Determining the frequency of morphological characteristics in a sample of Brazilian children<sup>,</sup>

Perrone, Eduardo; Zanolla, Thais Arbocese; Fock, Rodrigo Ambrosio; Perez, Ana Beatriz Alvarez; Brunoni, Decio

doi:10.1016/j.jped.2016.12.010

Abstract

Objective:

To establish the frequency of 82 morphological features in a sample of Brazilian children (between 3 and 13 years old), to understand the influence of age, gender, and ethnicity.

Methods:

This was a cross-sectional study that evaluated 239 children with typical development (between 3 and 13 years old) regarding the presence of 82 morphological characteristics. A previously described protocol, based on the London Dysmorphology Database, was applied to evaluate the sample. This protocol was culturally adapted to Brazilian Portuguese.

Results:

The frequency of 82 morphological characteristics was established in the sample; of 82 characteristics, 50% were considered morphological anomalies (frequency less than 4%). At least 25% of the sample presented more than one minor morphological anomaly. Age was shown to influence the frequency of the following morphological characteristics: widow's peak, prominent antihelix, prominent upper lip, irregular or crowded teeth, and clinodactyly, but had no influence on the frequency of minor morphological anomalies. Gender influenced dysplastic ears and attached earlobe, but had no influence on the frequency of minor morphological anomalies; ethnicity showed influence on camptodactyly and prominent antihelix. A statistically significant divergence was observed regarding 43 of the 73 morphological characteristics that could be compared with literature data (58.9%).

Conclusions:

The study determined the frequency of 82 morphological characteristics in 239 children with typical development. Age was the variable that showed more influence on the frequency of morphological characteristics, and comparison with literature data showed that the frequency depends on variables such as age and ethnicity.

KEYWORDS
Anomalies; Morphological; Frequency; Brazilian; Children

Resumo

Objetivo:

Estabelecer a frequência de 82 características morfológicas em uma amostra de crianças brasileiras (entre três e 13 anos), para entender a influência da idade, do sexo e da etnia.

Métodos:

Estudo transversal. Avaliamos 239 crianças com desenvolvimento típico (entre três e 13 anos), em relação à presença de 82 características morfológicas. Aplicamos um protocolo descrito anteriormente, baseado no London Dysmorphology Database, para avaliar nossa amostra. Esse protocolo foi culturalmente adaptado ao português do Brasil.

Resultados:

A frequência de 82 características morfológicas foi estabelecida em nossa amostra; de 82 características, 50% foram consideradas anomalias morfológicas (frequência inferior a 4%). Pelo menos 25% da nossa amostra apresentaram mais de uma anomalia morfológica menor. A idade mostrou influência na frequência das seguintes características morfológicas: "bico de viúva", "anti-hélice proeminente", "lábio superior proeminente", "dentes irregulares ou encavalados" e "clinodactilia", mas não teve influência na frequência de anomalias morfológicas menores. O sexo mostrou influência nas seguintes características: "orelhas displásicas" e "lóbulo da orelha aderente", mas não teve influência na frequência de anomalias morfológicas menores; a etnia mostrou influência na "camptodactilia" e "anti-hélice proeminente". Houve divergência (estatisticamente significativa) em 43 características morfológicas de 73 que pudemos comparar com os dados da literatura (58,9%).

Conclusões:

Estabelecemos a frequência de 82 características morfológicas em 239 crianças com desenvolvimento típico. A idade foi a variável que mostrou maior influência na frequência de características morfológicas e a comparação com dados da literatura mostrou que a frequência depende de variáveis como idade e etnia.

PALAVRAS-CHAVE
Anomalias; Morfológicas; Frequência; Brasileiras; Crianças

Introduction

A morphological anomaly is a phenotype that is substantially different from that observed in a reference population.¹1 Hennekam RC, Biesecker LG, Allanson JE, Hall JG, Opitz JM, Temple IK, et al. Elements of morphology consortium. Elements of morphology: general terms for congenital anomalies. Am J Med Genet A. 2013;161A:2726-33. This difference can be defined as the occurrence of the phenotypic characteristic in less than 2.5% of the population.¹1 Hennekam RC, Biesecker LG, Allanson JE, Hall JG, Opitz JM, Temple IK, et al. Elements of morphology consortium. Elements of morphology: general terms for congenital anomalies. Am J Med Genet A. 2013;161A:2726-33. Some authors consider a statistical threshold of 4% for its definition.²2 Marden PM, Smith DW, McDonald MJ. Congenital anomalies in the newborn infant, including minor variations. J Pediatr. 1964;64:357-71. Morphological anomalies are classified as major, when their presence results in medical consequences for the individual, and as minor, when they do not generate such effects.²2 Marden PM, Smith DW, McDonald MJ. Congenital anomalies in the newborn infant, including minor variations. J Pediatr. 1964;64:357-71. The presence of minor morphological anomalies is considered an indicator of an abnormal embryological development process; therefore, studies have already indicated a correlation between minor morphological and major anomalies.²2 Marden PM, Smith DW, McDonald MJ. Congenital anomalies in the newborn infant, including minor variations. J Pediatr. 1964;64:357-71.

3 Mehes K, Mestyan J, Knoch V, Vinceller M. Minor malformations in the neonate. Helv Pediatr Acta. 1973;28:47.^-⁴4 Leppig KA, Werler MM, Cann CI, Cook CA, Holmes LB. Predictive value of minor anomalies. I. Association with major malformations. J Pediatr. 1987;110:531-53.

