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Abstract

Background

Past studies reported a low correlation between rhinomanometry and computational fluid dynamics (CFD), but the source of the discrepancy was unclear. Low correlation or lack of correlation has also been reported between subjective and objective measures of nasal patency.

Objective:

This study investigates (1) the correlation and agreement between nasal resistance derived from CFD (R_CFD) and rhinomanometry (R_RMN), and (2) the correlation between objective and subjective measures of nasal patency.

Methods

Twenty-five patients with nasal obstruction underwent anterior rhinomanometry before and after mucosal decongestion with oxymetazoline. Subjective nasal patency was assessed with a 0-10 visual analog scale (VAS). CFD simulations were performed based on computed tomography scans obtained after mucosal decongestion. To validate the CFD methods, nasal resistance was measured in vitro (R_EXPERIMENT) by performing pressure-flow experiments in anatomically accurate plastic nasal replicas from 6 individuals.

Results

Mucosal decongestion was associated with a reduction in bilateral nasal resistance (0.34 ± 0.23 Pa.s/ml to 0.19 ± 0.24 Pa.s/ml, p = 0.003) and improved sensation of nasal airflow (bilateral VAS decreased from 5.2 ± 1.9 to 2.6 ± 1.9, p < 0.001). A statistically significant correlation was found between VAS in the most obstructed cavity and unilateral airflow before and after mucosal decongestion (r = −0.42, p = 0.003). Excellent correlation was found between R_CFD and R_EXPERIMENT (r = 0.96, p < 0.001) with good agreement between the numerical and in vitro values (R_CFD/R_EXPERIMENT = 0.93 ± 0.08). A weak correlation was found between R_CFD and R_RMN (r = 0.41, p = 0.003) with CFD underpredicting nasal resistance derived from rhinomanometry (R_CFD/R_RMN = 0.65 ± 0.63). A stronger correlation was found when unilateral airflow at a pressure drop of 75 Pa was used to compare CFD with rhinomanometry (r = 0.76, p < 0.001).

Conclusion

CFD and rhinomanometry are moderately correlated, but CFD underpredicts nasal resistance measured in vivo due in part to the assumption of rigid nasal walls. Our results confirm previous reports that subjective nasal patency correlates better with unilateral than with bilateral measurements and in the context of an intervention.

Keywords

anterior rhinomanometry computational fluid dynamics correlation experimental validation or in vitro experiments in vivo measurements nasal airway obstruction nasal resistance and nasal airflow nose and vas scores numerical simulations subjective nasal patency

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References

Sundh

Sunnergren

Long-term symptom relief after septoplasty. Eur Arch Otorhinolaryngol. 2015; 272(10): 2871–2875.

Dinis

Haider

Septoplasty: long-term evaluation of results. Am J Otolaryngol. 2002; 23(2):85–90.

Yuen

Tang

, et al. Time course in the relief of nasal blockage after septal and turbinate surgery: a prospective study. Arch Otolaryngol Head Neck Surg. 2004; 130(3):324–328.

Jessen

Ivarsson

Malm

Nasal airway resistance and symptoms after functional septoplasty: comparison of findings at 9 months and 9 years. Clin Otolaryngol Allied Sci. 1989; 14(3):231–234.

Holmstrom

The use of objective measures in selecting patients for septal surgery. Rhinology. 2010; 48(4):387–393.

Andre

Vuyk

Ahmed

, et al. Correlation between subjective and objective evaluation of the nasal airway. A systematic review of the highest level of evidence. Clin Otolaryngol. 2009; 34(6):518–525.

Kimbell

Frank

Laud

, et al. Changes in nasal airflow and heat transfer correlate with symptom improvement after surgery for nasal obstruction. J Biomech. 2013; 46(15):2634–2643.

Sullivan

Garcia

Frank-Ito

, et al. Perception of better nasal patency correlates with increased mucosal cooling after surgery for nasal obstruction. Otolaryngol Head Neck Surg. 2014; 150(1):139–147.

Gaberino

Rhee

Garcia

GJ.

Estimates of nasal airflow at the nasal cycle mid-point improve the correlation between objective and subjective measures of nasal patency. Respir Physiol Neurobiol. 2017; 238:23–32.

10.

Casey

Borojeni

Koenig

, et al. Correlation between subjective nasal patency and intranasal airflow distribution. Otolaryngol Head Neck Surg. 2017; 156(4):741–750.

11.

Zhao

Jiang

Blacker

, et al. Regional peak mucosal cooling predicts the perception of nasal patency. Laryngoscope. 2014; 124(3):589–595.

12.

Radulesco

Meister

Bouchet

, et al. Correlations between computational fluid dynamics and clinical evaluation of nasal airway obstruction due to septal deviation: an observational study. Clin Otolaryngol. 2019; 44(4):603–611.

13.

Sozansky

Houser

SM.

