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. 2017 Jun 8;2017:7431301. doi: 10.1155/2017/7431301

Factors Associated with Dental Pain in Mexican Schoolchildren Aged 6 to 12 Years

Mauricio Escoffié-Ramirez 1,2, Leticia Ávila-Burgos 2, Elena Saraí Baena-Santillan 3, Fernando Aguilar-Ayala 1, Edith Lara-Carrillo 4, Mirna Minaya-Sánchez 5, Martha Mendoza-Rodríguez 3, María de Lourdes Márquez-Corona 3, Carlo Eduardo Medina-Solís 3,4,*
PMCID: PMC5480020  PMID: 28685149

Abstract

Objective

To identify dental pain prevalence and associated factors in Mexican schoolchildren.

Methods

This cross-sectional study included 1,404 schoolchildren aged 6 to 12 years from public schools in the city of Pachuca de Soto, Hidalgo, Mexico. Data were collected through a questionnaire that addressed sociodemographic and socioeconomic factors, eating and dental hygiene habits, and behavior variables. The dependent variable was self-reported dental pain in the 12 months prior to the survey. Data were analyzed using nonparametric statistics and a binary logistical regression model.

Results

Dental pain prevalence among the studied children was 49.9%. The variables associated in the final model (p < 0.05) were younger mother's age, higher socioeconomic level, absence of an automobile in the home, fried food, fruit intake, lower tooth brushing frequency, never having used mouthwash or not knowing about it, and parents/guardians with regular to high levels of knowledge about oral health and a regular or good/very good perception of their child's oral health.

Conclusions

One in two children in the study had experienced dental pain in the twelve months prior to the survey. The association of socioeconomic variables with dental pain suggested inequalities among the children in terms of oral health.

1. Introduction

Oral disorders such as dental caries and periodontal disease are worldwide public health problems. The “Global Burden of Oral Conditions in 1990–2010” report showed that oral conditions continue to be highly prevalent, affecting about 3.69 billion people. In this report, untreated dental caries in the permanent dentition was identified as the most common of all the evaluated disorders, having the highest worldwide disease load, affecting 35% of all age groups. Severe periodontitis was the sixth most prevalent condition (11% of world population) and untreated caries of the primary dentition was the tenth (9% of world population). Severe tooth loss was the 36th most prevalent condition, affecting 2% of the world's population [14]. A number of studies from around the world state that 60–90% of schoolchildren suffer from dental caries [5]. In Latin America, dental caries is among the most frequent untreated health conditions among preschoolers, schoolchildren, and adolescents, who have limited access to restorative dental treatment. In Mexico, dental caries is the primary public oral health problem; for example, at 12 years of age between 70 and 85% of schoolchildren exhibit caries in the permanent dentition, with a high prevalence of untreated cases. Dental caries is also the main cause of dental death in various age groups, presenting a serious challenge to the oral healthcare system due to high care costs [6].

Oral and dental diseases can cause pain, suffering, functional deterioration, and diminished quality of life. The high cost of treatment constitutes a substantial burden to the national health system and for individual households. Families often opt to pay directly for dental care in an effort to maintain adequate oral health among household members. In developed countries, oral health treatment represents from 5 to 10% of health expenses. This treatment is unavailable or extremely limited in many developing countries, where affected teeth are often not treated or merely extracted, making them the main source of pain [79]. For decision-makers in different countries, especially in the “developing" ones where the burden of disease is high, it is necessary to consider oral health as a priority and having recent epidemiological data is essential.

The experience of pain, considered a normal consequence of organ or system disorders, is a ubiquitous public health concern. Untreated dental caries generally leads to dental pain. Although dental pain can seriously affect peoples' daily life, negatively affecting quality of life, few epidemiological studies on oral health include questions on dental pain. Orofacial pain, and especially dental pain, can cause sleep loss, diminished work effectiveness or academic performance, absence from school or work, weight loss, and avoidance of certain foods. Some researchers treat it as a predictor of dental health service use (usually curative or emergency) [10, 11]. In this type of care, teeth receive nonregressive treatments that can predispose them to loss over time; it can also raise the probability of an edentulous old age [12, 13].

