How obesity affects nasal function in obstructive sleep apnea: anatomic and volumetric parameters

Rodrigues, Marcos Marques; Carvalho, Pedro Henrique de Azambuja; Gabrielli, Mário Francisco Real; Lopes, Ricardo Nasser; Garcia Junior, Otávio Alves; Pereira Filho, Valfrido Antonio; Passeri, Luis Augusto

doi:10.1016/j.bjorl.2020.06.002

Abstract

Introduction

Obstructive sleep apnea is a consequence of upper airway collapse. Any obstructive sector in the upper airway can contribute to pharyngeal collapse. Obesity and obesity-related disorders play an important role in obstructive sleep apnea and its relationship with increased upper airway resistance.

Objective

This study was designed to evaluate the relationship between obesity and properties of the nasal cavity in patients with obstructive sleep apnea.

Methods

The study was conducted retrospectively by review of medical records of adult patients. The nasal obstruction symptom evaluation, NOSE instrument, was used to measure nasal obstruction. Sleep breathing disorders were evaluated by polysomnography exams. Nasal volume was obtained by computed tomography scans and volumetric reconstruction of nasal airway. Nasal anatomic alterations were assessed by nasal endoscopy.

Results

Analysis of 83 patient records, among whom 54 were male and 29 females, found the mean body mass index of 28.69 kg/m². Obese and non-obese groups were determined by using cut-off 30 kg/m². In the comparison between groups, the obese group had a positive and significant correlation with apnea/hypopnea index (p= 0.02), NOSE instrument (p= 0.033) and inferior turbinate hypertrophy (p= 0.036), with odds ratio 1.983 (95% IC 1.048 − 3.753). nasal septum deviation (p= 0.126) and nasal airway volume evaluation (p= 0.177) showed no significant results.

Conclusion

Obesity was significantly correlated with subjective nasal obstruction, NOSE scale, and inferior turbinate hypertrophy in patients with obstructive sleep apnea. There was no correlation with the nasal volume evaluation.

Level of Evidence

3b - Individual case-control study.

Keywords
Nasal cavity; Obstructive sleep apnea; Nasal obstruction

Resumo

Introdução

A apneia obstrutiva do sono é consequência do colapso das vias aéreas superiores Qualquer região de obstrução nas vias aéreas superiores pode contribuir para o colapso da faringe. A obesidade e os distúrbios relacionados à obesidade desempenham um papel importante na apneia obstrutiva do sono e sua relação com o aumento da resistência das vias aéreas superiores.

Objetivo

Avaliar a relação entre a obesidade e as propriedades da cavidade nasal em pacientes com apneia obstrutiva do sono.

Método

O estudo foi feito retrospectivamente através da revisão de prontuários médicos de pacientes adultos. O instrumento de avaliação NOSE, do inglês nasal obstruction symptom evaluation, foi usado para avaliar a obstrução nasal. Os distúrbios respiratórios do sono foram avaliados através de exames polissonográficos. O volume nasal foi obtido por tomografia computadorizada e a reconstrução volumétrica das vias aéreas nasais. As alterações anatômicas nasais foram avaliadas por endoscopia nasal.

Resultados

A análise dos prontuários de 83 pacientes, entre os quais 54 eram do sexo masculino e 29 do feminino, encontrou um índice de massa corporal médio de 28,69 kg/m². Os grupos obeso e não obeso foram determinados com o ponto de corte de 30 kg/m². Na comparação entre os grupos, o grupo obeso apresentou correlação positiva e significante com o índice de apneia/hipopneia (p = 0,02), instrumento NOSE (p = 0,033) e hipertrofia da concha inferior (p = 0,036), com uma odds ratio de 1,983 (IC95%: 1,048 a 3,753). A avaliação do desvio do septo nasal (p = 0,126) e do volume das vias aéreas nasais (p = 0,177) não mostrou resultados significantes.

Conclusão

A obesidade correlacionou-se significantemente com a obstrução nasal subjetiva pela escala NOSE e hipertrofia de concha inferior em pacientes com apneia obstrutiva do sono. Não houve correlação com a avaliação do volume nasal.

Nível de evidência

3b. Estudo de caso-controle individual.

Palavras-chave
Cavidade nasal; Apneia obstrutiva do sono; Obstrução nasal

Introduction

The main pathophysiological site of obstructive sleep apnea (OSA) is the upper airway (UA).¹1 Young T, Finn L, Kim H. Nasal obstruction as a risk factor for sleep-disordered breathing. The University of Wisconsin Sleep and Respiratory Research Group. J Allergy Clin Immunol. 1997;99:S757-762. The American Academy of Sleep Medicine defines OSA as a recurrent upper airway collapse during sleep, resulting in a total (apnea) or partial (hypopnea) reduction of airflow.

