Clinical and anatomical characteristics associated with obstructive sleep apnea severity in children

Bozzini, Maria Fernanda; Di Francesco, Renata C.; Soster, Letícia A.

doi:10.1016/j.clinsp.2022.100131

Abstract

Purpose

To determine the clinical and anatomical characteristics associated with obstructive sleep apnea severity in children with adenotonsillar hypertrophy.

Methods

The authors conducted a cross-sectional multidisciplinary survey and selected 58 Brazilian children (4‒9 years old) with adenotonsillar hypertrophy, parental complaints of snoring, mouth-breathing, and witnessed apnea episodes. The authors excluded children with known genetic, craniofacial, neurological, or psychiatric conditions. Children with a parafunctional habit or early dental loss and those receiving orthodontic treatment were not selected. All children underwent polysomnography, and three were excluded because they showed an apnea-hypopnea index lower than one or minimal oxygen saturation higher than 92%. The sample consisted of 55 children classified into mild (33 children) and moderate/severe (22 children) obstructive sleep apnea groups. Detailed clinical and anatomical evaluations were performed, and anthropometric, otorhinolaryngological, and orthodontic variables were analyzed. Sleep disorder symptoms were assessed using the Sleep Disturbance Scale for Children questionnaire. All children also underwent teleradiography exams and Rickett's and Jarabak's cephalometric analyses.

Results

The mild and moderate/severe obstructive sleep apnea groups showed no significant differences in clinical criteria. Facial depth angle, based on Ricketts cephalometric analysis, was significantly different between the groups (p= 0.010), but this measurement by itself does not express the child's growth pattern, as it is established by the arithmetic mean of the differences between the obtained angles and the normal values of five cephalometric measurements.

Conclusions

The clinical criteria and craniofacial characteristics evaluated did not influence the disease severity.

Keywords
Sleep; Sleep Apnea Syndromes; Polysomnography; Child

Highlights

Untreated obstructive sleep apnoea in children may result in severe health consequences, including cardiovascular, metabolic, endocrine and growth abnormalities.
Other sleep impairments may be associated with obstructive sleep apnoea, affecting children's quality of life.
Polysomnography is the gold standard for diagnosis, but it is costly and not widely available.
Other studies that contribute to the diagnosis process are relevant and of great importance.

Highlights

Untreated obstructive sleep apnoea in children may result in severe health consequences, including cardiovascular, metabolic, endocrine and growth abnormalities.
Other sleep impairments may be associated with obstructive sleep apnoea, affecting children's quality of life.
Polysomnography is the gold standard for diagnosis, but it is costly and not widely available.
Other studies that contribute to the diagnosis process are relevant and of great importance.

Introduction

Pediatric Obstructive Sleep Apnea (OSA) affects 1-5% of all children¹1 Kaditis AG, Alonso Alvarez ML, Boudewyns A, Alexopoulos EI, Ersu R, Joosten K, et al. Obstructive sleep disordered breathing in 2- to 18-year-old children: diagnosis and management. Eur Respir J. 2016;47(1):69-94. and several comorbidities associated with may directly affect a child's quality of life. The most common known comorbidities cited in the literature are enuresis, hyperactivity, inattention, aggressiveness, anxiety, excessive daytime sleepiness, cognitive deficits, and poor school performance.²2 Mitchell RB, Kelly J. Behavior. Neurocognition and quality-of-life in children with sleep-disordered breathing. Int J Pediatr Otorhinolaryngol. 2006;70(3):395-406.

3 Marcus CL, Brooks LJ, Draper KA, Gozal D, Halbower AC, Jones J, et al. Diagnosis and management of childhood obstructive sleep apnea syndrome. Pediatrics. 2012;130(3):576-84.-⁴4 Sateia MJ. International classification of sleep disorders. Third edition (ICSD 3). Chest. 2014;146(5):1387-94.

Adenotonsillar hypertrophy is the main risk factor for pediatric OSA³3 Marcus CL, Brooks LJ, Draper KA, Gozal D, Halbower AC, Jones J, et al. Diagnosis and management of childhood obstructive sleep apnea syndrome. Pediatrics. 2012;130(3):576-84. and evidence supports Adenotonsillectomy (AT) as the first-line treatment for this condition.⁵5 Friedman M, Wilson M, Lin HC, Chang HW. Updated systematic review of tonsillectomy and adenoidectomy for treatment of pediatric obstructive sleep apnea/hypopnea syndrome. Otolaryngol Head Neck Surg. 2009;140(6):800-8.,⁶6 Redline S, Amin R, Beebe D, Chervin RD, Garetz SL, Giordani B, et al. The Childhood Adenotonsillectomy Trial (CHAT): rationale, design, and challenges of a randomized controlled trial evaluating a standard surgical procedure in a pediatric population. Sleep. 2011;34(11):1509-17. Accurate diagnosis is best accomplished by the integration of clinical history and data from physical inspection and examinations confirming the presence of the obstruction.⁷7 Aurora RN, Zak RS, Karippot A, Lamm CI, Morgenthaler TI, Auerbach SH, et al. Practice parameters for the respiratory indications for polysomnography in children. Sleep. 2011;34(3):379-88.,⁸8 Wise MS, Nichols CD, Grigg-Damberger MM, Marcus CL, Witmans MB, Kirk VG, D'Andrea LA, Hoban TF. Executive summary of respiratory indications for polysomnography in children: an evidence-based review. Sleep. 2011;34(3):389-98. Polysomnography (PSG) remains the gold standard examination, and the diagnosis is confirmed if the child presents one or more OSA signs or symptoms associated with more than one Apnea and Hypopnea event per hour (AHI) during sleep.⁷7 Aurora RN, Zak RS, Karippot A, Lamm CI, Morgenthaler TI, Auerbach SH, et al. Practice parameters for the respiratory indications for polysomnography in children. Sleep. 2011;34(3):379-88.