Most studies on the frequency of morphological characteristics assessed newborns,²2 Marden PM, Smith DW, McDonald MJ. Congenital anomalies in the newborn infant, including minor variations. J Pediatr. 1964;64:357-71.

3 Mehes K, Mestyan J, Knoch V, Vinceller M. Minor malformations in the neonate. Helv Pediatr Acta. 1973;28:47.

4 Leppig KA, Werler MM, Cann CI, Cook CA, Holmes LB. Predictive value of minor anomalies. I. Association with major malformations. J Pediatr. 1987;110:531-53.^-⁵5 Tsai FJ, Tsai CH, Peng CT, Wu JY, Lien CH, Wang TR. Different race, different face: minor anomalies in Chinese newborn infants. Acta Paediatr. 1999;88:323-6. and it is known that morphological characteristics may change according to age.⁶6 Allanson JE, Hall JG, Hughes HE, Preus M, Witt RD. Noonan syndrome: the changing phenotype. Am J Med Genet. 1985;21:507-14.

7 Allanson JE. Rubinstein-Taybi syndrome: the changing face. Am J Med Genet. 1990;6:S38-41.

8 Allanson JE, O'Hara P, Farkas LG, Nair RC. Anthropometric craniofacial pattern profiles in Down syndrome. Am J Med Genet. 1993;47:748-52.

9 Allanson JE, Cole TR. Sotos syndrome: evolution of facial phenotype subjective and objective assessment. Am J Med Genet. 1996;65:13-20.

10 Allanson JE, Hennekam RC, Ireland M. De Lange syndrome. Subjective and objective comparison of the classical and mild phenotypes. J Med Genet. 1997;34:645-50.^-¹¹11 Allanson JE, Greenberg F, Smith AC. The face of Smith-Magenis syndrome: a subjective and objective study. J Med Genet. 1999;36:394-7.

The most recent survey on the frequency of morphological characteristics was carried out by Merks et al. in a sample of Dutch children aged between 8 and 14 years.¹²12 Merks JH, Ozgen HM, Cluitmans TL, van der Burg-van Rijn JM, Cobben JM, van Leeuwen FE, et al. Normal values for morphological abnormalities in school children. Am J Med Genet A. 2006;140A:2091-109.

There are no data on the frequency of morphological characteristics in a sample of Brazilian children. Additionally, the definition of a minor morphological anomaly involves a statistical concept. Based on these assumptions, this study aimed to determine the frequency of 82 morphological characteristics in a sample of children with typical development and to verify the influence of the variables age, gender, and ethnicity on their frequency.

Methods

Sample selection

The selected children met the following inclusion criteria: age between 3 and 13 years and typical developmental history, characterized by the absence of neuropsychomotor developmental delay and/or psychiatric disorders.

Statistical considerations

Considering a 95% confidence level and a 5% confidence interval, and based on previous literature data on the frequency of minor anomalies in the population,²2 Marden PM, Smith DW, McDonald MJ. Congenital anomalies in the newborn infant, including minor variations. J Pediatr. 1964;64:357-71.

3 Mehes K, Mestyan J, Knoch V, Vinceller M. Minor malformations in the neonate. Helv Pediatr Acta. 1973;28:47.^-⁴4 Leppig KA, Werler MM, Cann CI, Cook CA, Holmes LB. Predictive value of minor anomalies. I. Association with major malformations. J Pediatr. 1987;110:531-53. a sample of 200 children was estimated. To compensate for possible losses, the study included 239 children.

Categorical variables were described as frequencies. To compare the frequencies of the morphological characteristics with those already described, the Z-test was used to compare between two proportions.

To determine whether the frequency of each anomaly showed a statistically significant difference according to gender, age, and ethnicity, the chi-squared test or Fisher's exact test was used. The results with p ≤ 0.05 were considered significant. Statistical analysis was carried out using the SPSS software for statistical analysis (IBM Corp. Released 2011, IBM SPSS Statistics for Windows, Version 20.0, NY, USA).

Protocol use and morphological evaluation of the children

Children were evaluated according to a protocol containing 82 morphological characteristics based on the definition of the London Dysmorphology Database (LDDB), which lists approximately 2000 characteristics. The protocol used to evaluate the 82 characteristics has been previously used by Miles et al. to evaluate children with autism spectrum disorder (ASD).¹³13 Miles JH, Takahashi TN, Hong J, Munden N, Flournoy N, Braddock SR, et al. Development and validation of a measure of dysmorphology: useful for autism subgroup classification. Am J Med Genet A. 2008;146A:1101-16. This protocol is being validated for use in children with ASD in Brazil, and part of this process depends on its application in children with typical development. Thus, the authors chose to apply this protocol to the present sample.

The definition of some morphological characteristics was changed in relation to the previous definition given by the LDDB, after a consensus among four geneticists (authors of the study), aiming to make them more objective. The characteristics with the description after the cultural adaptation are shown in Table 1.

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Table 1
Frequency of morphological characteristics found.

For anthropometric data collection, a vertical anthropometer and a metric tape were used. During the morphological examination, the following were measured in addition to height; ears, hands, middle fingers, and middle toes. The curves used to define micro/macrotia; elongated/small feet; large/small hands; and elongated/short phalanges are those found in Smith's Recognizable Patterns of Human Malformation,¹⁴14 Jones KL, Jones MG, Casanelles MC. Smith's recognizable patterns of human malformation. 7th ed. Elsevier; 2013. using the ±2 SD (standard deviations) limit. A height-for-age measurement below the third percentile in the WHO curve was defined as short stature. The other characteristics were scored as absent or present.

