Association between Tooth Agenesis and Skeletal Malocclusions.

OBJECTIVES: The aim of this study was to evaluate the association between tooth agenesis and skeletal malocclusions in Brazilian non-syndromic orthodontic patients.
MATERIAL AND METHODS: Pretreatment orthodontic records of 348 patients of both genders and with various skeletal malocclusions were examined. Tooth agenesis was evaluated in panoramic radiographs. Angular measurements were taken from lateral cephalometric radiographs to classify the patient's malocclusion as skeletal Class I, Class II and Class III. Subjects were divided into 2 groups, "with tooth agenesis" and "without tooth agenesis". Chi-square or Fisher exact test was used to compare categorical data. ANOVA with Tukey's post-test was used for means comparisons. An alpha of 5% was established.
RESULTS: From 348 analysed patients, 28 presented tooth agenesis. There was no difference between genders (P = 0.27) nor mean age (P = 0.16). The most prevalent skeletal malocclusion was Class I (63.11%), followed by Class II (25.94%), and Class III (10.95%). The mean of congenitally missing teeth was 1.3 (SD 0.13). Thirteen subjects had premolar agenesis, 13 upper lateral incisor agenesis, 4 lower incisor agenesis and 2 molars agenesis. The group with tooth agenesis presented A point-nasion-B point (ANB) angle smaller (1.66 [SD 2.52]) than the group without tooth agenesis (2.86 [SD 2.49]) (P = 0.01). ANB angle had a negative correlation with the number of congenitally missing teeth (P = 0.039; r = -0.39).
CONCLUSIONS: Tooth agenesis is associated with a smaller A point-nasion-B point angle and is negatively correlated with the number of congenitally missing teeth.

INTRODUCTION

Tooth agenesis (or congenitally missing tooth) is one of the most common congenital anomaly in humans. It is characterized by developmental absence of one or more primary or permanent teeth. Permanent tooth is more commonly affected than primary tooth [1,2]. The most common absent teeth are third molars, followed by premolars and upper lateral incisors [3,4]. Reports on the overall prevalence of permanent tooth agenesis vary substantially. In Caucasians, the reported frequency of tooth agenesis, excluding third molars, range from 5.5% in European population, 3.9% in North American population and 6.3% in Australian population [5].

Tooth agenesis can be classified into syndromic and non-syndromic. Syndromic tooth agenesis refers to complex developing syndromes associated with a congenitally missing tooth or teeth [6]. More than 60 syndromes catalogued in Online Mendelian Inheritance in Man (OMIM) are associated with agenesis. Non-syndromic tooth agenesis involves a congenitally missing tooth in an isolated form, without an association with any other major birth defects [7].

In the past few years, some studies have evaluated the association between specifics craniofacial patterns and non-syndromic tooth agenesis [8-18], however, the results pertaining to skeletal malocclusions with tooth agenesis are controversial. Some authors did not find a significant association between tooth agenesis and malocclusions [10,15,18], while other authors observed association or tendency with skeletal Class II malocclusion [13,14,16]. On the other hand, other studies observed that tooth agenesis is associated or tendency with skeletal Class III malocclusion [8,9,11,17]. Therefore, the aim of this study was to evaluate if non-syndromic tooth agenesis is associated with skeletal malocclusions in Brazilian non-syndromic pre-orthodontic patients.

MATERIAL AND METHODS

Sample

The study protocol was reviewed and approved by the Ethics Committee of the School of Dentistry Ribeirão Preto, University of São Paulo (CAAE 50765715.3.0000.5419). Informed consent was obtained from all participating individuals or parents/legal guardians during the first orthodontic consultation.

Pre-orthodontic treatment panoramic and lateral cephalometric radiographs from patients treated from 2000 to 2015, at the Orthodontic clinic of the School of Dentistry of Ribeirão Preto - University of São Paulo, were evaluated.

The sample consisted of 348 untreated individuals, self-reported Caucasian, aged 8 to 42 years with various skeletal malocclusions. The exclusion criteria included patients younger than 8 years old, not self-reported Caucasian, with craniofacial syndromes or chronic conditions, history of facial trauma or facial surgery, previous orthodontic treatment, records with missing radiographs, and radiographs with poor quality or missing landmarks. One case with cleft lip and palate was found and excluded from the sample.

Determination of tooth agenesis phenotype

Cases of tooth agenesis were clearly evident from the panoramic radiographs alone. All panoramic radiographs were examined by the same professional (AMGC) using the same protocol [3,4].