PSG values before surgery are very important in identifying children with moderate or severe OSA because they are at a higher risk of developing surgical complications or residual apnea after AT.³3 Marcus CL, Brooks LJ, Draper KA, Gozal D, Halbower AC, Jones J, et al. Diagnosis and management of childhood obstructive sleep apnea syndrome. Pediatrics. 2012;130(3):576-84. OSA in children is classified as mild when the AHI is between 1 and 5 and the minimal saturation index is between 85% and 92%, while moderate to severe OSA is defined by an AHI higher than 5 and minimal saturation index less than 85%, depending on the PSG global analysis and clinical evaluation.⁹9 Uliel S, Tauman R, Greenfeld M, Sivan Y. Normal polysomnographic respiratory values in children and adolescents. Chest. 2004;125(3):872-8.,¹⁰10 Almeida LA, Anselmo-Lima WT, Valera FC. OSAS in children: where are we? Braz J Otorhinolaryngol. 2011;77(3): 273. The American Academy of Pediatrics suggests that all children with OSA should undergo PSG before surgery,¹¹11 American Academy of Pediatrics. Section on Pediatric Pulmonology, Subcommittee on Obstructive Sleep Apnea Syndrome. Clinical practice guideline: diagnosis and management of childhood obstructive sleep apnea syndrome. Pediatrics 2002;109(4):704-12. but the procedure is expensive, time-consuming, and not readily accessible.⁷7 Aurora RN, Zak RS, Karippot A, Lamm CI, Morgenthaler TI, Auerbach SH, et al. Practice parameters for the respiratory indications for polysomnography in children. Sleep. 2011;34(3):379-88.,³3 Marcus CL, Brooks LJ, Draper KA, Gozal D, Halbower AC, Jones J, et al. Diagnosis and management of childhood obstructive sleep apnea syndrome. Pediatrics. 2012;130(3):576-84.

In addition to adenotonsillar hypertrophy, obesity and craniofacial morphology are also cited as important predisposing factors for pediatric OSA.⁴4 Sateia MJ. International classification of sleep disorders. Third edition (ICSD 3). Chest. 2014;146(5):1387-94. Therefore, clinical and anatomical parameters play an important role in the diagnostic process. The aim of this study was to determine the clinical and anatomical characteristics associated with obstructive sleep apnea severity in children on a waiting list for AT and help clinicians manage the surgical risks and post-surgical follow-up.

Materials and methods

This cross-sectional interdisciplinary survey was conducted at the Otorhinolaryngology and Pediatrics Department of the University of São Paulo Medical School, São Paulo, Brazil. Children were recruited, and their parents agreed to participate by signing the informed consent form approved by the Institution's Committee on Ethics and Research.

Study sample

Children were consecutively selected from the waiting lists for AT between August 2015 and January 2019. The sample was composed of 58 Brazilian children (4.0‒9.0 years old) with nasopharynx obstruction (> 60%), tonsil enlargement (Brodsky's grades¹²12 Brodsky L. Modern assessment of tonsils and adenoids. Pediatr Clin N Am. 1989;36(6):1551-69. 2, 3 or 4), parental complaints of snoring (> 3 nights per week), mouth-breathing, and/or witnessed apnea episodes. All children were surgical candidates for AT.

The authors targeted a population that was older than 4.0 years of age to ensure cooperation during the examinations and younger than 9.0 years of age to avoid the effects of pubertal growth spurts on the study outcomes.

Standardized PSG was performed using the 2014 American Academy of Sleep Medicine (AASM) criteria: AHI ≥ 1 and/or minimal saturation < 92%.⁴4 Sateia MJ. International classification of sleep disorders. Third edition (ICSD 3). Chest. 2014;146(5):1387-94. Three children were excluded because they showed AHI < 1 and/or minimal saturation > 92% in PSG. The sample was then classified⁹9 Uliel S, Tauman R, Greenfeld M, Sivan Y. Normal polysomnographic respiratory values in children and adolescents. Chest. 2004;125(3):872-8. into the mild OSA group (33 children) and the moderate/severe OSA group (22 children), all candidates for AT. The authors were not able to recruit a control group because of ethical reasons for performing the exams on children without symptoms.

Inclusion criteria

Adenoid enlargement and tonsil enlargement
Surgical candidate for AT
Diagnosed with OSA defined as:

Parental report of snoring (an average of > 3 nights per week), mouth-breathing, and/or witnessed apnea episodes.

Nocturnal PSG confirming AHI ≥ 1 and/or minimal saturation < 92%.

Exclusion criteria

Known genetic, craniofacial, neurological, or psychiatric conditions likely to affect the airway, cognition, or behavior.
Parafunctional habit (digital sucking or pacifier), early dental loss, and/or receiving orthodontic treatment.

Clinical and anatomical analysis

A detailed clinical and anatomical analysis was performed. Age, gender, weight, and height were used to determine the BMI z-score using the World Health Organization (WHO) software. On the basis of their BMI z-scores, children were categorized as thin, eutrophic, overweight risk, overweight, or obese. All children underwent a systematic otorhinolaryngological examination. The adenoid size was determined by evaluating the percentage of nasopharyngeal obstruction observed in 3.2-mm ENT-P nasal fiberoptic endoscopy (Machida®, Japan). Tonsil size was determined by using Brodsky's criteria.¹²12 Brodsky L. Modern assessment of tonsils and adenoids. Pediatr Clin N Am. 1989;36(6):1551-69. Tonsil and adenoid evaluation were realized by two experienced otorhinolaryngologists.

Overnight PSG was performed using the Embla N7000 (Natus Neurology®, EUA) without sedation or sleep deprivation. Electrophysiological and cardiorespiratory parameters were recorded on a computerized system RemLogic (version 3.2, Natus Neurology®, USA). Sleep stages, hypopnea, central apnea, obstructive apnea, or mixed events were scored according to the 2014 AASM criteria.⁴4 Sateia MJ. International classification of sleep disorders. Third edition (ICSD 3). Chest. 2014;146(5):1387-94.