The physiological mechanism for sensing nasal airflow: a literature review. Int Forum Allergy Rhinol. 2014; 4(10):834–838.

14.

Bailey

Casey

Pawar

, et al. Correlation of nasal mucosal temperature with subjective nasal patency in healthy individuals. JAMA Facial Plast Surg. 2017; 19(1):46–52.

15.

Newsome

L Lin

Poetker

, et al. Clinical importance of nasal air conditioning: a review of the literature. Am J Rhinol Allergy. 2019; 33(6):763–769.

16.

Hariri

Rhee

Garcia

GJ.

Identifying patients who may benefit from inferior turbinate reduction using computer simulations. Laryngoscope. 2015; 125(12):2635–2641.

17.

Sanmiguel-Rojas

Burgos

Esteban-Ortega

Nasal surgery handled by CFD tools. Int J Numer Method Biomed Eng. 2018; 34(10):e3126.

18.

Moghaddam

Garcia

GJM

Frank-Ito

, et al. Virtual septoplasty: a method to predict surgical outcomes for patients with nasal airway obstruction. Int J Comput Assist Radiol Surg. 2020; 15(4):725–735.

19.

Quammen

Taylor

Krajcevski

, et al. The virtual pediatric airways workbench. Stud Health Technol Inform. 2016; 220:295–300.

20.

Burgos

Sanmiguel-Rojas

Del Pino

, et al. New CFD tools to evaluate nasal airflow. Eur Arch Otorhinolaryngol. 2017; 274(8):3121–3128.

21.

Vanhille

Garcia

GJM

Asan

, et al. Virtual surgery for the nasal airway: a preliminary report on decision support and technology acceptance. JAMA Facial Plast Surg. 2018; 20(1):63–69.

22.

Hildebrandt

Bruning

Lamecker

, et al. Digital analysis of nasal airflow facilitating decision support in rhinosurgery. Facial Plast Surg. 2019; 35(1):3–8.

23.

Wootton

Luo

Persak

, et al. Computational fluid dynamics endpoints to characterize obstructive sleep apnea syndrome in children. J Appl Physiol (1985). 2014; 116(1):104–112.

24.

Stewart

Witsell

Smith

, et al. Development and validation of the nasal obstruction symptom evaluation (NOSE) scale. Otolaryngol Head Neck Surg. 2004; 130(2):157–163.

25.

Bezerra

Padua

Pilan

, et al. Cross-cultural adaptation and validation of a quality of life questionnaire: the nasal obstruction symptom evaluation questionnaire. Rhinology. 2011; 49(2):227–231.

26.

Braun

Rich

Berghaus

, et al. Effects of oxymetazoline nasal spray on the nasal cycle assessed by long-term rhinoflowmetry. Rhinology. 2012; 50(4):370–375.

27.

Cherobin

Voegels

Gebrim

, et al. Sensitivity of nasal airflow variables computed via computational fluid dynamics to the computed tomography segmentation threshold. PLoS One. 2018; 13(11):e0207178.

28.

Patel

Garcia

Frank-Ito

, et al. Simulating the nasal cycle with computational fluid dynamics. Otolaryngol Head Neck Surg. 2015; 152(2):353–360.

29.

Clement

Gordts

; Standardisation Committee on Objective Assessment of the Nasal Airway, IRS, and ERS. Consensus report on acoustic rhinometry and rhinomanometry. Rhinology. 2005; 43(3):169–179.

30.

Maalouf

Bequignon

Devars Du Mayne

, et al. A functional tool to differentiate nasal valve collapse from other causes of nasal obstruction: the FRIED test. J Appl Physiol. 2016; 121(1):343–347.

31.

Kimbell

Basu

Garcia

GJM

, et al. Upper airway reconstruction using long-range optical coherence tomography: effects of airway curvature on airflow resistance. Lasers Surg Med. 2019; 51(2):150–160.

32.

Kelly

Prasad

Wexler

AS.

Detailed flow patterns in the nasal cavity. J Appl Physiol. 2000; 89(1):323–337.

33.

Jiang

Dong

, et al. Computational modeling and validation of human nasal airflow under various breathing conditions. J Biomech. 2017; 64:59–68.

34.

Mylavarapu

Murugappan

Mihaescu

, et al. Validation of computational fluid dynamics methodology used for human upper airway flow simulations. J Biomech. 2009; 42(10):1553–1559.

35.

Giavarina

Understanding bland Altman analysis. Biochem Med (Zagreb). 2015; 25(2):141–151.

36.

Cherobin

GB.

Rinomanometria Realizada Por Meio da Fluidodinâmica Computacional [PhD dissertation]. São Paulo, Brazil: Universidade de São Paulo; 2017.

37.

Aksoy

Veyseller

Yildirim

, et al. Role of nasal muscles in nasal valve collapse. Otolaryngol Head Neck Surg. 2010; 142(3):365–369.

38.

Hamilton

GS.