The inclusion criterion was that at least one permanent tooth was affected, excluding third molars. Tooth agenesis was defined based on the age of subjects and when initial tooth formation should be visible in the radiographs [3,4]. In accord with the mentioned criteria, second premolar agenesis was only considered on patients older than 8 years old [4].

Determination of skeletal malocclusion

Pretreatment lateral cephalometric radiographs were hand traced and measured by two orthodontists previously trained (MANM and FLR, inter-observer agreement 0.95).

The following landmarks were used for cephalometric analysis: point A (A), point B (B), sella (S), and nasion (N). Sagittal skeletal discrepancies were assessed using angular measurements: angle between sella, nasion and subspinale point A (SNA), angle between sella, nasion and supramentale point B (SNB), and angle between subspinale point A, nasion and supramentale point B (ANB). Then, the total sample was classified as skeletal Class I malocclusion (0° < ANB < 4°), skeletal Class II malocclusion (ANB ≥ 4°), and skeletal Class III malocclusion (ANB ≤ 0°).

Statistical analysis

Data were analysed using Epi Info 7 and Graph Pad Prism 5.0a. The Shapiro-Wilk test was used to verify the normality of the data. The comparisons were performed between the groups ‘with tooth agenesis’ and ‘without tooth agenesis’. Tooth agenesis evaluation was performed according to the type of congenitally missing teeth (upper lateral incisors, premolars and others congenitally missing teeth) and according to the affected arch (maxillary and mandible). The group without tooth agenesis was used as a comparison group.

Odds ratio calculations and Chi-square or Fisher’s exact tests were used to evaluate the association between tooth agenesis and skeletal malocclusion. Parametric data were expressed as mean and standard deviation (M [SD]). To compare the difference between the means of the angular measurements, t-test was used. The Pearson coefficient test was used to evaluate the degree of the correlation between number of congenitally missing teeth and angular measurements. The established alpha was 5%.

RESULTS

Three hundred forty-eight subjects were evaluated. The mean age was 15.2 (6.69) years. Twenty-eight (8.04%) patients presented at least one tooth agenesis.

Forty-five teeth were congenitally missing. The number of congenitally missing teeth ranged between 1 to 4 and the mean was 1.3 (0.13). Thirteen (3.75%) subjects had premolar agenesis, 13 (3.75%) upper lateral incisor agenesis, 4 (1.15%) lower incisor agenesis and 2 (0.58%) molars tooth agenesis.

The characteristics of the studied population are presented in the Table 1. The mean age and gender distribution were not different between patients with and without tooth agenesis (P > 0.05).

Table 1

Characteristics of the studied population

Variable	Without tooth agenesis	With tooth agenesis	P-value
Mean age (SD)	15.35 (6.87)	13.5 (3.81)	0.16
Gender, N (%)
Male	129 (90.85)	13 (9.15)	0.27
Female	190 (92.68)	15 (7.32)

No statistically significant P > 0.05 (t-test and Chi-square test).

SD = standard deviation; N = number.

Two hundred nineteen (63.11%) patients presented skeletal Class I malocclusion, 90 (25.94%) patients skeletal Class II malocclusion, and 38 (10.95%) patients skeletal Class III malocclusion. The distribution of tooth agenesis subgroups according to the skeletal malocclusion is presented in the Table 2. Skeletal Class III malocclusion was associated with premolar tooth agenesis (P = 0.039).

Table 2

Tooth agenesis subgroups’ distribution according to the skeletal profile

Groups	Skeletal malocclusion, N (%)			P-value
	Class I	Class II	Class III
Without tooth agenesis	199 (62.4)	87 (27.3)	33 (10.3)	Reference
All types of tooth agenesis	20 (71.4)	3 (10.7)	5 (17.9)	0.11
Type of congenitally missing tooth
Premolar agenesis	8 (61.5)	1 (7.7)	4 (30.8)	0.039a
Upper lateral incisor agenesis	9 (69.2)	2 (15.4)	2 (15.4)	0.597
Others tooth agenesis	4 (100)	0 (0)	0 (0)	0.302
Affected arch
Maxillary tooth agenesis	15 (68.2)	3 (13.6)	4 (18.2)	0.256
Mandible tooth agenesis	7 (63.6)	1 (9.1)	3 (27.3)	0.127

aStatistically significance difference (P < 0.05), Chi-square test.

N = number.

All comparisons were performed with the group without tooth agenesis. Others tooth agenesis was represented by two cases of molar agenesis and two cases of lower incisor agenesis.