To assess the symptoms of sleep disorders, parents filled out the SDSC questionnaire,¹³13 Bruni O, Ottaviano S, Guidetti V, Romoli M, Innocenzi M. The Sleep Disturbance Scale for Children (SDSC). Construction and validation of an instrument to evaluate sleep disturbances in childhood and adolescence. J Sleep Res. 1996;5(4):251-61. which has been already validated for the Portuguese language.¹⁴14 Ferreira VR, Carvalho LB, Ruotolo F, de Morais JF, Prado LB, Prado GF. Sleep disturbance scale for children: translation, cultural adaptation, and validation. Sleep Med. 2009;10(4):457-63. The 26 questions are grouped into six subscales representing the most common sleep disturbances: disorders in initiating and maintaining sleep, disorders of breathing during sleep, disorders of arousal, disorders of sleep-wake transition, disorders of excessive somnolence, and nocturnal hyperhidrosis.

The orthodontic evaluation consisted of dental and facial clinical analysis and was realized by an experienced orthodontist. Children were instructed to maintain teeth in occlusion with lips at rest and the following variables were analyzed: absence of lip sealing (yes/no), facial profile (plane/convex), increased overjet (> 3 mm),¹⁵15 Lee R. Esthetics and its relationship to function. In: Rufenacht, CR. Fundamentals of esthetics. Chicago. Quintessence, 1990:137-209. distocclusion (Angle Class II¹⁶16 Angle EH. Classification of malocclusion. Dent Cosmos. 1899;41(2):248-64. or Baume distal step),¹⁷17 Baume LJ. Physiological tooth migration and its significance for the development of occlusion. Biogenetic course of the deciduous dentition. J Dent Res. 1950;29(2):123-32. and transversal arch relationship (normal/ unilateral crossbite or bilateral crossbite). The evaluation of facial profile is a routine part of the examination of an orthodontic patient and for that is necessary a cephalometric analysis which provides an exact depiction of craniofacial morphology. All children underwent teleradiography for cephalometric analysis. Radiographs were taken using Orthophos XG 5 DS Ceph (Sirona®, Brazil) regulated to 12 mA, 90 kV, and 0.30 s of time exposure. All children were oriented in the natural head position.

Radiographs were digitized and cephalometric analysis was performed using Easy Ceph (Anne Solutions®, Brazil) software. Rickett's cephalometric analysis¹⁸18 Ricketts, RM. Cephalometric synthesis. Am J Orthod. 1960; 46(9):647-73. included the following skeletal craniofacial measurements: Facial Axis (FA), Facial Depth (FD), Mandibular Plane angle (MP), Lower Facial Height (LFH), Mandibular Arch (MA), and Vertical Growth Coefficient (VERT). The facial pattern was established using the VERT index, which is calculated by determining the arithmetic mean of differences between the obtained and normal values of the measurements cited above, represented in Fig. 1. On the basis of the growth tendency, the children were then classified into mesofacial, dolichofacial (vertical), or brachyfacial (horizontal) groups.

Fig. 1
Rickett's cephalometric analysis- facial axis (FA), facial depth (FD), mandibular plane angle (MP), lower facial height (LFH) and mandibular arch (MA).

Jarabak's cephalometric analysis¹⁹19 Jarabak JR, Fizzel JA. Technique and Treatment With Light Wire Edgewise Appliances. 2nd ed. St. Louis: C.V. Mosby Company, 1972. included the following skeletal craniofacial measurements: Posterior Facial height (PF), Anterior Facial height (AF), and the Jarabak's coefficient percentage (PF/AF ×100), represented in Fig. 2. Children were classified into neutral, hypodivergent (horizontal), or hyperdivergent (vertical) growth tendency patterns according to the percentage.

Fig. 2
Jarabak's cephalometric analysis- posterior facial height (PF) and anterior facial height (AF).

Statistical analysis

Categorical variables were described using absolute and relative frequencies and continuous variables were described using summary statistics (mean, standard deviation, median, minimum, and maximum).

Comparisons between categorical variables in the mild OSA and moderate/severe OSA groups were verified using Chi-Squared or exact tests (Fisher's exact test or likelihood-ratio test). Comparisons between continuous variables in the mild OSA and moderate/severe OSA groups were performed using Student's t-test. Odds ratios of each variable of interest were estimated with the respective 95% Confidence Intervals by using simple logistic regression. A multiple logistic regression model was estimated by selecting variables that showed p< 0.10 in the bivariate tests. Tests were performed with a 5% significance level.

Results

The PSG factors and OSA stratification for all children are described in Table 1. The mean AHI value was 4.8 ± 7.6, with an average minimal oxyhemoglobin saturation (min Sat O₂) of 86.8% ± 5.2%. Thus, 33 (60%) children were classified into the mild OSA group and 22 (40%) were classified into the moderate/severe OSA group.

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Table 1
Polysomnography variables and obstructive sleep apnea classification for all children.

Table 2 presents the demographic, anthropometric, and otorhinolaryngological data for both groups. The variables age, sex, BMI z-score, and adenoid and tonsil size were not significantly different between the groups. Sleep disorder symptoms associated with pediatric OSA were assessed using the SDSC questionnaire,¹³13 Bruni O, Ottaviano S, Guidetti V, Romoli M, Innocenzi M. The Sleep Disturbance Scale for Children (SDSC). Construction and validation of an instrument to evaluate sleep disturbances in childhood and adolescence. J Sleep Res. 1996;5(4):251-61. and none of the six subscales showed significant differences between groups, as shown in Table 3.

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Table 2
Demographic, anthropometric, and otorhinolaryngological findings for the mild OSA and moderate/severe OSA groups.

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Table 3
SDSC questionnaire subscale findings for the mild OSA and moderate/severe OSA groups.