Health needs can be identified through either subjective self-reporting of symptoms, diseases, injuries, and disabilities or a normative method applied by trained health personnel in a health clinic [8, 14]. Indicators based on self-reported health perception have been shown to be good predictors of oral health. An additional advantage is that data for these indicators can be collected from large groups, along with data for other indicators in population groups. This facilitates correlation of health variables with other variables of interest, such as socioeconomic level, sociodemographic aspects, residence, oral health habits, and education level [15, 16]. Self-reported dental and orofacial pain are good oral health indicators because they are related to the presence of dental diseases, such as caries, periodontal disease, and temporomandibular joint disorders. Among children, odontogenic pain prevalence ranges from 5 to 33% [17] and is frequently related to carious injury on the surface of one or more teeth [18]. Dental pain can also be used by dentists to make decisions; for example, in schoolchildren it can be a symptom of the seriousness of the carious injury. Dental pain has even been used to explore the impact of pain on the psychosocial wellbeing of the child patient and the parents [19]. Schoolchildren can experience pain from caries in primary and permanent teeth. Due to lack of awareness, however, parents usually associate dental pain with primary teeth, thinking that once a tooth exfoliates the pain will disappear. This highlights the need for oral health maintenance strategies, including better information on dental caries prevention, to reduce the risk of disorders [19].

Most orofacial pain is due to dental disorders, and acute pain is generally caused by oral conditions, particularly dental caries and periodontitis. However, pathological processes are not necessarily the sole or sufficient cause of this kind of pain. Pain perception can be modulated by cognitive factors such as knowledge, beliefs, and expectations, which in turn can be influenced by the social, economic, and cultural environment of affected individuals. Here we aimed to identify the factors associated with dental pain as an oral health indicator in schoolchildren, aged 6 to 12 years in the state of Hidalgo, Mexico.

2. Materials and Methods

2.1. Study Design and Sample Selection

This cross-sectional study was focused on schoolchildren attending primary schools in the city of Pachuca de Soto, Hidalgo. Previously published portions of the methodology explain the use of oral health assistants [20] and oral health services at some time in the past [21]. Study design and implementation met WHO recommendations for oral health epidemiological studies [22]. Sample size was calculated based on a smallest estimated proportion (prevalence) of 35%; a 95% confidence level; 3% accuracy; and a 10% no answer rate. The estimated sample population was 1,554 schoolchildren. In the first stage, a random selection was made of 15 of the 93 public primary schools in the city. In the second stage, a random sample was taken from these schools' enrollment lists to choose potential study participants. The chosen students' parents/guardians were invited to participate in the study and study objectives explained to them. A questionnaire was given to those who accepted, and, after reading, they were asked to sign an informed consent form. Reminders were sent to the parents/guardians who had accepted to participate every 7 days after they were given the questionnaire; they were reminded a maximum of three times. The response rate was 73.8% (n = 1,158) after the first, 87.8% (n = 1,376) after the second, and 93.8% (n = 1,470) after the third reminder. Inclusion criteria were (a) enrollment in one of the primary schools in the study and (b) age between 6 and 12 years. Exclusion criteria were (a) parent report of a disease that could affect child oral health and/or (b) parent/guardian not signing informed consent form. Final sample size was 1,404 schoolchildren.

2.2. Data Collection and Variables

Data were collected through a questionnaire answered at home by the schoolchildren's parent/guardian. The questionnaire was divided into sections that allowed the collection of sociodemographic, socioeconomic, food habits, oral health habits, oral appearance satisfaction, and oral health services use data. Questionnaires were distributed and recovered through the schools. The schoolchildren's self-report of dental pain was the studied variable. This was measured using the question “In the last twelve months, has your child experienced any pain/discomfort in the mouth, teeth or gums?” Results were measured with a dichotomous scale: 0 = no and 1 = yes.

A total of eight independent sociodemographic variables were used: age of schoolchild in years (0 = 6-7 yrs.; 1 = 8–10 yrs.; 2 = 11-12 yrs.); sex of schoolchild (0 = female; 1 = male); head of household (0 = mother; 1 = father; 2 = other); mother's and father's ages in years (continuous format); mother's and father's education level (0 = primary; 1 = middle; 2 = high; 3 = Bachelor's or higher); health insurance coverage (0 = uninsured, 1 = IMSS/ISSSTE, 2 = PEMEX, SEDENA, SEMAR, 3 = private, 4 = Seguro Popular); and automobile in household (0 = yes; 1 = no). Four schoolchild oral health variables were measured: brushing frequency (0 = at least once a day; 1 = less than once a day); toothpaste use (0 = at least once a day; 1 = less than once a day); dental floss use (0 = at least once a week; 1 = never, do not know); and mouthwash use (0 = at least once a week; 1 = never, do not know). Parent/guardian variables included brushing frequency (0 = at least once a day; 1 = less than once a day) and perception of schoolchild's oral health condition (0 = bad/very bad; 1 = regular; 2 = good/very good).