Obesity is an isolated risk factor for OSA and its progression,²2 Resta O, Caratozzolo G, Pannacciulli N, Stefàno A, Giliberti T, Carpagnano GE, et al. Gender, age and menopause effects on the prevalence and the characteristics of obstructive sleep apnea in obesity. Eur J Clin Invest. 2003;33:1084-9.

3 Durán J, Esnaola S, Rubio R, Iztueta A. Obstructive sleep apneahypopnea and related clinical features in a population-based sample of subjects aged 30 to 70 yr. Am J Respir Crit Care Med. 2001;163 3 Pt 1:685-9.

4 Romero-Corral A, Caples SM, Lopez-Jimenez F, Somers VK. Interactions between obesity and obstructive sleep apnea: implications for treatment. Chest. 2010;137:711-9.-⁵5 Rodrigues MM, Gabrielli MFR, Garcia Junior OA, Pereira Filho VA, Passeri LA. Nasal airway evaluation in obstructive sleep apnoea patients: volumetric tomography and endoscopic findings. Int J Oral Maxillofac Surg. 2017;46:1284-90. and obesity-related disorders play an important role in OSA; its relationship with increased upper airway resistance has been shown in various studies.⁶6 Demir N, Sanli A, Demir G, Erdogan BA, Yilmaz HB, Paksoy M. The Evaluation of Relationship Between Body Mass Index and Nasal Geometry Using Objective and Subjective Methods. J Craniofac Surg. 2015;26:1861-4.

7 Suratt PM, McTier RF, Findley LJ, Pohl SL, Wilhoit SC. Changes in breathing and the pharynx after weight loss in obstructive sleep apnea. Chest. 1987;92:631-7.-⁸8 Wittels EH, Thompson S. Obstructive sleep apnea and obesity. Otolaryngol Clin North Am. 1990;23:751-60. Two-thirds of OSA patients are obese.⁹9 Richman RM, Elliott LM, Burns CM, Bearpark HM, Steinbeck KS, Caterson ID. The prevalence of obstructive sleep apnoea in an obese female population. Int J Obes Relat Metab Disord J Int Assoc Study Obes. 1994;18:173-7. A gain of 10% in baseline weight has been linked to a six fold-increased risk for OSA,¹⁰10 Peppard PE, Young T, Palta M, Dempsey J, Skatrud J. Longitudinal study of moderate weight change and sleep-disordered breathing. JAMA. 2000;284:3015-21. and an increase of one standard deviation in BMI has been associated with a 4 fold increase in AHI.¹¹11 Young T, Palta M, Dempsey J, Skatrud J, Weber S, Badr S. The occurrence of sleep-disordered breathing among middle-aged adults. N Engl J Med. 1993;328:1230-5. Metabolic dysregulation in subjects with OSA-Obesity, such as an increase in leptin levels, may lead to an increase in appetite and decrease in physical activity. Sleep deprivation and anxiety are also associated with this condition. This set of factors leads to a vicious circle that perpetuates this association.⁴4 Romero-Corral A, Caples SM, Lopez-Jimenez F, Somers VK. Interactions between obesity and obstructive sleep apnea: implications for treatment. Chest. 2010;137:711-9.

Patients with OSA-Obesity have been found to have fat deposition in the tissues surrounding the upper airway, increasing its collapsibility. Schwab et al., 2003, in a study using volumetric magnetic resonance imaging, found an increased fat deposition on the base of the tongue and lateral pharyngeal wall. These sites are more obstructive and therefore an important site of upper airway collapse in OSA subjects.¹²12 Schwab RJ, Pasirstein M, Pierson R, Mackley A, Hachadoorian R, Arens R, et al. Identification of upper airway anatomic risk factors for obstructive sleep apnea with volumetric magnetic resonance imaging. Am J Respir Crit Care Med. 2003;168:522-30.

To analyze UA stability, it is important to consider the external forces that compound the tissue pressure, whose main factor is obesity.¹²12 Schwab RJ, Pasirstein M, Pierson R, Mackley A, Hachadoorian R, Arens R, et al. Identification of upper airway anatomic risk factors for obstructive sleep apnea with volumetric magnetic resonance imaging. Am J Respir Crit Care Med. 2003;168:522-30. Increased adipose tissue in the neck presses on the pharyngeal wall, causing more negative transmural pressure. The upper airway muscles of these patients have a primary myopathy, which makes them more susceptible to collapse because of an accumulation of muscle composed of the more fatigable fiber type II.¹³13 Carrera M, Barbé F, Sauleda J, Tomás M, Gómez C, Agustí AG. Patients with obstructive sleep apnea exhibit genioglossus dysfunction that is normalized after treatment with continuous positive airway pressure. Am J Respir Crit Care Med. 1999;159:1960-6.