Comparisons between the mild OSA and moderate/severe OSA groups on the basis of orthodontic and cephalometric analysis are shown in Table 4. Dental characteristic variables were not significantly different between the groups. FD, based on Ricketts cephalometric analysis, showed statistically significant differences (p= 0.010) between groups. Table 5 describes the multiple logistic regression model estimated for this variable. A positive association was observed between FD and OSA severity in children (p= 0.012). An increase of one degree in the FD angle increased the probability of moderate or severe OSA by 29% (OR = 1.29), as shown in Table 5.

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Table 4
Orthodontic evaluation and cephalometric analysis of mild and moderate/severe OSA groups.

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Table 5
Multiple logistic regression model for facial depth.

Discussion

Accurate OSA diagnosis in children is best accomplished by careful integration of the results of clinical and anatomical evaluations and PSG values.

The present data showed a lack of association between the OSA severity and the findings of demographic and anthropometric evaluations. Population ethnicity must be taken into account while evaluating these findings, and the genetic diversity in the Brazilian population may be an interference factor in the outcomes. The present anthropometric evaluation results are not in accordance with previous studies that reported obesity as one of the most risk factors not only in children but also in adults.²⁰20 Gulotta G, Ianella G, Vicini C, Polimeni A, Greco A, Vincentiis M, et al. Risk factors for obstructive sleep apnea syndrome in children: state of the art. Int J Environ Res Public Health. 2019;16(18):1-20.

The authors also found a lack of association between adenotonsillar hypertrophy and OSA severity. This finding was in accordance with the 2019 American Academy of Otorhinolaryngology clinical guidelines,²¹21 Mitchell RB, Archer SM, Ishman SL, Rosenfeld RM, Coles S, Finestone SA, et al. Clinical practice guideline: tonsillectomy in children (update). Otolaryngol Head Neck Surg. 2019;160(2):187-205. which reported that children with small tonsils may have severe OSA symptoms and that children without apparent OSA symptoms may have tonsillar hypertrophy and/or nasal airway obstruction. In the authors’ opinion, this probably occurs because OSA severity is related to multiple factors such as craniofacial anatomy and neuromuscular tone and not only upper airway obstruction.

Assessment of OSA symptoms is an important element for diagnosis, and some sleep questionnaires generally show a good correlation with PSG results. However, according to Wise et al.,⁸8 Wise MS, Nichols CD, Grigg-Damberger MM, Marcus CL, Witmans MB, Kirk VG, D'Andrea LA, Hoban TF. Executive summary of respiratory indications for polysomnography in children: an evidence-based review. Sleep. 2011;34(3):389-98. most of these questionnaires do not provide strong evidence to support their validity. The authors found no difference between the mild OSA and moderate/severe group in assessments based on sleep symptoms using the SDSC questionnaire. Caregiver reports of snoring witnessed apnea episodes or other nocturnal symptoms may be unreliable if the caregiver does not directly observe the child while sleeping or observes the child in only the early evening.²¹21 Mitchell RB, Archer SM, Ishman SL, Rosenfeld RM, Coles S, Finestone SA, et al. Clinical practice guideline: tonsillectomy in children (update). Otolaryngol Head Neck Surg. 2019;160(2):187-205. Therefore, the authors hypothesize that it is difficult to distinguish sleep symptoms in relation to OSA severity because questionnaires and clinical interviews are subjective instruments and are also affected by parental bias.

Absence of lip sealing, hyperdivergent growth pattern, increased MP, increased AF, mandibular retrusion, increased overjet, and increased transverse deficiency are commonly reported as major changes caused by oral breathing.²²22 Pirila-Parkkinen K, Pirttiniemi P, Nieminen P, Tolonen U, Pelttari U, Lopponen H. Dental arch morphology in children with sleep-disordered breathing. Eur J Orthod. 2009;31(2):160-7.

23 Pirilä-Parkkinen K, Löppönen H, Nieminen P, Tolonen U, Pirttiniemi P. Cephalometric evaluation of children with nocturnal sleep-disordered breathing. Eur J Orthod. 2010;32(6):662-71.-²⁴24 Becking BE, Verweij JP, Kalf-Scholte SM, Valkenburg C, Bakker EWP, van Merkesteyn JPR. Impact of adenotonsillectomy on the dentofacial development of obstructed children: a systematic review and meta-analysis. Eur J Orthod. 2017;39(5):509-18. Teleradiography and cephalometric analysis is a well-recognized tool for screening dental, skeletal, and soft tissue characteristics and is part of orthodontic documentation. Some authors performed studies seeking to use a non-invasive method for screening craniofacial phenotype, not involving X-Ray imaging in children.²⁵25 Sutherland K, Weichard AJ, Davey MJ, Horne RS, Cistulli PA, Nixon GM. Craniofacial photography and association with sleep-disordered breathing severity in children. Sleep Breath. 2020;24(3):1173-9.,²⁶26 Ikavalko T, Narhi M, Lakka T, Myllykangas R, Tuomilehto H, Vierola A, et al. Lateral facial profile may reveal the risk for sleep disordered breathing in children-the PANIC-study. Acta Odontol Scand. 2015;73(7):550-5. Clinical facial photography is feasible to obtain and shows preliminary evidence of relationships to sleep disorders but other studies are necessary to explore the real value in predicting the risk of OSA.²⁵25 Sutherland K, Weichard AJ, Davey MJ, Horne RS, Cistulli PA, Nixon GM. Craniofacial photography and association with sleep-disordered breathing severity in children. Sleep Breath. 2020;24(3):1173-9. According to Ikavalko et al.²⁶26 Ikavalko T, Narhi M, Lakka T, Myllykangas R, Tuomilehto H, Vierola A, et al. Lateral facial profile may reveal the risk for sleep disordered breathing in children-the PANIC-study. Acta Odontol Scand. 2015;73(7):550-5. it would be advantageous if other healthcare professionals, and not only orthodontists, could be trained to play a key role in identifying certain craniofacial risk features for OSA. Photography may provide a complementary assessment but cephalometry is still the best way to evaluate craniofacial characteristics.