The 239 children were evaluated by the first author of this study, who is also a geneticist, in two municipal schools in the city of Barueri (state of São Paulo, Brazil). It was decided to evaluate children from the public school system to prevent the ethnic selection bias that may occur in private schools.

Regulatory aspects

This study was submitted to and approved by the Research Ethics Committee of UNIFESP. Children were evaluated after parents or tutors gave their authorization by signing the free and informed consent form.

Results

Overall sample characteristics

A total of 239 children aged 3 to 13 years were evaluated in municipal schools of the city of Barueri (SP).

The mean age of the sample was 7 years and 9 months ± 2 years and 10 months, with a median of 7 years and 6 months. The sample comprised 111 male subjects (46.4%). Regarding ethnicity, the distribution of the analyzed subjects consisted of 62.3% white (n = 149), 25.9% mixed-race (n = 62), 10.9% African descendants (n = 26), and 0.8% native Brazilians (n = 2).

Determination of the frequency of morphological characteristics

Table 1 shows the frequencies of each assessed morphological characteristic.

Of the 82 morphological characteristics evaluated, 41 (50%) showed a frequency <4%, and could be considered as morphological anomalies. Therefore, one minor anomaly was observed in 42 subjects (17.5%), two anomalies in 12 subjects (5%), and three anomalies in six subjects (2.5%). Therefore, 60 children (25%) had at least one minor anomaly.

Determination of the frequency of morphological characteristics by gender

Of the 82 evaluated characteristics, only two showed frequencies with significant differences when divided by gender: dysplastic ears (20.7% [13.6-28.2%] in 111 male subjects vs. 7% [2.58-11.4%] in 128 female subjects; p = 0.002) and attached earlobe (10.8% [5.03-16.57%] in 111 male subjects vs. 21.2% [14.1-28.28%] in 128 female subjects; p = 0.032.

Determination of the frequency of morphological characteristics by age group

The 239 study subjects were grouped into five groups with different age ranges: group I, from 3 to 5 years; Group II, from 5 years and 1 month to 7 years; Group III, from 7 years and 1 month to 9 years; Group IV, from 9 years and 1 month to 11 years; and group V, from 11 years and 1 month to 13 years.

Five characteristics showed significant frequency variations depending on age: widow's peak, prominent antihelix, prominent upper lip, crowded teeth, and clinodactyly.

The first of the characteristics showed a statistically significant difference when comparing group II with group III (1.6% vs. 12.5%; p = 0.032); the second characteristic, when comparing groups I vs. II; II vs. III; III vs. IV (14.8% vs. 31.7% vs.57.5% vs. 34.2%; p < 0.05 in all comparisons); the third, when comparing groups II x III (11.1% vs. 0.0%; p = 0.041); the fourth, when comparing groups II vs. III (4.2% vs. 17.5%; p = 0.044); and the fifth, when comparing groups I vs. II (29.6% vs. 12.7%; p = 0.024).

Age did not influence the frequency of individuals who had at least one minor morphological anomaly. Group I had 22.2% of subjects with at least one minor anomaly; group II, 19.6%; group III, 30.7%; group IV, 32.4%; and group V, 36.3% (p = 0.451).

Determination of the frequency of morphological characteristics by ethnicity

The proportion of individuals with at least one morphological anomaly did not present a statistically significant difference between the ethnic groups; 23.9%, 30.7%, and 34.4% of white, African-descendants, and mixed-race individuals, respectively, presented at least one minor morphological anomaly (p = 0.407). The only characteristics that showed variations according to the ethnicity were: prominent antihelix (30.2% vs. 23.0% vs. 48.3% vs. 0% in white, African descendants, mixed-race, and native Brazilians, respectively; p = 0.026), and "camptodactyly" (0% vs. 7.7% vs. 1.6% vs. 0% in white, African descendants, mixed-race, and native Brazilians, respectively; p = 0.025).

Discussion

In general, a frequency of at least 25% of individuals with at least one morphological anomaly was observed in the present sample. The frequencies of the morphological characteristics, when compared with those already described in the literature, showed discrepancies. When stratifying children by age, ethnicity, and gender, the variables age and ethnicity appeared to influence the frequency of characteristics.

Frequency of identified morphological characteristics

Considering the 4% threshold to define a morphological anomaly, only 41 of the assessed characteristics could be considered as such. Most of these characteristics (39) are minor morphological anomalies, except upper lip cleft non-midline and short stature, which may have clinical implications and association with malformations and skeletal dysplasias, respectively, being considered major morphological anomalies.¹²12 Merks JH, Ozgen HM, Cluitmans TL, van der Burg-van Rijn JM, Cobben JM, van Leeuwen FE, et al. Normal values for morphological abnormalities in school children. Am J Med Genet A. 2006;140A:2091-109.

In the present study, 25% of the sample had at least one minor anomaly.

Marden et al.,²2 Marden PM, Smith DW, McDonald MJ. Congenital anomalies in the newborn infant, including minor variations. J Pediatr. 1964;64:357-71. when evaluating newborns, found a prevalence of 14.2% of individuals with at least one minor morphological anomaly without an associated major morphological anomaly; Mèhes et al.,³3 Mehes K, Mestyan J, Knoch V, Vinceller M. Minor malformations in the neonate. Helv Pediatr Acta. 1973;28:47. a prevalence of 16.3%; Leppig et al.,⁴4 Leppig KA, Werler MM, Cann CI, Cook CA, Holmes LB. Predictive value of minor anomalies. I. Association with major malformations. J Pediatr. 1987;110:531-53. a prevalence of 39.9%; and Tsai et al.,⁵5 Tsai FJ, Tsai CH, Peng CT, Wu JY, Lien CH, Wang TR. Different race, different face: minor anomalies in Chinese newborn infants. Acta Paediatr. 1999;88:323-6. a prevalence of 43.3% in Chinese newborns.