Using a polychoric correlation as part of a principal components analysis, three different interrelated groups of variables were formed. The first group encompassed two variables indicating socioeconomic position, one referring to housing characteristics (e.g., wall, roof, and floor building materials, presence/absence of a kitchen, bathroom characteristics, and number of bedrooms) and the other to household appliances (e.g., refrigerator, stove, television, and telephone). A second group consisted of three variables addressing frequency of candy, fried foods, and fruit consumption. The third group was one variable on parent/guardian knowledge of schoolchild oral health. After generating the principal component for each of these six (continuous) variables, the socioeconomic condition indices were categorized into quartiles, while the food intake and oral health knowledge indices were categorized into tertiles. Depending on the variable, the first indicated the lowest level and the last the highest level.

2.3. Statistical Analysis

After cleaning the database, we performed a descriptive analysis of the studied variables, estimating frequencies and percentages for each category of qualitative variable. The quantitative variables were analyzed by calculating the mean and standard deviation (SD). In the bivariate analysis, contingency tables were generated for the dental pain dependent variable with each independent variable and the Pearson χ2-type test of independence run. Mann-Whitney U tests for independent samples were applied for mother's and father's age. These were fitted to a binary logistical regression multivariate model to estimate the strength of association between the dependent and independent variables. Results were expressed as an odds ratio (OR) with a 95% confidence interval (CI 95%). Statistical significance for p values was set at <0.05. Only those variables with p < 0.25 in the bivariate model were considered in the multivariate model. In response to correlation between groups (school variable cluster), confidence intervals were calculated with robust Huber-White standard deviations. This occurred because similarity was higher and therefore had greater correlation, among schoolchildren from the same school; that is, the clusters were distinctly different [23]. The model fit was evaluated with the Hosmer-Lemeshow statistic [24]. All statistical analyses were run with the Stata ver. 13® package.

2.4. Ethical Aspects

This methodology met study subject protection guidelines and relevant Helsinki ethical regulations. The study protocol was approved by the Ethics and Research Committee of the Autonomous University of the State of Hidalgo (Universidad Autónoma del Estado de Hidalgo [UAEH]) and the committees of the National Institute of Public Health (UAEH Institutional Ethical Review Committee code: UAEH-DI-ICSA-ODO-CF-016). Written consent was obtained from all the patients/guardians.

3. Results

3.1. Sample Characteristics

The 1,404 schoolchildren in the sample had a mean age of 8.96 ± 1.99 years and 49.9% were female (Tables 1 and 2). The participant's mothers had a mean age of 34.8 ± 6.1 years, and fathers' mean age was 37.7 ± 6.32 years. In 77.6% of the participating families, the father was head of the household. The largest proportion of mothers (36.8%) had completed some or all of middle school, while the largest proportion of fathers (32.5%) had completed some or all of high school. Most (51.8%) of the participating families had public sector health insurance, through either the IMSS (Instituto Mexicano de Seguro Social) or ISSSTE (Instituto de Seguridad y Servicios Sociales de los Trabajadores del Estado). Most (85.7%) of the schoolchildren brushed their teeth at least once per day and always used toothpaste (90.9%). However, most had never used/did not know about dental floss (80.6%) or mouthwash (71.8%). Parent/guardian brushing frequency was largely “at least once per day” (89.4%), and the majority (45.2%) reported their child's oral health to be “regular.” Half (49.9%) of the schoolchildren were reported to have had dental pain at some time during the twelve months prior to the study.

Table 1.

Sociodemographic and socioeconomic data for schoolchildren aged 6 to 12 years in dental pain survey.