Table 3 demonstrates the mean of the cephalometric measurements SNA, SNB and ANB according to the groups. The ANB measurement was smaller in the group with tooth agenesis (P = 0.01).

Table 3

Cephalometric measurements distribution according to the group

Measurements	Without tooth agenesis Mean (SD)	Tooth agenesis Mean (SD)	P-value
SNA	81.54 (3.89)	81.26 (3.62)	0.71
SNB	78.66 (3.79)	79.58 (3.59)	0.21
ANB	2.86 (2.49)	1.66 (2.52)	0.01a

aStatistically significance difference (P < 0.05), Student’s t-test.

SNA = angle between the sella, nasion and subspinale point A; SNB = angle between the sella, nasion and supramentale point B; ANB = angle between subspinale point A, nasion and supramentale point B; SD = standard deviation.

The cephalometric measurements SNA, SNB and ANB angles were also evaluated according to the affected arch. There was no statistical difference among the groups (P > 0.05).

The evaluation according to the type of congenitally missing tooth demonstrated a statistical difference in the ANB angle for the premolar tooth agenesis (P = 0.01). The mean ANB measure in the premolar tooth agenesis group was 1.11 (2.79).

The correlation between the number of congenitally missing teeth and the SNA, SNB and ANB angles were performed. There was no correlation between SNA and SNB angles and the number of congenitally missing teeth. The ANB angle had a negative correlation with the number of congenitally missing teeth (P = 0.039; r = -0.39) (Figure 1).

Figure 1

Correlation between subspinale point A, nasion and supramentale point B angle and the number of congenitally missing teeth.

DISCUSSION

Some researches in dental development have been focused in the understanding of the aetiology of the tooth agenesis. In the past few years much progress has been made to identify the developmental basis of tooth formation [19,20]. Tooth agenesis has been associated with other developmental dental anomalies [3,21], non-syndromic oral cleft [22-24], cancer [25,26], and specifics craniofacial morphologies [17,27,28]. These association studies suggested that, in some instances, tooth agenesis and these conditions presented a similar genetic background.

Skeletal Class III malocclusion has been associated with tooth agenesis [8,9,11,17], which corroborates with present study that found an association between smaller value of the ANB angle and tooth agenesis. This association led us to raise the hypothesis that, in some instances, the same genes are involved in the aetiology of the both conditions.

Although there is some evidence of the genetic component in the aetiology of non-syndromic tooth agenesis [7,25,29,30,31-33] and skeletal Class III [34-39], there are no studies that evaluated the genetic aetiology of this condition. In the past two decades, genetic polymorphisms in some genes have been extensively studied in the tooth agenesis context. Genetic variations in growth factors including FGF3, FGF10, and FGFR2 [25], FGFR1 [40], BMP2 [7], BMP4 [31,33] and TGFb1 [32] have been associated with non-syndromic tooth agenesis. These growth factors genes have been implicated in the regulation of diverse developmental events, including tooth development and are also possibly involved in the mandible/maxilla growth and development.

An interesting finding observed in this study is that the number of congenitally missing teeth was negatively correlated with the ANB angle measurements. Previous studies also observed that severe forms of tooth agenesis are associated with skeletal Class III [8,11], in which each additional congenitally missing tooth decreases the ANB angle [11]. These findings suggested that the same aetiological factors involved in severe cases tooth agenesis establishment are involved in the mandible/maxilla development.

In the evaluation according to the type of congenitally missing teeth, there is a preferential association between premolar agenesis and the tendency towards skeletal Class III malocclusion. It is important to emphasize that genetic studies performed in patients with non-syndromic tooth agenesis observed that some genes are involved only in the aetiology of premolar agenesis [9]. Based on these findings, it can be hypothesize that these genes are involved in the mandible and/or maxilla development.

Since different types of congenitally missing teeth have a different genetic aetiology, studies should attempt to the type of affected teeth. In a Turkish population, third molar agenesis was associated with skeletal Class III malocclusion [12]. In the present study, the third molar agenesis was excluded due the young age of the included population.

A study by Hirukawa et al. [41] suggested that maxillary tooth agenesis might be involved in the skeletal Class III malocclusion, while Kreczi et al. [42] stated that tooth agenesis may have a negative influence on the sagittal development of a jaw. In the present study, there was no preferential association according to the dental arch. This might be explained by small sample size of this study, but it is also possible that the difference according to the dental arch does not exist.

CONCLUSIONS

Tooth agenesis is associated with a smaller subspinale point A, nasion and supramentale point B angle, which is correlated with number of congenitally missing teeth. The results also suggest that premolar agenesis is involved with Class III malocclusion.