they share a common exposure pathway.
Essentially, periodontal inflammation could potentially cause a systemic rise in inflammatory markers, which subsequently amplifies the body’s reaction to particulate air pollution in the lungs. Recently, in 2021, Han Jie-Lin et al. realized a retrospective cohort study using longitudinal generation tracking and the Taiwan air quality-monitoring databases, thus concluding that resident in Taiwan with long-term exposure to higher levels of air pollutants (SO2, CO, NO, NO2, NOx, PM2.5, and PM10) had a greater risk of periodontitis. The authors, however, arrived at a conclusion very similar to that of their predecessors, namely, that the precise mechanisms establishing a connection between periodontitis and air pollution are not yet fully understood, despite extensive research on various air pollutants and their associations with numerous systemic effects. These effects include, among others, increased systemic oxidative stress, increased blood coagulation, and decreased plasma antioxidant capacity [11,50].
In a recently published paper in 2023, Marruganti et al. aimed to further investigate the epidemiological connection between periodontitis and air pollution [10]. They conducted a cross-sectional study in a representative sample of population of South Korea, where they analyzed the average annual levels of PM10, O3, SO2, and NO2. Their findings revealed that even a slight increase in outdoor levels of PM10 and O3 were positively associated with prevalence of periodontitis [10]. On the other hand, NO2 and humidity showed an inverse correlation with periodontitis. The results remained consistent when considering severe cases of periodontitis, showing a similar association with SO2 and NO2. The authors discussed three potential mechanisms that could be associated with periodontitis: inflammation, oxidative stress, and alterations in the microbiome. Specifically, according to this study, the accumulation of particles and components of air pollutants (such iron, copper, and zinc) on the oral mucosa and periodontium can potentially activate comparable inflammatory pathways and induce oxidative stress within the oral cavity [10]. This process mirrors the mechanisms observed in the lungs. At present, however, one fact emerges, namely that, although there is a correlation of some air pollutants, especially particulate matter, with periodontitis, the underlying pathophysiological mechanisms have not yet been explained and clarified. Thus, much more research should be conducted in this regard.
Another finding important to analyze is the correlation between oral cleft and air pollutants, a finding that was common to as many as seven of the eleven articles analyzed, although the main objective of the present systematic review was to investigate the relationship of pollutants with oral diseases. Briefly, orofacial clefts are common congenital malformations generally subdivided into two types: cleft palate only (CPO) and cleft lip with or without cleft palate (CL/P). In a case-control study conducted by Jiang Wen et al. in 2021, it was hypothesized that maternal exposure to CO, NO2, and SO2 during the first trimester of pregnancy could potentially play a role in the occurrence of orofacial clefts. The researchers suggested that these associations might be independent from particulate matter, highlighting the specific focus on these gaseous pollutants in relation to the development of orofacial clefts [12]. In contrast, Liu-fang-Hua’s research in 2020 presented evidence supporting the notion that exposure to PM10 during the three months prior to conception and the first trimester of pregnancy raises the likelihood of developing oral clefts [13]. Several other authors, including Jinzhou Zhao in China and Ying Zhou in the United States, have reported similar associations between PM2.5, PM10, O3, CO, and SO2 exposure and the risk of oral clefts [14]. These studies have shown that PM2.5 significantly increases the risk of cleft palate alone, but does not affect the incidence of cleft lip with or without palate [14]. Additionally, research conducted by Marshall et al. and Tanner in the United States and other studies have found limited and inconsistent evidence linking maternal exposure to ambient air pollutants with cleft malformations [17,19]. However, the majority of the authors reached the consensus that the biological mechanisms responsible for the connections between gaseous air pollutants and orofacial clefts still remain unclear. Some proposed mechanisms include: (1) mutations in fetal DNA that disrupt cellular apoptosis, (2) instances of oxygen deprivation (anoxic events), (3) oxidative damage, and (4) toxicity targeting specific fetal cell populations [51]. In one study out of the eleven, the association between PM2.5 and oral cancer was examined. The authors suggest that elevated levels of PM2.5 might be linked to a higher risk of oral cancer [15]. However, the exact mechanism by which this relationship exists is not fully comprehended, although for some authors the carcinogenicity of PM2.5 has been linked to oxidative DNA damage, metabolism of organic compounds, and inflammatory lesions [52].