There are few published studies in the literature addressing associations between dental and craniofacial deformities and OSA severity.²⁷27 Flores-Mir C, Korayem M, Heo G, Witmans M, Major MP, Major PW. Craniofacial morphological characteristics in children with obstructive sleep apnea syndrome: a systematic review and meta-analysis. J Am Dent Assoc. 2013;144(3):269-77.,²⁸28 Katyal V, Pamula Y, Martin J, Daynes CN, Kennedy JD, Sampsonf WJ. Craniofacial and upper airway morphology in pediatric sleep-disordered breathing: systematic review and meta-analysis. Am J Orthod Dentofacial Orthop. 2013;143(1):20-30.e3. The authors choose Ricketts's and Jarabak's cephalometric analysis because both are routinely used to establish craniofacial growth pattern, which is constant during life. In a systematic review and meta-analysis, Flores-Mir et al.²⁷27 Flores-Mir C, Korayem M, Heo G, Witmans M, Major MP, Major PW. Craniofacial morphological characteristics in children with obstructive sleep apnea syndrome: a systematic review and meta-analysis. J Am Dent Assoc. 2013;144(3):269-77. found an association between craniofacial characteristics and pediatric OSA, but Katyal et al.²⁸28 Katyal V, Pamula Y, Martin J, Daynes CN, Kennedy JD, Sampsonf WJ. Craniofacial and upper airway morphology in pediatric sleep-disordered breathing: systematic review and meta-analysis. Am J Orthod Dentofacial Orthop. 2013;143(1):20-30.e3. stated that there was no evidence of a direct causal relationship. Di Francesco et al.²⁹29 Di Francesco R, Monteiro R, Paulo ML, Buranello F, Imamura R. Craniofacial morphology and sleep apnea in children with obstructed upper airways: differences between genders. Sleep Med. 2012;13(6):616-20. found that craniofacial characteristics such as dolichocephaly, mandibular plane, and FD correlate with OSA severity but only in boys. Other studies have reported that dental changes associated with a long face and a vertical growth pattern characterizes the most common OSA phenotype in children.³⁰30 Villa MP, Paolino MC, Castaldo R, Vanacore N, Rizzoli A, Miano S, et al. Sleep clinical record: an aid to rapid and accurate diagnosis of paediatric sleep disordered breathing. Eur Respir J. 2013;41(6):1355-61.

The present data showed that there was no association between dental characteristics and OSA severity. Differently from what was expected, the findings showed a positive association between FD and OSA severity, but this measurement by itself does not express the child's growth pattern, as it is established by the arithmetic mean of the differences between the obtained angles and the normal values of five cephalometric measurements. The authors hypothesize that the severity of OSA in children may be more influenced by the maxilla position and not by growth pattern or mandibular position as cited in the literature.

Conclusion

In conclusion, the clinical criteria and craniofacial characteristics evaluated did not influence the disease severity. In the authors’ opinion, it is still difficult to define whether dental and anatomical changes are derived from birth or adaptations from impaired breathing. It is possible that different associations would be observed in younger or older children due to the airway obstruction period.

Nevertheless, as OSA severity is related to multiple factors, it is essential to continue focusing on the diagnosis and evaluating not only mandibular but also maxillary morphology prior to surgery. Choice of treatment must be tailored to the individual child depending on disease severity, predisposing factors, and comorbidities.³¹31 Bitners AC, Arens R. Evaluation and management of children with obstructive sleep apnea syndrome. Lung. 2020;198(2):257-70. Recent literature evidence that OSA management requires a multidisciplinary approach in order to make an early diagnosis and a correct treatment plan.³²32 Giuca MR, Carli E, LArdani L, Pasini M, Miceli M, Fambrini E. Pediatric obstructive sleep apnea syndrome: emerging evidence and treatment approach. Sci World J. 2021;2021:5591251. The interdisciplinary work from health professionals is essential for a good OSA treatment approach in children.

Study limitations and future studies

Additional prospective multicenter studies using larger samples and including children of different ages and races are required to validate these findings.

It is important to continue studying the effectiveness of other less expensive alternatives to diagnose and predict OSA severity in children.

Abbreviations

AASM American Academy of Sleep Medicine
AF Anterior Facial height
AHI Apnea-Hypopnea Index
AT Adenotonsillectomy
BMI Bone Mass Index
FA Facial Axis
FD Facial Depth
Kv Kilowatts
LFH Lower Facial Height
Ma Miliamps
MA Mandibular Arch
MP Mandibular Plane angle
OSA Obstructive Sleep Apnea
PF Posterior Facial height
PSG Polysomnography
VERT Vertical growth coefficient
WHO World Health Organization

Acknowledgments

To all children who participated in this study. To the Child Institute staff of University of São Paulo, Medical School, São Paulo, Brazil, who performed all polysomnography exams.