The presence of a point of upper airway obstruction (UAO) increases intraluminal negative pressure in the section located after the point of obstruction, which triggers the narrowing of this segment. Patients with nasal obstruction are more exposed to the collapse of the upper airways by increasing negative pressure on the lumen of the pharynx.¹⁴14 Kryger M. Anatomy and Physiology of Upper Airway Obstruction: Chapter 101 of Principles and Practice of Sleep Medicine. 5 edition Saunders; 2010. The nose contributes to half of total upper airway resistance.¹⁵15 Proctor DF. The upper airways. I. Nasal physiology and defense of the lungs. Am Rev Respir Dis. 1977;115:97-129.

There are several methods to evaluate the nose and analyze how nasal alterations affect UA resistance. Endoscopic and computed tomography (CT) findings are important for the identification of obstructive sites. The nasal obstruction symptom evaluation scale (NOSE) is a validated subjective test for evaluating nasal symptoms.¹⁶16 Stewart MG, Witsell DL, Smith TL, Weaver EM, Yueh B, Hannley MT. Development and validation of the Nasal Obstruction Symptom Evaluation (NOSE) scale. Otolaryngol Head Neck Surg. 2004;130:157-63. In this study the nasal volume was measured by CT volumetric reconstruction of the free spaces in the nasal cavity. Thus, the purpose this study was to evaluate whether there was any correlation between obesity and subjective/objective properties of the nasal cavity in patients with OSA.

Methods

This study was approved by the ethical committee in research, under the number 47794715.3.0000.5416, and all procedures followed were in accordance with the ethical standards of the responsible committee on human experimentation (institutional and national) and with the Helsinki Declaration of 1975, as revised in 2008.

It was carried out retrospectively by reviewing medical records of adult patients from the Oral and Maxillofacial Surgery Clinic and Otorhinolaryngology Clinic. Patients were evaluated at a specific ambulatory clinic for patients with complaints and symptoms related to respiratory sleep disorders. The following data were obtained from the medical records: otorhinolaryngology (ENT) examination, upper airway endoscopy, anthropometric variables, Body Mass Index (BMI), baseline polysomnography, and Computed Tomography (CT) scans to define the nasal cavity volume.

The NOSE Instrument (Nasal Obstruction Symptom Evaluation) was used to grade nasal obstruction. The scale consisted of 5 questions (nasal congestion, nasal blockage, trouble with breathing, exercise and sleeping) receiving scores ranging from 0 to 4. These scores were added and multiplied by 5. Thus, the NOSE Instrument ranged from 0 to 100.¹⁶16 Stewart MG, Witsell DL, Smith TL, Weaver EM, Yueh B, Hannley MT. Development and validation of the Nasal Obstruction Symptom Evaluation (NOSE) scale. Otolaryngol Head Neck Surg. 2004;130:157-63. This instrument is routinely applied to all patients with suspicion of OSA. All questionnaires were validated by the senior physician of the ambulatory clinic (MMR).

Upper airway endoscopy was performed to evaluate the anatomic alterations in the nose and pharynx. Possible findings included nasal septum deviations, inferior turbinate hypertrophy, tonsil hypertrophy and unstable sites of pharynx and larynx. Nasal Septum deviations (NSD) were considered when the septum blocked the fiberscope path and/or there was contact with the lateral wall of the nose. The size of the inferior turbinates we graded as follows: Grade 0 - no turbinates; Grade 1 − the inferior turbinates occupying <25% of nasal cavity; Grade 2 − the inferior turbinate occupying 25%−50% of nasal cavity; Grade 3 − the inferior turbinate occupying 50%−75% of the cavity; Grade 4 − the inferior turbinate occupying almost the nasal cavity and touching nasal septum.¹⁷17 Rao SUP, Basavaraj P, Yempalle SB, Ramachandra AD. A Prospective Study of Different Methods of Inferior Turbinate Reduction. J Clin Diagn Res JCDR. 2017;11. MC01-MC03.