Study Limitations

This study has several limitations. Firstly, the exact concentrations of PM10, PM2.5, and other pollutants analyzed, such as CO, SO2, NO2, and O3, are not well specified in every study. As a result, interpreting all the data with absolute clarity becomes challenging. In several selected studies, the levels of air pollutants were assessed using a database that gathers data from air monitoring stations located across the region. In addition, the variations in findings among studies could be attributed, at least in part, to disparities in the levels and ranges of air pollutants. Nevertheless, a substantial portion of the reviewed studies assert a strong correlation between air pollutants and oral diseases, specifically periodontitis. However, the exact biological mechanisms underlying this correlation do not seem to be fully understood, indicating the need for further comprehensive investigation in this regard.

5. Conclusions

In conclusion, this systematic review highlights a potential link between air pollution and oral health, specifically pointing to a significant correlation with periodontitis as evidenced in some studies. However, the limited understanding of the underlying biological mechanisms underscores the necessity for further research to elucidate these connections. By raising awareness and educating patients about the detrimental effects of air pollution on oral health, dentists can help advance public health initiatives.

Author Contributions

Conceptualization, B.S. and S.C.; methodology, M.S. and B.S.; software, E.A., M.S. and P.D.C.; validation, B.S. and P.D.C.; investigation, M.S.; resources, S.C.; data curation, M.S. and E.A.; writing—original draft preparation, M.S. and B.S.; writing—review and editing, P.D.C. and E.A.; visualization, S.C. and B.S.; supervision, B.S.; project administration, B.S. and S.C.; funding acquisition, S.C., P.D.C. and B.S. B.S. and M.S. contributed equally to this work and share first authorship. All authors have read and agreed to the published version of the manuscript.

Funding

Italian Ministry of University and Research (MUR) National Innovation Ecosystem, grant ECS00000041-VITALITY-CUP D73C22000840006.

Conflicts of Interest

The authors declare no conflicts of interests.

Abbreviations

O3Ozone
NONitrogen Monoxide
NO2Nitrogen Dioxide
SO2Sulfur Dioxide
COCarbon Monoxide
PM10,2.5particulate matter
N.A.Not applicable