The external nasal valve. Facial Plast Surg Clin North Am. 2017; 25(2):179–194.

39.

Kienstra

Gassner

Sherris

, et al. Effects of the nasal muscles on the nasal airway. Am J Rhinol. 2005; 19(4):375–381.

40.

Resuli

Oktem

Ataus

The role of the depressor nasi septi muscle in nasal air flow. Aesthetic Plast Surg. 2020;44(5):1766–1775. doi: 10.1007/s00266-020-01693-3

41.

Quadrio

Pipolo

Corti

, et al. Effects of CT resolution and radiodensity threshold on the CFD evaluation of nasal airflow. Med Biol Eng Comput. 2016; 54(2–3):411–419.

42.

Zwicker

Yang

Melchionna

, et al. Validated reconstructions of geometries of nasal cavities from CT scans. Biomed Phys Eng Express. 2018; 4(4):045022.

43.

Inthavong

Chetty

Shang

, et al. Examining mesh independence for flow dynamics in the human nasal cavity. Comput Biol Med. 2018; 102:40–50.

44.

Frank-Ito

Wofford

Schroeter

, et al. Influence of mesh density on airflow and particle deposition in sinonasal airway modeling. J Aerosol Med Pulm Drug Deliv. 2016; 29(1):46–56.

45.

Hasegawa

Kern

EB.

Variations in nasal resistance in man: a rhinomanometric study of the nasal cycle in 50 human subjects. Rhinology. 1978; 16:19–29.

46.

Eccles

Nasal airflow in health and disease. Acta Otolaryngol. 2000; 120(5):580–595.

47.

Rundcrantz

Postural variations of nasal patency. Acta Otolaryngol. 1969; 68(5):435–443.

48.

Broms

Rhinomanometry. III. Procedures and criteria for distinction between skeletal stenosis and mucosal swelling. Acta Otolaryngol. 1982; 94(3–4): 361–370.

49.

Eccles

A guide to practical aspects of measurement of human nasal airflow by rhinomanometry. Rhinology. 2011; 49(1):2–10.

50.

van Egmond

van Heerbeek

Ter Haar

ELM

, et al. Clinimetric properties of the Glasgow health status inventory, Glasgow benefit inventory, peak nasal inspiratory flow, and 4-phase rhinomanometry in adults with nasal obstruction. Rhinology. 2017; 55(2):126–134.

51.

Han

Zhang

Accuracy evaluation of a numerical simulation model of nasal airflow. Acta Otolaryngol. 2014; 134(5):513–519.

52.

Osman

Großmann

Brosien

, et al. Assessment of nasal resistance using computational fluid dynamics. Curr Dir Biomed Eng. 2016; 2(1):617–621.

53.

Hemtiwakorn

Mahasitthiwat

Tungjitkusolmun

, et al. Patient-Specific aided surgery approach of deviated nasal septum using computational fluid dynamics. IEEJ Trans Electric Electron Eng. 2015; 10(3):274–286.

54.

Moreddu

Meister

Philip-Alliez

, et al. Computational fluid dynamics in the assessment of nasal obstruction in children. Eur Ann Otorhinolaryngol Head Neck Dis. 2019; 136(2):87–92.

55.

Kelly

Asgharian

Kimbell

, et al. Particle deposition in human nasal airway replicas manufactured by different methods. Part I: inertial regime particles. Aerosol Sci Tech. 2004; 38(11):1063–1071.

56.

Carney

Bateman

Jones

NS.

Reliable and reproducible anterior active rhinomanometry for the assessment of unilateral nasal resistance. Clin Otolaryngol Allied Sci. 2000; 25(6):499–503.

57.

Vogt

Jalowayski

Althaus

, et al. 4-phase-rhinomanometry (4PR)–basics and practice 2010. Rhinol Suppl. 2010; 21:1–50.

58.

O'Neill

Tolley

NS.

Theoretical considerations of nasal airflow mechanics and surgical implications. Clin Otolaryngol Allied Sci. 1988; 13(4):273–277.

59.

O'Neill

Tolley

NS.

The complexities of nasal airflow—theory and practice. J Appl Physiol. 2019; 127(5):1215–1223.

60.

Akmenkalne

Prill

Vogt

Nasal valve elastography: quantitative determination of the mobility of the nasal valve. Rhinology Online. 2019; 2(2):81–86.

61.

Moghaddam

Woodson

, et al. Airflow limitation in a collapsible model of the human pharynx: physical mechanisms studied with fluid-structure interaction simulations and experiments. Physiol Rep. 2019; 7(10):e14099.

62.

Horschler

Schroder

Meinke

On the assumption of steadiness of nasal cavity flow. J Biomech. 2010; 43(6):1081–1085.

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Rhinomanometry Versus Computational Fluid Dynamics: Correlated,but Different Techniques

Abstract

Background

Objective:

Methods

Results

Conclusion

Keywords

Get full access to this article

References

Supplementary Material