Variables n %
Age
 6-7 yrs. 409 29.1
 8–10 yrs. 609 43.4
 11-12 yrs. 386 27.5
Sex
 Female 701 49.9
 Male 703 50.1
Head of household
 Mother 241 17.2
 Father 1090 77.6
 Other 73 5.2
Mother's education level
 Primary 137 9.8
 Middle 517 36.8
 High 493 35.1
 Bachelor's or higher 257 18.3
Father's education level
 Primary 125 9.2
 Middle 365 26.8
 High 443 32.5
 Bachelor's or higher 430 31.5
Health insurance
 Uninsured 433 30.8
 IMSS/ISSSTE 727 51.8
 PEMEX/SEDENA/SEMAR 68 4.8
 Private 49 3.5
 Seguro Popular 127 9.1
SEL (household appliances)
 1st quartile 351 25.0
 2nd quartile 352 25.1
 3rd quartile 351 25.0
 4th quartile 350 24.9
SEL (housing characteristics)
 1st quartile 356 25.3
 2nd quartile 354 25.2
 3rd quartile 345 24.6
 4th quartile 349 24.9
Automobile in home
 Yes 893 63.6
 No 511 36.4
n Mean ± sd
Mothers' age 1404 34.89 ± 6.06
Father's age 1363 37.72 ± 6.32
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Table 2.

Risk indicator (diet, oral health habits, and behavior) distribution among schoolchildren aged 6 to 12 years in dental pain survey.

Variables n %
High calorie food intake
Candies
 Low 470 33.5
 Moderate 466 33.2
 High 468 33.3
Fried food
 Low 471 33.5
 Moderate 467 33.3
 High 466 33.2
Fruit
 Low 469 33.4
 Moderate 473 33.7
 High 462 32.9
Oral health habits
Brushing frequency
 At least once a day 1204 85.7
 Less than once a day 200 14.3
Toothpaste use
 At least once a day 1276 90.9
 Less than once a day 128 9.1
Dental floss use
 At least once a week 273 19.4
 Never, do not know of it 1131 80.6
Mouthwash use
 At least once a week 396 28.2
 Never, do not know of it 1008 71.8
Parent oral health knowledge and habits
Brushing frequency
 At least once a day 1255 89.4
 Less than once a day 149 10.6
Knowledge of oral health
 Sufficient 468 33.3
 Regular 468 33.3
 Insufficient 468 33.3
Perception of child's oral health
 Very bad/bad 158 11.3
 Regular 635 45.2
 Good/very good 611 43.5
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3.2. Bivariate Analysis of Reported Pain versus Independent Variables

Of the half of the children who reported to have had dental pain, the largest proportion were male, affiliated with the Seguro Popular system, located in the lowest socioeconomic level in terms of housing characteristics, and lived in households without an automobile (Table 3). Unexpectedly, the highest dental pain prevalence was observed in the highest socioeconomic level based on domestic appliances.

Table 3.

Bivariate analysis of sociodemographic and socioeconomic variables for schoolchildren aged 6 to 12 years in dental pain survey.

Variables No pain n = 704 (50.1%) Pain n = 700 (49.9%) p value
Age
 6-7 yrs. 210 (51.3) 199 (48.7) 0.601
 8–10 yrs. 296 (48.6) 313 (51.4)
 11-12 yrs. 198 (51.3) 188 (48.7)
Sex
 Female 375 (53.5) 326 (46.5) 0.012
 Male 329 (46.8) 374 (53.2)
Head of household
 Mother 131 (54.4) 110 (45.6) 0.356
 Father 537 (49.3) 553 (50.7)
 Other 36 (49.3) 37 (50.7)
Mother's education level
 Primary 63 (46.0) 74 (54.0) 0.103
 Middle 242 (46.8) 275 (53.2)
 High 260 (52.7) 233 (47.3)
 Bachelor's or higher 139 (54.1) 118 (45.9)
Father's education level
 Primary 56 (44.8) 69 (55.2) 0.190
 Middle 168 (46.0) 197 (54.0)
 High 225 (50.8) 218 (49.2)
 Bachelor's or higher 226 (52.6) 204 (47.4)
Health insurance
 Uninsured 235 (54.3) 198 (45.7) 0.010
 IMSS/ISSSTE 358 (49.2) 369 (50.8)
 PEMEX/SEDENA/SEMAR 39 (57.4) 29 (42.6)
 Private 25 (51.0) 24 (49.0)
 Seguro Popular 47 (37.0) 80 (63.0)
SEL (household appliances)
 1st quartile 205 (58.4) 146 (41.6) 0.004
 2nd quartile 170 (48.3) 182 (51.7)
 3rd quartile 170 (48.4) 181 (51.6)
 4th quartile 159 (45.4) 191 (54.6)
SEL (housing characteristics)
 1st quartile 150 (42.1) 206 (57.9) <0.001
 2nd quartile 167 (47.2) 187 (52.8)
 3rd quartile 179 (51.9) 166 (48.1)
 4th quartile 208 (59.6) 141 (40.4)
Automobile in home
 Yes 489 (54.8) 404 (45.2) <0.001
 No 215 (42.1) 296 (57.9)
Mean ± sd Mean ± sd
Mothers' age 35.47 ± 6.15 34.30 ± 5.91 0.0001 ∗∗
Fathers' age 37.97 ± 6.36 37.48 ± 6.28 0.0436 ∗∗
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Pearson χ2 test; ∗∗Mann-Whitney test.