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Dentistry 12 00215 g001
Figure 1. PRISMA flow diagram.
Figure 1. PRISMA flow diagram.
Dentistry 12 00215 g001
Dentistry 12 00215 g002
Figure 2. Geographic distribution of studies included: Taiwan (n = 4) 37%; United States (n = 3) 27%; China (n = 3) 27%; South Korea (n = 1) 9%.
Figure 2. Geographic distribution of studies included: Taiwan (n = 4) 37%; United States (n = 3) 27%; China (n = 3) 27%; South Korea (n = 1) 9%.
Dentistry 12 00215 g002
Table 1. Table summarizing the principal results of the study. PM = Particulate Matter; O3 = Ozone; NO = Nitrogen Monoxide; NO2 = Nitrogen Dioxide; SO2 = Sulfur Dioxide; CO = Carbon Monoxide.
Table 1. Table summarizing the principal results of the study. PM = Particulate Matter; O3 = Ozone; NO = Nitrogen Monoxide; NO2 = Nitrogen Dioxide; SO2 = Sulfur Dioxide; CO = Carbon Monoxide.
AuthorYearType of StudyPollutantPM (Particulate Matter)CountryImpact on Oral HealthRisk of Bias
Marruganti et al. [10]2023Cross-sectional studyO3
NO2
SO2		PM<10South Korea PeriodontitisHigh
Han-Jie Lin et al. [11]2021Retrospective cohort study NO
NO2
SO2		PM2.5
PM10		TaiwanPeriodontitisHigh
Jiang Wen
[12]		2021Case-control
study		CO
O3
NO2
SO2		PM2.5
PM10		ChinaOral CleftHigh
Liu Fang-Hua
[13]		2020Population-based, case-control studyN.A.PM10ChinaOral cleft in offspringHigh
Jinzhu Zhao
[14]		2018Prospective population-based cohort studyO3
SO2
CO		PM2.5
PM10		ChinaOral CleftHigh
Yu-Hua Chu et al. [15]2018Retrospective studyO3
NO2
SO2
CO
NO		PM10
PM2.5
PM10–2.5		TaiwanPM2.5 and oral cancer High
Ying Zhou [16]2017Retrospective studyO3PM2.5USAOral cleftHigh
Tanner Jean Paul [17]2015Retrospective cohort studyBenzenePM2.5USAOral CleftHigh
Tsung-Han Yang [18]2014Cross-sectional studyN.A.PM2.5TaiwanPeriodontitisHigh
Marshall Elizabeth G. [19]2009Case-control studyO3
CO
NO2		PM10
PM2.5		USAOral cleft malformationsHigh
Hwang Bing-Fang [20]2008Population-based case-control studySO2
NOx
O3		PM10TaiwanCleft Lip with or without palateHigh
Table 2. QUADAS-2 tool quality assessment, ** high risk of BIAS.
Table 2. QUADAS-2 tool quality assessment, ** high risk of BIAS.
AuthorPatient SelectionIndex TestReference Standard Flow and Timing
Marruganti et al. [10]********
Han-Jie Lin et al. [11]********
Jiang Wen [12]********
Liu Fang-Hua [13]********
Jinzhu Zhao [14]********
Yu-Hua Chu et al. [15]********
Ying Zhou [16]********
Tanner Jean Paul [17]********
Tsung-Han Yang [18]********
Marshall Elizabeth G. [19]********
Hwang Bing-Fang [20]********
Table 3. Table summarizing the principal results of the study. N.A. = Not applicable; OR = Odds ratio.
Table 3. Table summarizing the principal results of the study. N.A. = Not applicable; OR = Odds ratio.
AuthorSample
Size		Study DesignPollutant
and PM		Age (Years) and
Gender, N(%)		Resume of Principal Results
Marruganti et al. [10]42,020Cross-sectional surveyO3
NO2
SO2
PM<10		44.91
M 17,876 (49.6%)
W 24,144 50.4%)		An increase of 5 µg/m3 in PM10 concentration was associated with a higher prevalence of periodontitis (OR = 1.17; 95% confidence interval—CI: 1.11–1.24). Similarly, a 5 ppb increase in O3 levels was also positively associated with periodontitis prevalence, with an odds ratio of 1.4 (95% CI: 1.00–1.30). On the other hand, a 5% increase in humidity showed an inverse association with periodontitis (OR = 0.94; 95% CI: 0.90–0.99), meaning that higher humidity levels were associated with a lower prevalence of periodontitis. Additionally, a 3 ppb increase in NO2 levels was inversely associated with periodontitis, with an odds ratio of 0.93 (95% CI: 0.89–0.96), indicating that higher NO2 levels were associated with a lower prevalence of periodontitis.
Han-Jie Lin et al. [11]292,263Retrospective cohort study NO
NO2
SO2
PM2.5
PM10		41.1
M 131,278 (44.9%)
W 160,985 (55.1%)		The incidence of periodontitis increased with exposure to SO2, CO, NO, NO2, NOx, PM2.5, and PM10. The concentrations of these air pollutants were divided into quartiles (Q1, Q2, Q3, and Q4). After adjusting for age, sex, population density, and comorbidities, the adjusted hazard ratios (95% confidence interval—CI%) for periodontitis in Q2–Q4 showed a significant increase with higher levels of exposure to SO2, CO, NO, NO2, NOx, PM2.5, and PM10, respectively.
Jiang Wen [12]446 Case
4460 Control		Case-control
study		CO
O3
NO2
SO2
PM2.5
PM10		N.A.
Case
M 272
W 174
Control
M 2325