References

¹
Kaditis AG, Alonso Alvarez ML, Boudewyns A, Alexopoulos EI, Ersu R, Joosten K, et al. Obstructive sleep disordered breathing in 2- to 18-year-old children: diagnosis and management. Eur Respir J. 2016;47(1):69-94.
²
Mitchell RB, Kelly J. Behavior. Neurocognition and quality-of-life in children with sleep-disordered breathing. Int J Pediatr Otorhinolaryngol. 2006;70(3):395-406.
³
Marcus CL, Brooks LJ, Draper KA, Gozal D, Halbower AC, Jones J, et al. Diagnosis and management of childhood obstructive sleep apnea syndrome. Pediatrics. 2012;130(3):576-84.
⁴
Sateia MJ. International classification of sleep disorders. Third edition (ICSD 3). Chest. 2014;146(5):1387-94.
⁵
Friedman M, Wilson M, Lin HC, Chang HW. Updated systematic review of tonsillectomy and adenoidectomy for treatment of pediatric obstructive sleep apnea/hypopnea syndrome. Otolaryngol Head Neck Surg. 2009;140(6):800-8.
⁶
Redline S, Amin R, Beebe D, Chervin RD, Garetz SL, Giordani B, et al. The Childhood Adenotonsillectomy Trial (CHAT): rationale, design, and challenges of a randomized controlled trial evaluating a standard surgical procedure in a pediatric population. Sleep. 2011;34(11):1509-17.
⁷
Aurora RN, Zak RS, Karippot A, Lamm CI, Morgenthaler TI, Auerbach SH, et al. Practice parameters for the respiratory indications for polysomnography in children. Sleep. 2011;34(3):379-88.
⁸
Wise MS, Nichols CD, Grigg-Damberger MM, Marcus CL, Witmans MB, Kirk VG, D'Andrea LA, Hoban TF. Executive summary of respiratory indications for polysomnography in children: an evidence-based review. Sleep. 2011;34(3):389-98.
⁹
Uliel S, Tauman R, Greenfeld M, Sivan Y. Normal polysomnographic respiratory values in children and adolescents. Chest. 2004;125(3):872-8.
¹⁰
Almeida LA, Anselmo-Lima WT, Valera FC. OSAS in children: where are we? Braz J Otorhinolaryngol. 2011;77(3): 273.
¹¹
American Academy of Pediatrics. Section on Pediatric Pulmonology, Subcommittee on Obstructive Sleep Apnea Syndrome. Clinical practice guideline: diagnosis and management of childhood obstructive sleep apnea syndrome. Pediatrics 2002;109(4):704-12.
¹²
Brodsky L. Modern assessment of tonsils and adenoids. Pediatr Clin N Am. 1989;36(6):1551-69.
¹³
Bruni O, Ottaviano S, Guidetti V, Romoli M, Innocenzi M. The Sleep Disturbance Scale for Children (SDSC). Construction and validation of an instrument to evaluate sleep disturbances in childhood and adolescence. J Sleep Res. 1996;5(4):251-61.
¹⁴
Ferreira VR, Carvalho LB, Ruotolo F, de Morais JF, Prado LB, Prado GF. Sleep disturbance scale for children: translation, cultural adaptation, and validation. Sleep Med. 2009;10(4):457-63.
¹⁵
Lee R. Esthetics and its relationship to function. In: Rufenacht, CR. Fundamentals of esthetics. Chicago. Quintessence, 1990:137-209.
¹⁶
Angle EH. Classification of malocclusion. Dent Cosmos. 1899;41(2):248-64.
¹⁷
Baume LJ. Physiological tooth migration and its significance for the development of occlusion. Biogenetic course of the deciduous dentition. J Dent Res. 1950;29(2):123-32.
¹⁸
Ricketts, RM. Cephalometric synthesis. Am J Orthod. 1960; 46(9):647-73.
¹⁹
Jarabak JR, Fizzel JA. Technique and Treatment With Light Wire Edgewise Appliances. 2nd ed. St. Louis: C.V. Mosby Company, 1972.
²⁰
Gulotta G, Ianella G, Vicini C, Polimeni A, Greco A, Vincentiis M, et al. Risk factors for obstructive sleep apnea syndrome in children: state of the art. Int J Environ Res Public Health. 2019;16(18):1-20.
²¹
Mitchell RB, Archer SM, Ishman SL, Rosenfeld RM, Coles S, Finestone SA, et al. Clinical practice guideline: tonsillectomy in children (update). Otolaryngol Head Neck Surg. 2019;160(2):187-205.
²²
Pirila-Parkkinen K, Pirttiniemi P, Nieminen P, Tolonen U, Pelttari U, Lopponen H. Dental arch morphology in children with sleep-disordered breathing. Eur J Orthod. 2009;31(2):160-7.
²³
Pirilä-Parkkinen K, Löppönen H, Nieminen P, Tolonen U, Pirttiniemi P. Cephalometric evaluation of children with nocturnal sleep-disordered breathing. Eur J Orthod. 2010;32(6):662-71.
²⁴
Becking BE, Verweij JP, Kalf-Scholte SM, Valkenburg C, Bakker EWP, van Merkesteyn JPR. Impact of adenotonsillectomy on the dentofacial development of obstructed children: a systematic review and meta-analysis. Eur J Orthod. 2017;39(5):509-18.
²⁵
Sutherland K, Weichard AJ, Davey MJ, Horne RS, Cistulli PA, Nixon GM. Craniofacial photography and association with sleep-disordered breathing severity in children. Sleep Breath. 2020;24(3):1173-9.
²⁶
Ikavalko T, Narhi M, Lakka T, Myllykangas R, Tuomilehto H, Vierola A, et al. Lateral facial profile may reveal the risk for sleep disordered breathing in children-the PANIC-study. Acta Odontol Scand. 2015;73(7):550-5.
²⁷
Flores-Mir C, Korayem M, Heo G, Witmans M, Major MP, Major PW. Craniofacial morphological characteristics in children with obstructive sleep apnea syndrome: a systematic review and meta-analysis. J Am Dent Assoc. 2013;144(3):269-77.
²⁸
Katyal V, Pamula Y, Martin J, Daynes CN, Kennedy JD, Sampsonf WJ. Craniofacial and upper airway morphology in pediatric sleep-disordered breathing: systematic review and meta-analysis. Am J Orthod Dentofacial Orthop. 2013;143(1):20-30.e3.
²⁹
Di Francesco R, Monteiro R, Paulo ML, Buranello F, Imamura R. Craniofacial morphology and sleep apnea in children with obstructed upper airways: differences between genders. Sleep Med. 2012;13(6):616-20.
³⁰
Villa MP, Paolino MC, Castaldo R, Vanacore N, Rizzoli A, Miano S, et al. Sleep clinical record: an aid to rapid and accurate diagnosis of paediatric sleep disordered breathing. Eur Respir J. 2013;41(6):1355-61.
³¹
Bitners AC, Arens R. Evaluation and management of children with obstructive sleep apnea syndrome. Lung. 2020;198(2):257-70.
³²
Giuca MR, Carli E, LArdani L, Pasini M, Miceli M, Fambrini E. Pediatric obstructive sleep apnea syndrome: emerging evidence and treatment approach. Sci World J. 2021;2021:5591251.