18 Harju T, Honkanen M, Vippola M, Kivekäs I, Rautiainen M. The effect of inferior turbinate surgery on ciliated epithelium: A randomized, blinded study. Laryngoscope. 2019;129:18-24.-¹⁹19 McCoul ED, Todd CA, Riley CA. Posterior Inferior Turbinate Hypertrophy (PITH). Otolaryngol-Head Neck Surg Off J Am Acad Otolaryngol-Head Neck Surg. 2019;160:343-6. Inferior Turbinate Hypertrophy (ITH) was considered when the turbinate blocked the fiberscope path or Grades 3 − 4. All endoscopies were performed by means of a standardized protocol and validated by the senior physician of the ambulatory clinic. All procedures were recorded on video and described in a written report.

Sleep was assessed by polysomnography (PSG) type I, in an average period of six hours. The electrophysiological parameters evaluated during sleep were: electroencephalography (EEC), electrooculography (EOG), electromyography (EMG), electrocardiography (ECG), airflow (nasal and oral), respiratory effort (thoracic and abdominal), other body movements (by means of EMG), blood gases (oxygen saturation, carbon dioxide concentration) and body temperature. The technique was used as defined by the rules for scoring respiratory events in sleep from the American Academy of Sleep Medicine, 2012 manual.¹⁷17 Rao SUP, Basavaraj P, Yempalle SB, Ramachandra AD. A Prospective Study of Different Methods of Inferior Turbinate Reduction. J Clin Diagn Res JCDR. 2017;11. MC01-MC03. The severity of OSA was classified using apnea-hypopnea index as defined by AASM.¹⁸18 Harju T, Honkanen M, Vippola M, Kivekäs I, Rautiainen M. The effect of inferior turbinate surgery on ciliated epithelium: A randomized, blinded study. Laryngoscope. 2019;129:18-24. A medical specialist in sleep calculated the patients’ apnea-hypopnea index (AHI), obtained by the sum of the apnea and hypopnea events divided by the hours of sleep. This index was used to classify the severity of OSA as follows: normal (AHI < 5 events/hour), mild OSA (AHI between 5 and 15 events/hour), moderate OSA (AHI between 15 and 30 events/hour) and severe OSA (AHI > 30 events/hour).

The CT images were not a routine at this ambulatory visit. The patients that had a CT scan in our file were included in this study. The CT were obtained by means of 128 channel tomography with the patients placed in the supine position. All subjects were instructed to not swallow during image acquisition. The sections were obtained in the axial plane and reconstructed in the coronal plane, from the anterior nasal spine to the anterior limit of the nasopharynx. All images were stored on a DVD for later analysis by specific software.

The tridimensional images of the CT scans were imported and reconstructed by using the Osirix v.7.0 32 bit software (OsiriX Foundation, Geneva, Switzerland) to define the nasal volume.¹⁹19 McCoul ED, Todd CA, Riley CA. Posterior Inferior Turbinate Hypertrophy (PITH). Otolaryngol-Head Neck Surg Off J Am Acad Otolaryngol-Head Neck Surg. 2019;160:343-6. The images were fixed in the Frankfurt plane, perpendicular to the horizontal plane, by image software. Weissheimer et al. (2012), has demonstrated that Osirix Software was validated for evaluating the upper airway volume.

Thus, images would be generated, corresponding to consecutive coronal sections of the region of interest, with spacing of 4 mm. A trained blinded observer conducted the evaluation process. The evaluation was repeated in 30% (minimum value to validate the standard error) of the sample, by the same evaluator, after a minimum period of 30 days to establish the method error. The values obtained in the reevaluation were similar to those of the first measures.

All measurements were performed in the coronal plane of CT slices with a thickness of 0.25 mm and 4 mm distance between slices. To determine the nasal airway volume, the area was measured in all the CT slices. The outline of the nasal airway in each slice was manually traced by means of the computer trackpad, considering only the free space of the nasal cavity; that is, turbinate and septum deviations were not included in the area calculation (Fig. 1). The software tool OsiriX calculated the area automatically. Then for each section of the CT, the area already given, a TIFF image was generated. This process was performed in both nasal cavities in the same slice in the coronal plane.

Figure 1
Coronal cut area delimitation and volume reconstruction. (A, CT coronal Cut; B, Reconstruction Technique) (From Rodrigues et al., 2017).⁵5 Rodrigues MM, Gabrielli MFR, Garcia Junior OA, Pereira Filho VA, Passeri LA. Nasal airway evaluation in obstructive sleep apnoea patients: volumetric tomography and endoscopic findings. Int J Oral Maxillofac Surg. 2017;46:1284-90..