The difference in frequencies found between the studies can be justified by the number of characteristics assessed, the evaluation method, and the ethnicity of the assessed children.

The 41 characteristics that were not considered as morphological anomalies - as they were observed in over 4% of the present sample - are morphological variants or normal characteristics (frequency >50%).³3 Mehes K, Mestyan J, Knoch V, Vinceller M. Minor malformations in the neonate. Helv Pediatr Acta. 1973;28:47.^,⁴4 Leppig KA, Werler MM, Cann CI, Cook CA, Holmes LB. Predictive value of minor anomalies. I. Association with major malformations. J Pediatr. 1987;110:531-53.

Influence of the variables age, gender, and ethnicity on the observed characteristics

Data are scarce on the influence of gender on the morphological characteristics of individuals. Marden et al.²2 Marden PM, Smith DW, McDonald MJ. Congenital anomalies in the newborn infant, including minor variations. J Pediatr. 1964;64:357-71. did not address the question of the influence of gender on the morphological anomalies of the assessed newborns. Leppig et al.⁴4 Leppig KA, Werler MM, Cann CI, Cook CA, Holmes LB. Predictive value of minor anomalies. I. Association with major malformations. J Pediatr. 1987;110:531-53. also did not consider this issue; however, they stated that prominent heel, for instance, was an anomaly found only in girls.

In contrast with Leppig et al.⁴4 Leppig KA, Werler MM, Cann CI, Cook CA, Holmes LB. Predictive value of minor anomalies. I. Association with major malformations. J Pediatr. 1987;110:531-53. and Marden et al.,²2 Marden PM, Smith DW, McDonald MJ. Congenital anomalies in the newborn infant, including minor variations. J Pediatr. 1964;64:357-71. Tsai et al.⁵5 Tsai FJ, Tsai CH, Peng CT, Wu JY, Lien CH, Wang TR. Different race, different face: minor anomalies in Chinese newborn infants. Acta Paediatr. 1999;88:323-6. emphasized that variables such as gender, maternal age, and gestational age did not influence the frequency of anomalies found in their sample. The influence of gender on morphological variants was not assessed in any of them.

The present study demonstrated that, of the 82 morphological characteristics assessed, only two showed a statistically significant difference when considering gender: dysplastic ears and attached earlobe. These two characteristics, due to their frequency, would be considered morphological variants. For all other morphological variants and morphological anomalies, no influence of gender was observed on the identified frequencies.

In short, gender is a variable that does not appear to influence the morphological characteristics considered morphological anomalies.

Regarding the influence of the age range on the frequency of the assessed characteristics, it is known that genetic syndrome phenotypes, as well as the individuals' morphological characteristics, change over time⁶6 Allanson JE, Hall JG, Hughes HE, Preus M, Witt RD. Noonan syndrome: the changing phenotype. Am J Med Genet. 1985;21:507-14.

7 Allanson JE. Rubinstein-Taybi syndrome: the changing face. Am J Med Genet. 1990;6:S38-41.

8 Allanson JE, O'Hara P, Farkas LG, Nair RC. Anthropometric craniofacial pattern profiles in Down syndrome. Am J Med Genet. 1993;47:748-52.

9 Allanson JE, Cole TR. Sotos syndrome: evolution of facial phenotype subjective and objective assessment. Am J Med Genet. 1996;65:13-20.

10 Allanson JE, Hennekam RC, Ireland M. De Lange syndrome. Subjective and objective comparison of the classical and mild phenotypes. J Med Genet. 1997;34:645-50.^-¹¹11 Allanson JE, Greenberg F, Smith AC. The face of Smith-Magenis syndrome: a subjective and objective study. J Med Genet. 1999;36:394-7. ; however, none of the aforementioned studies allowed the determination of the age group interference on the frequency of the identified morphological characteristics.

The present study was a pioneer in evaluating the influence of this variable. All characteristics that showed statistically significant variations in frequency according to age were morphological variants. The characteristics that showed any variation in their frequency according to age were: widow's peak, prominent antihelix, prominent upper lip, crowded teeth, and clinodactyly.

The onset of the characteristic crowded teeth after 7 years of age is perhaps due to the age group, when deciduous teeth start to be replaced by permanent dentition.

The characteristics widow's peak and prominent antihelix presented increased frequency with age. This may reflect the fact that some characteristics, even though they may be present from birth, are easier to identify in older age groups. In contrast, clinodactyly is more easily perceived in younger age groups.

Merks et al.,¹²12 Merks JH, Ozgen HM, Cluitmans TL, van der Burg-van Rijn JM, Cobben JM, van Leeuwen FE, et al. Normal values for morphological abnormalities in school children. Am J Med Genet A. 2006;140A:2091-109. when comparing the frequency of characteristics found in their study on schoolchildren with the frequency identified in previous studies on newborns, also concluded that there is an important influence of age on the individual's phenotype.

These findings show that studies on the frequency of morphological characteristics with larger samples in specific age groups are important to determine what is or what is not considered a morphological anomaly for that specific age group.

All characteristics that varied according to age range were previously considered as morphological variants. Age did not influence the frequencies observed for minor morphological anomalies.