Publication Dates

Publication in this collection
09 Jan 2023
Date of issue
2022

History

Received
16 Mar 2022
Reviewed
13 July 2022
Accepted
3 Oct 2022

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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[21] ²¹
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[22] ²²
Pirila-Parkkinen K, Pirttiniemi P, Nieminen P, Tolonen U, Pelttari U, Lopponen H. Dental arch morphology in children with sleep-disordered breathing. Eur J Orthod. 2009;31(2):160-7.

[23] ²³
Pirilä-Parkkinen K, Löppönen H, Nieminen P, Tolonen U, Pirttiniemi P. Cephalometric evaluation of children with nocturnal sleep-disordered breathing. Eur J Orthod. 2010;32(6):662-71.

[24] ²⁴
Becking BE, Verweij JP, Kalf-Scholte SM, Valkenburg C, Bakker EWP, van Merkesteyn JPR. Impact of adenotonsillectomy on the dentofacial development of obstructed children: a systematic review and meta-analysis. Eur J Orthod. 2017;39(5):509-18.

[25] ²⁵
Sutherland K, Weichard AJ, Davey MJ, Horne RS, Cistulli PA, Nixon GM. Craniofacial photography and association with sleep-disordered breathing severity in children. Sleep Breath. 2020;24(3):1173-9.

[26] ²⁶
Ikavalko T, Narhi M, Lakka T, Myllykangas R, Tuomilehto H, Vierola A, et al. Lateral facial profile may reveal the risk for sleep disordered breathing in children-the PANIC-study. Acta Odontol Scand. 2015;73(7):550-5.

[27] ²⁷
Flores-Mir C, Korayem M, Heo G, Witmans M, Major MP, Major PW. Craniofacial morphological characteristics in children with obstructive sleep apnea syndrome: a systematic review and meta-analysis. J Am Dent Assoc. 2013;144(3):269-77.

[28] ²⁸
Katyal V, Pamula Y, Martin J, Daynes CN, Kennedy JD, Sampsonf WJ. Craniofacial and upper airway morphology in pediatric sleep-disordered breathing: systematic review and meta-analysis. Am J Orthod Dentofacial Orthop. 2013;143(1):20-30.e3.

[29] ²⁹
Di Francesco R, Monteiro R, Paulo ML, Buranello F, Imamura R. Craniofacial morphology and sleep apnea in children with obstructed upper airways: differences between genders. Sleep Med. 2012;13(6):616-20.

[30] ³⁰
Villa MP, Paolino MC, Castaldo R, Vanacore N, Rizzoli A, Miano S, et al. Sleep clinical record: an aid to rapid and accurate diagnosis of paediatric sleep disordered breathing. Eur Respir J. 2013;41(6):1355-61.

[31] ³¹
Bitners AC, Arens R. Evaluation and management of children with obstructive sleep apnea syndrome. Lung. 2020;198(2):257-70.

[32] ³²
Giuca MR, Carli E, LArdani L, Pasini M, Miceli M, Fambrini E. Pediatric obstructive sleep apnea syndrome: emerging evidence and treatment approach. Sci World J. 2021;2021:5591251.

Variables	Description (n= 55) %
AHI
Mean ± SD	4.8 ± 7.6
Median (min‒max)	2.3 (0.2‒48.7)
Minimal Sat O₂ (%)
Mean ± SD	86.8± 5.2
Median (min‒max)	88 (72‒95)
Mean Sat O₂ (%)
Mean ± SD	95.2± 1.8
Median (min‒max)	95 (90.6‒98)
Snoring during the exam
No	30 (54.5)
Yes	25 (45.5)
OSA classification
Mild	33 (60)
Moderate	13 (23.6)
Severe	9 (16.4)

Variables	OSA		OR	95% CI		p-value
Variables	Mild	Moderate/ Severe	OR	Inferior	Superior	p-value
Age (years)			1.37	0.96	1.97	0.084^a a Student's t
Mean ± SD	5.5± 1.4	6.2± 1.7
Median (min‒max)	5 (4‒9)	6 (4‒9)
Sex						0.375
Male	17 (54.8)	14 (45.2)	1.00
Female	16 (66.7)	8 (33.3)	0.61	0.20	1.83
Z score classification, n (%)						0.180^b b Likelihood-ratio. Sat O2, Blood Oxyhemoglobin Saturation.
Thin/Eutrophic	22 (62.9)	13 (37.1)	1.00
Overweight risk/Overweight	9 (69.2)	4 (30.8)	0.75	0.19	2.94
Obese	2 (28.6)	5 (71.4)	4.23	0.72	25.02
Adenoid enlargement (%)			1.00	0.96	1.03	0.866^a a Student's t
Mean ± SD	69.4± 15.6	68.6± 17.3
Median (min‒max)	70 (30‒90)	70 (30‒90)
Tonsil enlargement grade, n (%)			0.79	0.27	2.31	0.894^b b Likelihood-ratio. Sat O2, Blood Oxyhemoglobin Saturation.
2	2 (50)	2 (50)
3	24 (60)	16 (40)
4	7 (63.6)	4 (36.4)