Of the schoolchildren with reported dental pain, a larger proportion had high fried food intake and low fruit intake (Table 4). These children also had lower brushing frequency and toothpaste use values. An unexpected result was that those who used dental floss and mouthwash at least once a week had a higher dental pain frequency than those who did not use these hygiene tools. Dental pain was also more frequent among the schoolchildren with a parent/guardian who reported lower brushing frequency, had a regular or high oral health information level, and perceived their child's oral health as being bad/very bad or regular.

Table 4.

Bivariate analysis of risk indicators (diet, oral health habits, and behavior) among schoolchildren aged 6 to 12 years in dental pain survey.

Factors No pain n (%) Pain n (%) p value
High calorie food intake
Candies
 Low 230 (48.9) 240 (51.1) 0.502
 Moderate 244 (52.4) 222 (47.6)
 High 230 (49.2) 238 (50.8)
Fried food
 Low 268 (56.9) 203 (43.1) <0.001
 Moderate 230 (49.2) 237 (50.8)
 High 206 (44.2) 260 (55.8)
Fruit
 Low 207 (44.1) 262 (55.9) 0.005
  Moderate 247 (52.2) 226 (47.8)
 High 250 (54.1) 212 (45.9)
Oral health habits
Brushing frequency
 At least once a day 640 (53.2) 564 (46.8) <0.001
 Less than once a day 64 (32.0) 136 (68.0)
Toothpaste use
 At least once a day 662 (51.9) 614 (48.1) <0.001
 Less than once a day 42 (32.8) 86 (67.2)
Dental floss use
 At least once a week 121 (44.3) 152 (55.7) 0.032
 Never, do not know of it 583 (51.5) 548 (48.5)
Mouthwash use
 At least once a week 157 (39.7) 239 (60.3) <0.001
 Never, do not know of it 547 (54.3) 461 (45.7)
Parent oral health knowledge and habits
Brushing frequency
 At least once a day 656 (52.3) 599 (47.7) <0.001
 Less than once a day 48 (32.2) 101 (67.8)
Knowledge of child's oral health
 Sufficient 285 (60.9) 183 (39.1) <0.001
 Regular 218 (46.6) 250 (53.4)
 Insufficient 201 (42.9) 267 (57.1)
Perception of child's oral health
 Very bad/bad 46 (29.1) 112 (70.9) <0.001
 Regular 325 (51.2) 310 (48.8)
 Good/very good 333 (54.5) 278 (45.5)
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Pearson χ2 test.

3.3. Logistical Regression Multivariate Model

Our multivariate model results revealed that, for each year of increase in mother's age, the possibility of dental pain in the schoolchild decreased (ORA = 0.98; CI 95% = 0.96–0.99) (Table 5). Schoolchildren in the top quartile of housing characteristics (NSE) had a lower probability (ORA = 0.98; CI 95% = 0.96–0.99) of experiencing dental pain than those in lower quartiles. Living in a home with no automobile increased the probability of experiencing dental pain by 49% compared to the children in homes with automobiles. In contrast to children with low reported fried food intake, those with a high intake had a 2.34% (CI 95% = 1.42–3.88) greater probability of dental pain, and those with moderate intake had an 87% (CI 95% = 1.30–2.69) greater probability. High (ORA = 0.61; CI 95% = 0.42–0.88) and moderate (ORA = 0.68; CI 95% = 0.48–0.97) fruit intake decreased the probability of experiencing dental pain compared to those with low intake. Schoolchildren who brushed their teeth less than once per day had 2.31 times greater probability of having dental pain than those who brushed at least once per day. A parent/guardian perception of good/very good (ORA = 0.34 CI 95% = 0.19–0.62) and regular (ORA = 0.39 CI 95% = 0.19–0.80) child oral health lowered the possibility of dental pain compared to a bad/very bad perception. Surprisingly, parent/guardian nonuse of mouthwash lowered (ORA = 0.46; CI 95% = 0.27–0.78) child probability of having dental pain in contrast to those who used it at least once per week.