Ethnic aspects are noteworthy, since the morphological characteristics of skin color and facial features are used to categorize what the literature calls ethnicity and currently, through genomic studies, as ancestry.

Demographic statistics use the self-declared skin color as an indicator of ancestry. Thus, according to data from the Brazilian Institute of Geography and Statistics (Instituto Brasileiro de Geografia e Estatística [IBGE], 2010 census),¹⁵15 IBGE - Instituto Brasileiro de Geografia e Estatística. Available from: http://www.ibge.gov.br/home/estatistica/populacao/censo2010/caracteristicas_religiao_deficiencia/caracteristicas_religiao_deficiencia_tab_xls.shtm http://www.ibge.gov.br/home/estatistica/populacao/censo2010/caracteristicas_religiao_deficiencia/caracteristicas_religiao_deficiencia_tab_xls.shtm [accessed 6.11.16].
http://www.ibge.gov.br/home/estatistica/... the Brazilian population consists of 47.7% of white; 43.1% of mixed-race; 7.6% of African descendants; 1.1% of Asian descendants; and 0.4% of native Brazilian individuals. The use of the chi-squared test of adherence indicated that there was a difference between the distribution of the present sample regarding ethnicity in relation to the Brazilian population (p < 0.001).

Such difference is predictable, since in the present study ethnic designation was derived from observation and physical examination, whereas that of IBGE is self-reported. In turn, the miscegenation of the Brazilian population is considered one of the widest in the world, and information on the morphological phenotype, either determined by physical characteristics or self-declared, is not a good predictor of genomic ancestry.¹⁶16 Parra FC, Amado RC, Rocha J, Antunes C, Pena SD. Color and genomic ancestry in Brazilians. Proc Natl Acad Sci USA. 2003;100:177-82.^,¹⁷17 Pimenta JR, Zuccherato LW, Debes AA, Maselli L, Soares RP, Moura Neto RS, et al. Color and genomic ancestry in Brazilians: a study with forensic microsatellites. Hum Hered. 2006;62:190-5.

The absence of a statistically significant difference between the proportion of individuals with morphological anomalies, when considering ethnicity, was expected, since morphological anomalies represent intrinsic developmental alterations and there would be no reason for them to predominate in a particular ethnicity. The fact that only two of the 82 morphological features showed significant differences when stratified by ethnicity can be justified by the evaluator's ethnic considerations when defining characteristics (e.g., thick lower lip).

Comparison with the study by Merks et al.¹²12 Merks JH, Ozgen HM, Cluitmans TL, van der Burg-van Rijn JM, Cobben JM, van Leeuwen FE, et al. Normal values for morphological abnormalities in school children. Am J Med Genet A. 2006;140A:2091-109.

Data on the frequency of morphological characteristics in children's samples are scarce in the literature.

In this sense, the present data are better compared with those by Merks et al.¹²12 Merks JH, Ozgen HM, Cluitmans TL, van der Burg-van Rijn JM, Cobben JM, van Leeuwen FE, et al. Normal values for morphological abnormalities in school children. Am J Med Genet A. 2006;140A:2091-109. The authors were pioneers in determining the frequency of morphological characteristics in a sample of the Dutch population with a median age of 11 years. Based on the data obtained in the assessment of 683 characteristics (using LDDB) in 923 children, frequencies were established, allowing the classification of the characteristics as morphological anomalies or variants.

Of the 73 morphological characteristics that were evaluated in both studies and had a frequency other than zero, in 43 (59%) a statistically significant difference was observed between the frequencies found in the present study and those in the study by Merks et al.¹²12 Merks JH, Ozgen HM, Cluitmans TL, van der Burg-van Rijn JM, Cobben JM, van Leeuwen FE, et al. Normal values for morphological abnormalities in school children. Am J Med Genet A. 2006;140A:2091-109. The characteristics showing any discrepancy are shown in Table 2.

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Table 2
Morphological characteristics found with significant statistical difference in comparisons with the study by Merks et al.¹²12 Merks JH, Ozgen HM, Cluitmans TL, van der Burg-van Rijn JM, Cobben JM, van Leeuwen FE, et al. Normal values for morphological abnormalities in school children. Am J Med Genet A. 2006;140A:2091-109.

Some hypotheses can be raised to clarify this discrepancy: the ethnic composition of Merks' sample was different from that of the present sample (the first one, consisting of white children, and the second one consisting of Brazilian children, the result of miscegenation); the age range of the evaluated patients was also different; the subjectivity and the continuity of some morphological characteristics makes their assessment observer-dependent.

Some examples will be used to illustrate the previously mentioned hypotheses.

Regarding the ethnic difference, it seems paradoxical that a lower frequency of children with thick lower lip was observed in the present sample when compared to that in Merks'¹²12 Merks JH, Ozgen HM, Cluitmans TL, van der Burg-van Rijn JM, Cobben JM, van Leeuwen FE, et al. Normal values for morphological abnormalities in school children. Am J Med Genet A. 2006;140A:2091-109. sample (8.8% vs. 14.5%, respectively). However, as the ethnical criterion was considered in the definition of a thick lower lip, and as this characteristic is subjective and continuous, in the sample only children who had a very thick lower lip were considered as presenting this characteristic, leading to its.

Tsai et al.,⁵5 Tsai FJ, Tsai CH, Peng CT, Wu JY, Lien CH, Wang TR. Different race, different face: minor anomalies in Chinese newborn infants. Acta Paediatr. 1999;88:323-6. after assessing 3345 Chinese newborns, verified that ethnicity influenced the frequency of morphological features (single palmar crease, ascending oblique palpebral fissure, and frontal bossing were observed at a frequency higher than 4% in a sample of Chinese newborns, being morphological variants in that sample).