Variables	OSA		OR	95% CI		p-value
Variables	Mild	Moderate/ Severe	OR	Inferior	Superior	p-value
Disorders in initiating and maintaining sleep			0.98	0.88	1.08	0.619^a a Student's t, # Likelihood-ratio.
Mean ± SD	16± 5.9	15.2± 5.1
Median (min‒max)	15 (7‒31)	14 (9‒28)
Disorders in breathing during sleep			1.10	0.90	1.33	0.362^a a Student's t, # Likelihood-ratio.
Mean ± SD	11.2± 3.2	12± 2.4
Median (min‒max)	12 (4‒15)	12 (8‒15)
Disorders of arousal			1.09	0.85	1.41	0.503^a a Student's t, # Likelihood-ratio.
Mean ± SD	4.7± 2.4	5.1± 1.7
Median (min‒max)	4 (3‒13)	5 (3‒9)
Disorders of sleep-wake transition			1.02	0.91	1.14	0.772^a a Student's t, # Likelihood-ratio.
Mean ± SD	16± 4.9	16.4± 4.4
Median (min‒max)	15 (9‒29)	18 (6‒23)
Disorders of excessive somnolence			1.01	0.92	1.11	0.812^a a Student's t, # Likelihood-ratio.
Mean ± SD	11.5± 6.1	11.9± 5.8
Median (min‒max)	10 (5‒25)	12.5 (5‒25)
Nocturnal hyperhidrosis			0.97	0.82	1.16	0.755^a a Student's t, # Likelihood-ratio.
Mean ± SD	6.2± 3.1	5.9± 3.3
Median (min‒max)	7 (2‒10)	6 (2‒10)
Total			0.99	0.96	1.03	0.649^a a Student's t, # Likelihood-ratio.
Mean ± SD	65.9± 15.8	64± 15.7
Median (min‒max)	61 (47‒106)	60.5 (43‒04)

Variables	OSA		OR	95% CI		p-value
Variables	Mild	Moderate/ Severe	OR	Inferior	Superior	p-value
Lip sealing absence						0.723^a a Fisher's exact
No	7 (70)	3 (30)	1.00
Yes	26 (57.8)	19 (42.2)	1.71	0.39	7.46
Facial profile						0.509
Plane	15 (55.6)	12 (44.4)	1.00
Convex	18 (64.3)	10 (35.7)	0.69	0.24	2.05
Increased overjet						0.437
No	24 (57.1)	18 (42.9)	1.00
Yes	9 (69.2)	4 (30.8)	0.59	0.16	2.23
Distocclusion						0.197
No	20 (54.1)	17 (45.9)	1.00
Yes	13 (72.2)	5 (27.8)	0.45	0.13	1.53
Transversal arch relationship						0.081^b b Likelihood-ratio
Normal	24 (54.5)	20 (45.5)	1.00
Unilateral cross bite	5 (71.4)	2 (28.6)	0.48	0.08	2.75
Bilateral cross bite	4 (100)	0 (0)	^d d Impossible to estimate. mm, Millimeters.
Ricketts analysis
Facial axis (degree)			1.10	0.95	1.28	0.186^c c Student's t
Mean ± SD	84.8± 4.1	86.2± 3.7
Median (min‒max)	85.5 (74.1‒92.1)	86.1 (80.4‒94.1)
Facial depth (degree)			1.29	1.06	1.57	0.010^c c Student's t
Mean ± SD	84.1± 4.6	87± 2.8
Median (min‒max)	84.6 (65.9‒90.7)	86.8 (82.5‒92.5)
Mandibular plane angle (degree)			0.90	0.79	1.02	0.086^c c Student's t
Mean ± SD	32.4± 5.5	30.1± 4
Median (min‒max)	32 (21.8‒47.2)	30.4 (21.6‒40.4)
Lower facial height (degree)			0.91	0.80	1.03	0.126^c c Student's t
Mean ± SD	51.1± 4.6	49± 4.8
Median (min‒max)	51.2 (41.9‒64.3)	49.2 (39.4‒60.2)
Mandibular arch (degree)			0.99	0.94	1.05	0.787^c c Student's t
Mean ± SD	24.4± 12.4	23.6± 6.1
Median (min‒max)	22.1 (11.7‒84.6)	24.4 (11.7‒33.8)
Facial pattern classification						0.367^b b Likelihood-ratio
Mesofacial	4 (40)	6 (60)	1.00
Dolichofacial	27 (64.3)	15 (35.7)	0.37	0.09	1.52
Brachyfacial	2 (66.7)	1 (33.3)	0.33	0.02	5.03
Jarabak analysis
Posterior facial height (mm)			1.00	0.91	1.11	0.937^c c Student's t
Mean ± SD	55.5± 5.6	55.6± 4.9
Median (min‒max)	54.4 (46.8‒69.7)	55.9 (47.3‒64.2)
Anterior facial height (mm)			1.01	0.94	1.08	0.880^c c Student's t
Mean ± SD	94.6± 7.8	94.9± 8.1
Median (min‒max)	93.6 (79.5‒113.7)	94.3 (78.5‒107.5)
Jarabak index (%)			0.98	0.86	1.13	0.820^c c Student's t
Mean ± SD	58.6± 4.4	58.3± 3.7
Median (min‒max)	59 (50‒68)	58 (51‒67)
Growth pattern						0.887^b b Likelihood-ratio
Neutral	13 (61.9)	8 (38.1)	1.00
Hypodivergent	4 (66.7)	2 (33.3)	0.81	0.12	5.50
Hyperdivergent	16 (57.1)	12 (42.9)	1.22	0.38	3.87

Variable	OR	95%CI		p-value
		Inferior	Superior
Facial depth	1.29	1.06	1.57	0.012

Brasil

Brasil

Clinical and anatomical characteristics associated with obstructive sleep apnea severity in children

Abstract

Purpose

Methods

Results

Conclusions

Highlights

Highlights

Introduction

Materials and methods

Study sample

Inclusion criteria

Exclusion criteria

Clinical and anatomical analysis

Statistical analysis

Results

Discussion

Conclusion

Study limitations and future studies

Abbreviations

Acknowledgments

References

Publication Dates

History