The Nasal Airway Volume (NAV) measured in each computed tomography slice was calculated by multiplying the area and height, which was equivalent to the distance between the coronal slices. The OsiriX software tool calculated the area of the missed slices spaced by 4 mm. The volume of the entire nose free airway was the sum of all volumes measured in each slice. NAV was the sum of volume obtained from both sides of the nasal cavity. The NAV obtained was similar to a pyramidal structure composed of the free airway space of the nose.

Inclusion/exclusion criteria

Patients evaluated from December 2014 to December 2015, with OSA diagnosis, were included; both genders with age ranging between 18 and 70 years.

We excluded patients with the following conditions:

Morbid Obesity (BMI > 40), due to technical limitations on CT scan machine.

Craniofacial abnormalities (cranio-dysostosis, craniostenosis and meningomyelocele);

Nasal obstruction due to nasal polyps;

Presence of any craniofacial or airway tumor;

Laryngeal and pharyngeal paralysis;

Previous surgery on the UA.

Absence of CT or PSG records.

Statistical analysis

Data were analyzed by statistical descriptive tests and frequency of results. The Kolgomorov-Smirnov Normality Test was used to establish the adequate test for variables. For the Nasal Volume and Nose Scale correlation analysis, the Mann-Whitney test was chosen. Chi-Square test was chosen for analysis of nominal variables. SAS System for Windows (Statistical Analysis System), version 9.3 software (SAS Institute Inc, 2002 − 2008, Cary, NY, USA) was used for the analysis.

Results

Ninety patients were evaluated from December 2014 to December 2015. Seven patients were excluded from the sample because three had tomographic scans with poor definition of the limits determined in the methodology, and four had incomplete data necessary for the research protocol. Therefore, 83 patients were included in the study, 29 (34.9%) females and 54 (65.1%) males. The descriptive analysis of the main variables is shown in Table 1.

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Table 1
Descriptive variables by Kolmogorov-Smirnov Test.

The above-mentioned test showed that the NOSE Scale and AHI did not have a normal distribution in this sample.

The sample variables were evaluated in gender groups. The analysis is shown in Table 2.

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Table 2
Mean Comparison in Gender Groups.

This data demonstrate that gender does not influence the nasal variables. The statistical significance was found only in AIH as literature preview. The subjects were divided into Obese and Non-Obese groups using a cut-off of 30 kg/m² (Table 3).

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Table 3
Group Statistics by Obesity Group.

The data above demonstrated that the obese group had a significant positive correlation with the NOSE Scale (p= 0.033) and AHI (p= 0.020). There was no difference in the Nasal Volume evaluation (p = 0.177) between the groups. Cross tabulation between Inferior Turbinate Hypertrophy (ITH) and Obesity showed a significant correlation (p= 0.036). Odds ratio for ITH in obese group was 1.983 with 95% Confidence Interval of 1.048 − 3.753. There was no significant difference for NSD.

The ITH group had a significant positive correlation with the NOSE Scale (p= 0.041) and BMI (p= 0.044). There was no difference in the Nasal Volume evaluation (p= 0.198) and AHI (p= 0.051) between the groups (Table 4).

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Table 4
Group Statistics by ITH Group.

Discussion

Sleep apnea is an upper airway disease in which the pharynx is the main site affected. Nasal obstruction should be considered in the analysis of the balance between the opening and collapsing forces. Patients with nasal obstruction are more exposed to upper airway collapse by increasing negative pressure on the lumen of the pharynx.¹⁴14 Kryger M. Anatomy and Physiology of Upper Airway Obstruction: Chapter 101 of Principles and Practice of Sleep Medicine. 5 edition Saunders; 2010. Studies have shown that nasal obstruction is a risk factor for OSA but there is no linear association between obstruction and severity of sleep-disordered breathing.¹1 Young T, Finn L, Kim H. Nasal obstruction as a risk factor for sleep-disordered breathing. The University of Wisconsin Sleep and Respiratory Research Group. J Allergy Clin Immunol. 1997;99:S757-762. Approximately 15% of patients with sleep-disordered breathing also have nasal obstruction.²⁰20 Berry RB, Budhiraja R, Gottlieb DJ, Gozal D, Iber C, Kapur VK, et al. Rules for scoring respiratory events in sleep: update of the 2007 AASM Manual for the Scoring of Sleep and Associated Events. Deliberations of the Sleep Apnea Definitions Task Force of the American Academy of Sleep Medicine. J Clin Sleep Med JCSM Off Publ Am Acad Sleep Med. 2012;8:597-619.