The fact that some characteristics are continuous and subjective makes it difficult to define the limit to consider them as normal or altered, which may result in under- or overestimation of their frequencies.

This reasoning applies to clinodactyly, whose definition only states a "significant lateral bending, usually observed in the fifth finger". This characteristic was found in 16.7% of the assessed individuals, in contrast to 3.6% in the Merks et al.¹²12 Merks JH, Ozgen HM, Cluitmans TL, van der Burg-van Rijn JM, Cobben JM, van Leeuwen FE, et al. Normal values for morphological abnormalities in school children. Am J Med Genet A. 2006;140A:2091-109. sample. Probably, the latter authors considered higher degrees of clinodactyly during their evaluation. If the definition were clearer regarding the degree of acceptable bending, a similar frequency might have been observed.

Another assessed characteristic that showed high prevalence in the evaluated sample (65.7%) and could therefore be considered as a normal variant was overlapping toes (including clinodactyly). What led to this high prevalence was the inclusion of the term clinodactyly in the definition, since clinodactyly of the fifth toe in children is a common finding and has subjective evaluation.

The median age of the Merks et al.¹²12 Merks JH, Ozgen HM, Cluitmans TL, van der Burg-van Rijn JM, Cobben JM, van Leeuwen FE, et al. Normal values for morphological abnormalities in school children. Am J Med Genet A. 2006;140A:2091-109. sample was different from the present sample (11 years vs. 7 years and 6 months, respectively). The age group of the patients may have influenced the difference in some findings. When the present sample was divided into different age groups, the influence of the age variable was observed.

Of the 43 characteristics that presented frequency discrepancy between the studies, 31 (72.1%) could be considered as morphological variants, one (2.4%) as a normal characteristic, and 11 (25.5%) as morphological anomalies. Of the 30 characteristics that showed similar frequencies between the studies, 22 (73.3%) could be considered morphological anomalies and eight (26.7%) as variants. This indicates that the chance of finding a morphological variant in the group of patients with a discrepancy in the assessed data was eight-fold higher than in the group without discrepancy (OR: 8; p < 0.001; 95% CI: 2.7-23.0).

As the morphological variants are characterized by having a frequency above 4% and by a continuum of the characteristic, it is easy to understand they will be more difficult to evaluate, and therefore more susceptible to the discrepancy in frequency survey data in the literature.

Study limitations

The evaluation of the morphological characteristics was carried out by only one examiner and only once; therefore, it was not possible to rule out inter- or intraobserver variations. Additionally, sample calculation was made based on the presence of at least one minor morphological anomaly in the population and not on the frequency of each them in particular; therefore, the differences not found between the different groups (when stratified by gender, age group, ethnicity, and when compared to the literature) do not necessarily mean that the groups are equal, since the difference may not have been observed due to lack of statistical power to detect them.

The present study determined and classified morphological characteristics in a sample of the Brazilian population aged 3-13 years, so that it was possible to determine what is a variant of normality and what is a morphological anomaly for this population. It showed that some morphological characteristics need to be standardized to facilitate their identification.

The study also demonstrated there is an important influence of age and ethnicity on the frequency of some characteristics; studies with larger samples, associating age and ethnicity to the frequency of the identified characteristics, are necessary to adequately classify a morphological characteristic.

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Please cite this article as: Perrone E, Zanolla TA, Fock RA, Perez AB, Brunoni D. Determining the frequency of morphological characteristics in a sample of Brazilian children. J Pediatr (Rio J). 2017;93:592-600.
☆☆
Study carried out at Universidade Federal de São Paulo (UNIFESP), São Paulo, SP, Brazil.