W 2135		An increase in CO, NO2, and SO2 exposure significantly elevated the risk of cleft lip with or without cleft palate (CL/P) in all months of the first trimester of pregnancy, with odds ratios ranging from 1.39 to 1.48 for CO, 1.35 to 1.61 for NO2, and 1.22 to 1.35 for SO2. The risk of cleft palate only (CPO) also increased with higher levels of NO2 exposure during the first trimester, with odds ratios ranging from 1.60 to 1.66. However, no significant effect of O3 exposure was observed in relation to the risk of oral clefts.
Liu Fang-Hua [13]3086 Case
7950 Control		Population-based, case-control studyN.A.
PM10		N.A.
Case
M 1743
W 1343
Control
M 4023
W 3927		Maternal exposure to PM10 showed a positive association with an increased risk of oral cleft during the three months before conception (per 10 μg/m3 increase: OR = 1.04, 95% CI 1.01 to 1.07; highest quartile vs. lowest quartile: OR = 1.23, 95% CI 1.04 to 1.45) and the first trimester of pregnancy (per 10 μg/m3 increase: OR = 1.05, 95% CI 1.02 to 1.08; highest quartile vs. lowest quartile: OR = 1.37, 95% CI 1.15 to 1.64). Similar positive associations were observed in the analysis of individual months, with the highest quartile versus lowest quartile showing a particularly strong association in the second month of pregnancy (OR = 1.77, 95% CI 1.51 to 2.09).
Jinzhu Zhao [14]105,927Prospective population-based cohort studyO3
SO2
CO
PM2.5
PM10		N.A.The aim of this study was to assess whether increased levels of maternal exposure to PM2.5, PM10, O3, CO, and SO2 are linked to a higher risk of oral clefts in Wuhan, China. The results revealed significant associations between PM2.5 exposure and both outcomes (CPO and CLP), particularly during the second month of pregnancy (aORs = 1.29 per 10 μg/m3 change; 95% CI: 1.17–1.42), as well as the third month of pregnancy (aORs = 1.11; 95% CI: 1.01–1.22). Moreover, the risk of having a baby with an oral cleft increased by 11–29% within the range of PM2.5 concentrations considered in the study. Similarly, significant associations were observed between CLP and exposure to O3 and PM10. Additionally, a significant association was found between CPO and exposure to CO.
Yu-Hua Chu et al. [15]482,559Retrospective studyO3
NO2
SO2
CO
NO
PM10
PM2.5
PM10–2.5		N.A.The researchers assessed the levels of CO, O3, CO, and SO2, NOx (PM10–2.5), and PM2.5 in 2009, categorizing them into quartiles. The analysis included a total of 482,659 men aged 40 years and above. Logistic regression was employed to examine the association between PM2.5 and oral cancer cases diagnosed between 2012 and 2013. After adjusting for factors such as PM10–2.5, SO2, O3, age, and betel quid chewing, the odds ratios (ORs) for oral cancer were found to be 0.91 (95% CI 0.75 to 1.10) for PM2.5 levels between 26.74 and 32.37 μg/m3, 1.00 (95% CI 0.84 to 1.20) for levels between 32.37 and 40.37 μg/m3, and 1.42 (95% CI 1.17 to 1.73) for levels ≥ 40.37 μg/m3. The association between PM2.5 and oral cancer risk remained unchanged even after further adjustment for smoking. In both models, PM10–2.5 and SO2 did not show a significant association with oral cancer, irrespective of their concentrations. However, O3, frequent betel quid chewing and occasional and frequent smoking were found to be significantly linked to oral cancer.
Ying Zhou [16]4.7 MillionRetrospective studyO3
PM2.5		N.A.The researchers found that for every 10 μg/m3 increase in PM2.5 concentration, there was a significant association with cleft palate alone (odds ratio, OR = 1.43, 95% confidence interval, CI: 1.11–1.86). However, they did not observe a significant association between PM2.5 concentration and cleft lip with or without cleft palate. Furthermore, no associations were found between ozone exposure and the two outcomes of orofacial clefts. The study suggests that increased levels of PM2.5 significantly increase the risk of cleft palate alone, but do not affect the incidence of cleft lip with or without palate.
Tanner Jean Paul [17]2,123,874Retrospective cohort studyBenzene
PM2.5		N.A.The findings revealed that mothers who had the highest level of benzene exposure had a higher likelihood of giving birth to an infant with an isolated cleft palate (adjusted prevalence ratio, 4th quartile: 1.52; 95% confidence interval, CI: 1.13–2.04) or any orofacial cleft (adjusted prevalence ratio, 4th quartile: 1.29; 95% CI: 1.08–1.56).
Tsung-Han Yang [18]200Cross-sectional studyN.A.
PM2.5		M = 100 (50%)
W = 100 (50%)		The authors discovered that for every 10 μg/m3 rise in the 24 h average of PM2.5, there was a 3.22% increase (95% confidence interval, CI: 1.21, 5.23; p < 0.01) in high-sensitivity C-reactive protein (hs-CRP) levels and a 1.03% increase (95% CI: 0.01, 2.05; p < 0.01) across all study participants. Among adult patients with chronic periodontitis, there was an 8.45% increase in hs-CRP and a 2.57% increase in the oxidative stress marker oxidative DNA adduct 8-hydroxy-2-deoxyguanosine (8-OHdG), both of which were associated with elevated levels of PM2.5 over a 24 h period. Notably, female participants demonstrated a more pronounced hs-CRP response to increased levels of PM2.5 compared to male participants.