Table 5.

Multivariate analysis of dental pain in schoolchildren aged 6 to 12 years in dental pain survey.

Variables OR CI 95% p value
Mother's age 0.98 0.96–0.99 0.019
NSE (housing characteristics)
 1st to 3rd quartile (−) 1
 4th quartile (+) 0.52 0.30–0.92 0.026
Automobile in home
 Yes 1
 No 1.49 1.14–1.93 0.003
Fried food intake
 Low 1
 Moderate 1.87 1.30–2.69 0.001
 High 2.34 1.42–3.88 0.001
Fruit intake
 Low 1
 Moderate 0.68 0.48–0.97 0.033
 High 0.61 0.42–0.88 0.009
Brushing frequency
 At least once a day 1
 Less than once a day 2.31 1.51–3.53 0.000
Mouthwash use
 At least once a week 1
 Never, do not know of it 0.46 0.27–0.78 0.004
Knowledge of child's oral health
 Sufficient 1
 Regular 2.09 1.43–3.04 0.000
 Insufficient 2.72 1.55–4.77 0.000
Perception of child's oral health
 Very bad/bad 1
 Regular 0.39 0.19–0.80 0.011
 Good/very good 0.34 0.19–0.62 0.000
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Note: Model fitted to variables in table; reference category; model fit: Hosmer-Lemeshow χ2(8) = 9.42; p = 0.3081.

4. Discussion

To our knowledge, our study is one of the first to address the prevalence of and factors associated with dental pain in Mexico. The frequently observed relationship between dental pain and dental caries in this age group makes it an important variable. Identifying dental pain in schoolchildren can be a good indicator of the need for curative or emergency treatment, an estimator of the proportion of people who may use oral health services in the future, and therefore a key datum in planning oral health service needs.

Half (49.9%) of the studied schoolchildren had experienced dental pain in the twelve months prior to the survey, and different variables were associated with its presence. This prevalence is higher than the 35.7% reported for schoolchildren from private and public schools in Brazil [10, 25] but similar to the 47.6% reported for schoolchildren in Uganda [26]. Higher prevalences have been reported in people 10 years of age and older in Chad (64.1%) [27]; in eight-year-old children in Sri Lanka (49% [self-reported] to 53% [reported by parents]) [28]; and in eight- to ten-year-old children in Western Cape, South Africa, in the two months prior to the study (70%) [29]. These differences in dental pain prevalence can be attributed to various causes, including the development context in different countries and locations, disease level variations between the studied populations, health system response to a population's oral health needs, and the methodologies used in each study.

In a previous study on parent/guardian influence and responsibility for child health, parents acknowledged the benefits of brushing teeth with fluoride toothpaste. Even so, the parents of children that had experienced caries and dental pain believed that the causes were beyond their control, due to genetics, attributed to health problems intrinsic to childhood, or just random [30].

The positive impact of greater mother's age on dental pain may be due to the information and experience older mothers have accumulated throughout their lives. This coincides with a study in the United Kingdom indicating that greater mother's age favorably affects child cognitive, behavioral, and health condition [31].

Describing the association between an individual's pain and their socioeconomic level (based here on the socioeconomic variables remaining in the final model: housing characteristics and automobile in household) can be quite complex since socioeconomic position is a multifactorial construct [32]; however, a number of hypotheses have been reported to plausibly explain this association [33]. In school-age children, dental pain is largely of odontogenic origin. Addressing the causes of dental pain in Mexico can be problematic since the public health system offers only limited coverage for oral health treatments. The private sector is the only source of adequate treatment, although this requires substantial out-of-pocket expenditure.