References

¹
Hennekam RC, Biesecker LG, Allanson JE, Hall JG, Opitz JM, Temple IK, et al. Elements of morphology consortium. Elements of morphology: general terms for congenital anomalies. Am J Med Genet A. 2013;161A:2726-33.
²
Marden PM, Smith DW, McDonald MJ. Congenital anomalies in the newborn infant, including minor variations. J Pediatr. 1964;64:357-71.
³
Mehes K, Mestyan J, Knoch V, Vinceller M. Minor malformations in the neonate. Helv Pediatr Acta. 1973;28:47.
⁴
Leppig KA, Werler MM, Cann CI, Cook CA, Holmes LB. Predictive value of minor anomalies. I. Association with major malformations. J Pediatr. 1987;110:531-53.
⁵
Tsai FJ, Tsai CH, Peng CT, Wu JY, Lien CH, Wang TR. Different race, different face: minor anomalies in Chinese newborn infants. Acta Paediatr. 1999;88:323-6.
⁶
Allanson JE, Hall JG, Hughes HE, Preus M, Witt RD. Noonan syndrome: the changing phenotype. Am J Med Genet. 1985;21:507-14.
⁷
Allanson JE. Rubinstein-Taybi syndrome: the changing face. Am J Med Genet. 1990;6:S38-41.
⁸
Allanson JE, O'Hara P, Farkas LG, Nair RC. Anthropometric craniofacial pattern profiles in Down syndrome. Am J Med Genet. 1993;47:748-52.
⁹
Allanson JE, Cole TR. Sotos syndrome: evolution of facial phenotype subjective and objective assessment. Am J Med Genet. 1996;65:13-20.
¹⁰
Allanson JE, Hennekam RC, Ireland M. De Lange syndrome. Subjective and objective comparison of the classical and mild phenotypes. J Med Genet. 1997;34:645-50.
¹¹
Allanson JE, Greenberg F, Smith AC. The face of Smith-Magenis syndrome: a subjective and objective study. J Med Genet. 1999;36:394-7.
¹²
Merks JH, Ozgen HM, Cluitmans TL, van der Burg-van Rijn JM, Cobben JM, van Leeuwen FE, et al. Normal values for morphological abnormalities in school children. Am J Med Genet A. 2006;140A:2091-109.
¹³
Miles JH, Takahashi TN, Hong J, Munden N, Flournoy N, Braddock SR, et al. Development and validation of a measure of dysmorphology: useful for autism subgroup classification. Am J Med Genet A. 2008;146A:1101-16.
¹⁴
Jones KL, Jones MG, Casanelles MC. Smith's recognizable patterns of human malformation. 7th ed. Elsevier; 2013.
¹⁵
IBGE - Instituto Brasileiro de Geografia e Estatística. Available from: http://www.ibge.gov.br/home/estatistica/populacao/censo2010/caracteristicas_religiao_deficiencia/caracteristicas_religiao_deficiencia_tab_xls.shtm http://www.ibge.gov.br/home/estatistica/populacao/censo2010/caracteristicas_religiao_deficiencia/caracteristicas_religiao_deficiencia_tab_xls.shtm [accessed 6.11.16].
» http://www.ibge.gov.br/home/estatistica/populacao/censo2010/caracteristicas_religiao_deficiencia/caracteristicas_religiao_deficiencia_tab_xls.shtm
¹⁶
Parra FC, Amado RC, Rocha J, Antunes C, Pena SD. Color and genomic ancestry in Brazilians. Proc Natl Acad Sci USA. 2003;100:177-82.
¹⁷
Pimenta JR, Zuccherato LW, Debes AA, Maselli L, Soares RP, Moura Neto RS, et al. Color and genomic ancestry in Brazilians: a study with forensic microsatellites. Hum Hered. 2006;62:190-5.

Publication Dates

Publication in this collection
Nov-Dec 2017

History

Received
13 Aug 2016
Accepted
20 Dec 2016

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial No Derivative License, which permits unrestricted non-commercial use, distribution, and reproduction in any medium provided the original work is properly cited and the work is not changed in any way.

[1] ☆
Please cite this article as: Perrone E, Zanolla TA, Fock RA, Perez AB, Brunoni D. Determining the frequency of morphological characteristics in a sample of Brazilian children. J Pediatr (Rio J). 2017;93:592-600.

[2] ☆☆
Study carried out at Universidade Federal de São Paulo (UNIFESP), São Paulo, SP, Brazil.

Morphological characteristic	Frequency (%)	95% CI	n
Short stature^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	0.8	-0.33-1.93	239
Unusual hair whorl/pattern	20	14.65-25.35	215
Widow's peak	5.9	2.91-8.89	239
Frontal upsweep/cowlick^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	1.3	-0.14-2.74	239
Asymmetric ears	5	2.24-7.76	239
Dysplastic ears	13.4	9.08-17.72	239
Large ears (macrotia)^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	0.4	-0.4-1.2	239
Low-set ears^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	0.8	-0.33-1.93	239
Posteriorly rotated ears^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	0.8	-0.33-1.93	239
Ear pits^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	0	DNA	239
Prominent ears	9.6	5.87-13.33	239
Simple ears	9.2	5.54-12.86	239
Small ears/microtia^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	1.7	0.06-3.34	239
Prominent antihelix	33.9	27.9-39.9	239
Notched ear helix	8.4	4.8-11.92	239
Crumpled ear helix^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	0	DNA	239
Over-folded ear helix	5.4	2.53-8.27	239
Pits of ear helix^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	0	DNA	239
Prominent ear helix	9.6	5.87-13.33	239
Attached earlobe	16.3	11.62-20.98	239
Large/wide nose	15.1	10.56-19.64	239
Short/small nose^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	0.4	-0.4-1.2	239
Asymmetric face^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	0.8	-0.33-1.93	239
Coarse facial features^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	0	DNA	239
Flat face^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	1.3	-0.14-2.74	239
Mid-face hypoplasia^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	1.3	-0.14-2.74	239
Small face^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	2.1	0.28-3.92	239
Long/narrow face	5	2.24-7.76	239
Triangular face	4.2	1.66-6.74	239
Dimpled or grooved chin	3.8	1.38-6.22	239
Pointed chin^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	1.3	-0.14-2.74	239
Flat zygomatic region^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	1.3	-0.14-2.74	239
Prominent mandible/prognathism	2.9	0.77-5.03	239
Small mandible/micrognathia	2.5	0.52-4.48	239
Long philtrum	12.1	8.0-16.3	239
Prominent/deep philtrum	9.2	5.54-12.86	239
Short philtrum	8.4	4.88-11.92	239
Simple/absent/flat philtrum^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	2.1	0.28-3.92	239
Wide philtrum	2.9	0.77-5.03	239
Down-turned corners^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	0.8	-0.33-1.93	239
Cupid bow shape of mouth^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	1.7	0.06-3.34	239
Macrostomia^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	0.8	-0.33-1.93	239
Microstomia	2.5	0.52-4.48	239
Open-mouth appearance^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	0.4	-0.4-1.2	239
Everted/prominent lower lip^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	0.8	-0.33-1.93	239
Thick lower lip	8.8	5.21-12.9	239
Cleft upper lip (nonmidline)^a a Characteristic considered as a morphological anomaly (considering the 4% threshold). ,^b b Characteristic considered as a major morphological anomaly. DNA, does not apply.	0	DNA	239
Prominent upper lip	7.5	1.38-6.22	239
Thin upper lip	3.8	1.38-6.22	239
Enamel abnormalities^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	0.8	-0.33-1.93	239
Crowded or irregular teeth	12.6	8.39-16.81	239
Abnormal tooth shape^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	2.1	0.28-3.92	239
Small teeth^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	0	DNA	239
Widely spaced teeth	4.6	1.94-7.26	239
Large hands^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	0.8	-0.33-1.93	239
Small hands	3.8	1.38-6.22	239
Camptodactyly^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	1.3	-0.14-2.74	239
Clinodactyly	16.7	11.97-21.43	239
Cutaneous syndactyly of the fingers^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	0.4	-0.4-1.2	239
Tapering fingers	3.8	1.38-6.22	239
Thin fingers	7.5	1.38-6.22	239
Hypoplastic/short metacarpals^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	0	DNA	239
Short phalanges^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	1.7	0.06-3.34	239
Wide phalanges^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	0.4	-0.4-1.2	239
Long phalanges^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	1.7	0.06-3.34	239
Broad thumbs	7.5	1.38-6.22	239
Dystrophic (dysplastic), including striated nails^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	0.4	-0.41-1.21	235
Hyperconvex	8	4.55-11.45	238
Hypoplastic/small nails	2.9	0.77-5.03	238
Short nails	10.5	6.61-14.39	238
Clubfoot varus^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	0	DNA	239
Large feet^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	2.1	0.28-3.92	239
Small feet^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	0.8	-0.33-1.93	239
Wide feet	10.9	6.9-14.85	239
Hallux valgus	10	6.2-13.8	239
Broad toes	3.3	1.04-5.56	239
Overlapping toes (including clinodactyly)	65.7	59.68-71.72	239
Short toes	2.5	0.52-4.48	239
Syndactyly of 2-3 toes^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	0.4	-0.4-1.2	239
Syndactyly of toes (except for 2-3 toes)^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	0.8	-0.33-1.93	239
Wide-spaced toes	9.2	5.54-12.86	239
Camptodactyly/hammer toes^a a Characteristic considered as a morphological anomaly (considering the 4% threshold).	0.4	-0.4-1.2	239