Marshall Elizabeth G. [19]690,000Case-control studyO3
CO
NO2
PM10
PM2.5		N.A.The authors conducted a comparative analysis of estimated exposure to ambient air pollutants during early pregnancy between mothers of children with oral cleft defects (cases) and mothers of control subjects. They adjusted for available risk. The analysis revealed that higher quartiles of CO concentration demonstrated a consistent protective association with CPO (p < 0.01). For other contaminants, the 95% confidence intervals of the odds ratios for certain quartiles did not include one, indicating a potential association. CLP showed limited evidence of an association with increasing SO2 exposure, while CPO displayed weak associations with increasing O3 exposure.
Hwang Bing-Fang [20]721,289Population-based case-control studySO2
NOx
O3
PM10		N.A.Using geographic information systems, the authors employed the inverse distance weighting method to establish exposure parameters for SO2, NOx,O3, CO, and PM10 during the first three months of pregnancy. The authors expressed the effect estimates as odds ratios (ORs) per 10 ppb change for SO2, NOx, and O3, 100 ppb change for CO, and 10 μg/m3 change for PM10. The analysis revealed an increased risk of cleft lip and/or palate (CL/P) in relation to O3 levels during the first gestational month (adjusted OR = 1.20; 95% confidence interval, 1.02–1.39) and second gestational month (adjusted OR = 1.25; 95% CI, 1.03–1.52) within the range of 16.7 ppb to 45.1 ppb. However, there was no significant association observed with CO, NOx, SO2, or PM10.
Table 4. Table summarizing the principal air pollutants investigated.
Table 4. Table summarizing the principal air pollutants investigated.
PollutantCharacteristicsHealth Effects
PM2.5 and PM10Particulate matter originating from primary emissions or secondary particles formed through physical and chemical reactions. PM2.5 and PM10 are extensively studied pollutants.Heightens the risk of air pollution-related diseases, including acute respiratory tract infections, cardiovascular disease, chronic obstructive pulmonary disease (COPD), and lung cancer [21,22,23].
O3Formed through complex photochemical reactions in the troposphere, particularly in the presence of pollutants and sunlight.Acute effects include throat dryness, pharyngitis, bronchitis, reduced pulmonary bactericidal capacity, eye irritation, and cardiovascular effects. Chronic effects include fibrosis, teratogenic effects, and impacts on the reproductive system [24,25,26].
COGenerated through incomplete combustion, characterized by its colorless and odorless nature.Forms carboxyhemoglobin, leading to hypoxia, ischemia, and cardiovascular diseases. Symptoms of carbon monoxide poisoning include headaches, dizziness, weakness, nausea, vomiting, and loss of consciousness [25,27,28,29,30,31,32].
NO2Emitted from combustion, primarily in urban areas, by automobile engines and power plants.Causes irritation to the respiratory system, exacerbating respiratory symptoms, and resulting in hospitalizations. Prolonged exposure increases the risk of asthma development and susceptibility to respiratory infections, leading to respiratory diseases, breathlessness, bronchospasm, and pulmonary edema [27,28].
SO2Emitted from the combustion of fossil fuels and industrial activities.Adversely affects the respiratory system, leading to bronchitis, bronchospasm, increased mucus production, and aggravation of existing respiratory conditions [32].
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Sinjari, B.; Santilli, M.; Di Carlo, P.; Aruffo, E.; Caputi, S. The Correlation between Oral Health and Air Pollution: A Systematic Review. Dent. J. 2024, 12, 215. https://doi.org/10.3390/dj12070215

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Sinjari B, Santilli M, Di Carlo P, Aruffo E, Caputi S. The Correlation between Oral Health and Air Pollution: A Systematic Review. Dentistry Journal. 2024; 12(7):215. https://doi.org/10.3390/dj12070215

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Sinjari, Bruna, Manlio Santilli, Piero Di Carlo, Eleonora Aruffo, and Sergio Caputi. 2024. "The Correlation between Oral Health and Air Pollution: A Systematic Review" Dentistry Journal 12, no. 7: 215. https://doi.org/10.3390/dj12070215

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