In this sample it was demonstrated that Endoscopic Nasal findings (NSD/ITH) are more important than NAV in appreciation of OSA patients. In the calculation of NAV the entire nasal cavity was considered, including the segment after a possible point of maximum obstruction, a gain of air flow that decreases intraluminal pressure in cranial segments of upper airway, leading a collapse of upper airway in the pharynx.²¹21 Sleep-related breathing disorders in adults: recommendations for syndrome definition and measurement techniques in clinical research. The Report of an American Academy of Sleep Medicine Task Force. Sleep. 1999;22:667-89.

The correlation between Nasal Obstruction and OSA is controversial. Haddad et al., 2013, evaluated nasal function with nasofibroscopy, nasal inspiratory peak flow and acoustic rhinometry in CPAP adherence. The results demonstrated that the majority of the nasal parameters evaluated in this study did not influence CPAP adherence.²¹21 Sleep-related breathing disorders in adults: recommendations for syndrome definition and measurement techniques in clinical research. The Report of an American Academy of Sleep Medicine Task Force. Sleep. 1999;22:667-89.

In our sample, obese subjects had more nasal symptoms, as shown by the NOSE Scale. Inferior Turbinate Hypertrophy was also correlated with obesity. Obese/OSA patients have 1.983 times greater chance of developing ITH. Subjects with ITH had higher NOSE scores, higher BMI and similar Nasal Volume when compared with non-ITH group. This result can demonstrate that ITH had a relationship with obesity independently of Nasal Volume and gender. Martinho et al., 2008, found similar results: 65.7% of OSA/Obese patients had ITH (p< 0.05).²²22 Weissheimer A, Menezes LM de, Sameshima GT, Enciso R, Pham J, Grauer D. Imaging software accuracy for 3-dimensional analysis of the upper airway. Am J Orthod Dentofac Orthop Off Publ Am Assoc Orthod Its Const Soc Am Board Orthod. 2012;142:801-13. This correlation was not significant when NAV was evaluated. NAV is a variable that evaluates all the free airway space but does not evaluate the airflow in the nose. For example, in a patient with a nasal airway blocked by ITH, NAV will include the volume after and above the airway blockage; that is, a site with compromised airflow.

Gender did not influence the relationship between obesity and nasal function. There is no difference in NOSE and Nasal Volume scores. It’s expected that female subjects have a smaller nasal cavity, but this link was not observed in this sample. The only significant difference was shown in AIH that is reflected in the literature.¹¹11 Young T, Palta M, Dempsey J, Skatrud J, Weber S, Badr S. The occurrence of sleep-disordered breathing among middle-aged adults. N Engl J Med. 1993;328:1230-5.

Demir et al., 2015, found similar results, showing a statistically significant correlation between the increase in body mass and the increase in NOSE score, but they found no significant result when they evaluated nasal function using acoustic rhinometry; however, in their study they did not evaluate patients with OSA.⁶6 Demir N, Sanli A, Demir G, Erdogan BA, Yilmaz HB, Paksoy M. The Evaluation of Relationship Between Body Mass Index and Nasal Geometry Using Objective and Subjective Methods. J Craniofac Surg. 2015;26:1861-4.

Obesity and OSA are conditions linked to higher levels of inflammatory cytokines in nasal tissue, such as C-reactive protein, tumor necrosis factor alpha, interleukins (4, 13, 5, 8, 9), and granulocyte-macrophage colony-stimulating factor. OSA-Obese patients have more inflammatory markers in the tissue.²³23 Young T, Finn L, Kim H. Nasal obstruction as a risk factor for sleep-disordered breathing. The University of Wisconsin Sleep and Respiratory Research Group. J Allergy Clin Immunol. 1997;99:S757-762. The inferior turbinate is contractile and is the main site exposed to changes by inflammatory status of the nose. Inflammatory markers and edema resulting from respiratory trauma and snoring could explain the increased inferior turbinate findings in OSA-Obese subjects.²²22 Weissheimer A, Menezes LM de, Sameshima GT, Enciso R, Pham J, Grauer D. Imaging software accuracy for 3-dimensional analysis of the upper airway. Am J Orthod Dentofac Orthop Off Publ Am Assoc Orthod Its Const Soc Am Board Orthod. 2012;142:801-13. Obesity also was pointed out as a cause of failure of treatment of the inferior turbinate conditions with radiofrequency.²⁴24 Mayer-Brix J, Müller-Marschhausen U, Becker H, Peter JH. How frequent are pathologic ENT findings in patients with obstructive sleep apnea syndrome? HNO. 1989;37:511-6.