Morphological characteristic	Observed frequency (%) (Perrone, 2016)	Observed frequency (%) (Merks et al., 2006)¹²12 Merks JH, Ozgen HM, Cluitmans TL, van der Burg-van Rijn JM, Cobben JM, van Leeuwen FE, et al. Normal values for morphological abnormalities in school children. Am J Med Genet A. 2006;140A:2091-109.	Z-value	p-value
Unusual hair whorl/pattern	20	0.1	-13.6	<0.001
Frontal upsweep/cowlick	1.3	15.8	6.0	<0.001
Asymmetric ears	5.0	1.7	-2.95	0.003
Dysplastic ears	13.4	0.0	-11.2	<0.001
Prominent ears	9.6	2.6	-4.9	<0.001
Simple ears	9.2	0.1	-8.9	<0.001
Notched ear helix	8.4	0.0	-8.8	<0.001
Prominent ear helix	9.6	2.6	-4.9	<0.001
Large/wide nose	15.1	0.4	-11	<0.001
Short/small nose	0.4	9.3	4.65	<0.001
Hypoplasia of the middle third of the face	1.3	0	-3.42	<0.001
Long/narrow face	5.0	2.2	-2.43	0.01
Triangular face	4.2	0.1	-5.79	<0.001
Prominent mandible/prognathism	2.9	0.3	-3.88	<0.001
Long philtrum	12.1	3.1	-5.68	<0.001
Prominent/deep philtrum	9.2	1.8	-5.63	<0.001
Short philtrum	8.4	2.8	-3.92	<0.001
Simple/absent/flat philtrum	2.1	5.3	2.1	0.03
Down-turned corners	0.8	0.1	-1.97	0.047
Open-mouth appearance	0.4	0.0	-1.96	0.04
Thick lower lip	8.8	14.5	2.32	0.02
Prominent upper lip	7.5	2.1	-4.29	<0.001
Thin upper lip	3.8	8.9	2.66	0.007
Enamel abnormalities	0.8	0	-2.78	0.005
Irregular or crowded teeth	12.6	0	-10.9	<0.001
Abnormal tooth shape	2.1	0.1	-3.8	<0.001
Widely spaced teeth	4.6	0	-6.54	<0.001
Large hands	0.8	0	-2.78	0.005
Small hands	3.8	0	-5.9	<0.001
Camptodactyly	1.3	0	-3.4	0.006
Clinodactyly	16.7	3.6	-12.6	<0.001
Tapering fingers	3.8	0.4	-4.36	<0.001
Broad thumbs	7.5	0.9	6.2	<0.001
Hyperconvex	8.0	0	-8.65	<0.001
Hypoplastic/small nails	2.9	0.2	-4.2	<0.001
Short nails	10.5	0.9	-7.9	<0.001
Large feet	10.9	0.3	-9.3	<0.001
Hallux valgus	10.0	2.4	-5.4	<0.001
Broad toes	3.3	0.7	-3.4	<0.001
Overlapping toes (including clinodactyly)	65.7	0.3	-26.7	<0.001
Short toes	2.5	0.2	-3.8	<0.001
Syndactyly of toes (except 2-3 toes)	0.8	0	-2.78	0.005
Wide-spaced toes	9.2	26.3	5.59	<0.001

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