Fried food intake was associated with a greater possibility of dental pain in the studied schoolchildren. A possible explanation for this is the greater presence of dentobacterial plaque caused by intake of fried, high carbohydrate foods between regular meals. This in turn can directly affect teeth and gums exposed for long periods [34]. In conjunction with poor oral health practices, this could explain the greater possibility of dental pain in this group of children. A number of studies document the effects of sweet and salty snacks on dental caries, one of the main causes of dental pain [35]. Mitigating the effect of poor health habits can be done by promoting greater physical activity, higher fruit and vegetable intake, and school breakfasts [36]. Although programs promoting healthy habits do exist in Mexico, schoolchildren are exposed to a number of nutritional risks, such as purchasing power, skipping a meal (usually breakfast), and junk food for sale near schools [37]. Indeed, the most prevalent diet among schoolchildren in Mexico is one of fruit, salty fried snacks, candy, and pastries [38]. In the present results, the schoolchildren who consumed fruit had a decreased probability of developing dental pain, which may be explained by a healthier lifestyle, including a lower intake of cariogenic foods [39]. This coincides with a study done in the United States indicating that people with more severe caries also had poor oral hygiene and consumed high levels of sugars and fats and low levels of fruits and vegetables [40]. Further research is needed in Mexico to better understand the relationship between lifestyle and oral health.

Brushing of teeth mechanically removes and disorganizes dental biofilm, limiting its ability to cause disease. It is the most cost effective dental care instruction, is widely recommended for maintaining oral health, and is a habit best inculcated at an early age [41]. In the present results, lower brushing frequency was associated with the presence of dental pain, which can be explained by a lower frequency of caries (and therefore dental pain) in those children with better oral hygiene habits. Mouthwash is normally seen as a positive addition to oral hygiene [42], but in the present results dental pain frequency was lower in the schoolchildren whose parents stated they did not use mouthwash or did not know about it; no explanation is immediately apparent for this result.

Health literacy is the “ability to obtain, process and understand information” and the services needed to make adequate health decisions [43]. Some studies have documented a relationship between health knowledge and clinical results [44], but few have addressed the association between health knowledge and oral health [43]. Parental attitudes can have direct repercussions on child oral health, as demonstrated in a study showing that limited oral health knowledge among parents was associated with negative attitudes towards oral health, low frequency of healthy behaviors, and worse oral health in children [44]. The present results, however, suggested an association between dental pain in schoolchildren and high to regular knowledge of oral health practices among parents. These parents may more readily take their child for dental treatment, which can cause discomfort identified by the child as dental pain, even though it is transitory and forms part of a dental therapeutic procedure.

Parents are vital to child development because they are responsible for seeking timely treatment for any disorders that might occur in the child. Oral health is a component of overall good health since it can affect taste, mastication, speech, and facial expression [45]. Identifying the factors that influence the association between parent perception and child oral health could help primary care givers and oral health service providers (e.g., health promotors, dentists) to understand why schoolchildren do not receive early attention for dental problems at home or with a general dentist. This is particularly important because this association often results in children requiring more invasive treatments [46]. Parent perceptions of their child's oral health condition as good/very good or regular were associated with a lower dental pain frequency than the most affected group. Perhaps clinical conditions (e.g., color and structure) and symptoms influence parent perception, motivating them to make the decision to seek preventative and/or curative care, thus anticipating problems such as dental caries [47].

The present study has three main limitations. The first is that, due to its cross-sectional design, the temporality between variables is not accurate (temporality ambiguity), potentially causing reversed directions, and representing a possible inherent bias. Information selection bias (i.e., memory) is the second limitation; dental pain was explored over a 12-month period prior to the survey, affecting memory accuracy, be it in the individual or in cooperation with the parent/guardian-child. The third limitation is that the study does not include all of the schoolchildren in the region, meaning it is not representative of the state's overall school population. Future research should now address the source(s) of dental pain in schoolchildren.

5. Conclusions

Overall, dental pain prevalence in the sampled population was high: 1 in every 2 children had experienced dental pain in the 12 months prior to the survey. Among the diverse factors affecting this prevalence, socioeconomic condition (housing characteristics and presence of an automobile in the home) suggested the presence of inequalities in oral health status and access to dental care among the studied children. Future studies should now evaluate the response of oral health services to people with dental pain.

Conflicts of Interest

The authors declare that they have no conflicts of interest.

Authors' Contributions

Mauricio Escoffié-Ramirez, Leticia Ávila-Burgos, Elena Saraí Baena-Santillan, and Carlo Eduardo Medina-Solís were involved in the design and development of the study, did the analysis of the data, and wrote the first draft of the manuscript. Fernando Aguilar-Ayala, Edith Lara-Carrillo, Mirna Minaya-Sánchez, Martha Mendoza-Rodríguez, and María de Lourdes Márquez-Corona were involved in the conception of the paper and analysis and interpretation of the results. All the authors were involved in the critical review and made intellectual contributions; they also accepted the final version.

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