Obesity is an important condition that contributes to daytime Leg Fluid Accumulation (LFA), such as heart failure and end-stage renal disease.²⁵25 Haddad FLM, Vidigal T, Mello-Fujita L, Cintra FD, Gregório LC, Tufik S, et al. The influence of nasal abnormalities in adherence to continuous positive airway pressure device therapy in obstructive sleep apnea patients. What role does the nose play? Sleep Breath Schlaf Atm. 2015;19:5-6.,²⁶26 Martinho FL, Tangerina RP, Moura SMGT, Gregório LC, Tufik S, Bittencourt LRA. Systematic head and neck physical examination as a predictor of obstructive sleep apnea in class III obese patients. Braz J Med Biol Res Rev Bras Pesqui Medicas E Biol. 2008;41:1093-7. Significant correlation has been shown between OSA and LFA. During recumbence the leg fluid was redistributed rostrally; approximately 260 mL of fluid was redistributed from the legs and was associated with a 1 cm increase in neck circumference, indicating neck fluid accumulation.²⁷27 Li K, Wei P, Qin Y, Wei Y. Is C-reactive protein a marker of obstructive sleep apnea? A meta-analysis. Medicine (Baltimore). 2017;96:e6850. These studies have suggested that alterations in upper airway mucosa could directly affect the inferior turbinate in OSA/obese patients by more fluid redistribution and more chronic inflammation in the nasal mucosa.

The main treatments of OSA in obese patients are CPAP therapy and bariatric surgery.²⁸28 Akdag M, Dasdag S, Ozkurt FE, Celik MY, Degirmenci A, Demir H, et al. Long-term effect of radiofrequency turbinoplasty in nasal obstruction. Biotechnol Biotechnol Equip. 2014;28:285-94. The AHI Increases as Weight Increases.²⁹29 Yumino D, Redolfi S, Ruttanaumpawan P, Su M-C, Smith S, Newton GE, et al. Nocturnal rostral fluid shift: a unifying concept for the pathogenesis of obstructive and central sleep apnea in men with heart failure. Circulation. 2010;121:1598-605. OSA is common in patients undergoing gastric bypass surgery. Bariatric surgery can reduce BMI and decrease fat pads surrounding the pharynx. Buchwald et al., 2004 in a meta-analysis showed that OSA was resolved in 85.7% of patients undergoing bariatric surgery.³⁰30 White LH, Bradley TD, Logan AG. Pathogenesis of obstructive sleep apnoea in hypertensive patients: role of fluid retention and nocturnal rostral fluid shift. J Hum Hypertens. 2015;29:342-50.

Nevertheless, nasal surgery appears to reliably augment CPAP compliance when nasal patency is the limiting issue.³¹31 Redolfi S, Yumino D, Ruttanaumpawan P, Yau B, Su M-C, Lam J, et al. Relationship between overnight rostral fluid shift and Obstructive Sleep Apnea in nonobese men. Am J Respir Crit Care Med. 2009;179:241-6. When evaluating OSA in obese patients it is important not to look for alterations in the pharynx alone. The Obese/OSA patients have more nasal symptoms. Our results demonstrated the importance of full evaluation of OSA patients. Nasal obstruction treatments cannot improve AHI but nasal steroids and nasal surgery can improve sleep and quality of life.³²32 White DP. Sleep apnea. Proc Am Thorac Soc. 2006;3:124-8. The nasal examination is fundamental for appropriate CPAP adherence mainly in obese-OSA patients who, in our sample, had 1.983 times more risk of nasal obstruction due to ITH. This relationship can be explained by the increase in inflammatory markers, mucosa vibration and LFA redistribution in obese patients.³³33 Wolk R, Shamsuzzaman ASM, Somers VK. Obesity, sleep apnea, and hypertension. Hypertens Dallas Tex. 1979;2003(42):1067-74.,³⁴34 Buchwald H, Avidor Y, Braunwald E, Jensen MD, Pories W, Fahrbach K, et al. Bariatric surgery: a systematic review and meta-analysis. JAMA. 2004;292:1724.

Conclusion

In conclusion, obesity was correlated with subjective nasal obstruction (NOSE Scale) and inferior turbinate hypertrophy in patients with OSA. There was no correlation with the Nasal Volume evaluation. Thorough nasal evaluation is important in OSA patients to create a suitable treatment plan.

☆
Study conducted at Oral and Maxillofacial Surgery Division of the Dental School at Araraquara − Unesp, and from the Otorhinolaryngology Clinics of the Medical School at the University of Araraquara - Uniara, Araraquara, SP, Brazil.
Peer Review under the responsibility of Associação Brasileira de Otorrinolaringologia e Cirurgia Cérvico-Facial.

References

¹
Young T, Finn L, Kim H. Nasal obstruction as a risk factor for sleep-disordered breathing. The University of Wisconsin Sleep and Respiratory Research Group. J Allergy Clin Immunol. 1997;99:S757-762.
²
Resta O, Caratozzolo G, Pannacciulli N, Stefàno A, Giliberti T, Carpagnano GE, et al. Gender, age and menopause effects on the prevalence and the characteristics of obstructive sleep apnea in obesity. Eur J Clin Invest. 2003;33:1084-9.
³
Durán J, Esnaola S, Rubio R, Iztueta A. Obstructive sleep apneahypopnea and related clinical features in a population-based sample of subjects aged 30 to 70 yr. Am J Respir Crit Care Med. 2001;163 3 Pt 1:685-9.
⁴
Romero-Corral A, Caples SM, Lopez-Jimenez F, Somers VK. Interactions between obesity and obstructive sleep apnea: implications for treatment. Chest. 2010;137:711-9.
⁵
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Publication Dates

Publication in this collection
27 June 2022
Date of issue
May-Jun 2022

History

Received
04 Dec 2018
Accepted
07 June 2020

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.

[1] ☆
Study conducted at Oral and Maxillofacial Surgery Division of the Dental School at Araraquara − Unesp, and from the Otorhinolaryngology Clinics of the Medical School at the University of Araraquara - Uniara, Araraquara, SP, Brazil.

[2] Peer Review under the responsibility of Associação Brasileira de Otorrinolaringologia e Cirurgia Cérvico-Facial.

	BMI	NOSE scale	AHI	Nasal volume
n	83	83	83	83
Mean ± Std. deviation	28.70	39.52	27.94	17.25
Mean ± Std. deviation	4.06	19.67	27.59	4.15
Kolmogorov-Smirnov Z	0.629	2.296	1.64	0.800
p	0.824	0.001	0.009	0.545

	Gender	Mean	Std. deviation	p
NOSE	Male	40.95	20.60	0.935^a a Mann-Whitney test.
NOSE	Female	39.00	16.73	0.935^a a Mann-Whitney test.
AIH	Male	36.18	29.47	0.0001^a a Mann-Whitney test.
AIH	Female	10.24	8.24	0.0001^a a Mann-Whitney test.
Nasal volume	Male	17.97	4.35	0.155^b b Students-t test.
Nasal volume	Female	15.85	3.74	0.155^b b Students-t test.
BMI	Male	29.07	3.90	0.474^b b Students-t test.
BMI	Female	27.97	4.05	0.474^b b Students-t test.

	Obesity group	n	Mean	Std. deviation	Percent	p
NOSE Scale	Non-obese	56	37.11	18.16	−	0.033^a a Mann-Whitney test.
NOSE Scale	Obese	27	44.52	21.99	−	0.033^a a Mann-Whitney test.
AHI	Non-Obese	56	22.47	23.59	−	0.020^a a Mann-Whitney test.
AHI	Obese	27	39.28	32.02	−	0.020^a a Mann-Whitney test.
Nasal volume	Non-Obese	56	16.78	3.85	−	0.177^b b Student’s-t test.
Nasal volume	Obese	27	18.29	4.62	−	0.177^b b Student’s-t test.
ITH ^c c Inferior Turbinate Hypertrophy.	Non-obese	56	−	−	13/56 (23%)	0.036^e e Chi-Square Test.
ITH ^c c Inferior Turbinate Hypertrophy.	Obese	27	−	−	13/27(48%)	0.036^e e Chi-Square Test.
NSD ^d d Nasal Septum Deviation.	Non-obese	56	−	−	29/56 (51%)	0.126^e e Chi-Square Test.
NSD ^d d Nasal Septum Deviation.	Obese	27	−	−	18/27(66%)	0.126^e e Chi-Square Test.

	ITH	Mean	Std. deviation	p
NOSE	Yes	45.86	21.46	0.041^a a Mann-Whitney test.
NOSE	No	37.81	18.38	0.041^a a Mann-Whitney test.
AIH	Yes	33.93	31.42	0.051^a a Mann-Whitney test.
AIH	No	23.10	24.65	0.051^a a Mann-Whitney test.
Nasal volume	Yes	17.09	5.08	0.198^b b Student’s-t test.
Nasal volume	No	17.36	3.98	0.198^b b Student’s-t test.
BMI	Yes	29.70	3.49	0.044^b b Student’s-t test.
BMI	No	27.96	3.94	0.044^b b Student’s-t test.

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Nível de evidência

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History