An investigation on airflow in pathological nasal airway by PIV

Kim, S. K.; Haw, Jung Rim

doi:10.1007/bf03181538

Cited by 7 publications

(4 citation statements)

References 7 publications

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“…Lack of meshing elements especially at the thin turbinates region inside the nasal cavity will cause failure in capturing nasal airflow in the crucial areas. The results showed that the grid dependency study resulted in an optimized meshing of 1,109,123 elements, and the computational results are validated with the pressure drop obtained from Kim and Son [31] and Wen et al [15, 17] as shown in Figure 5.…”

Section: Methodssupporting

confidence: 76%

Standardization of Malaysian Adult Female Nasal Cavity

Lee

Abdullah

Ahmad

et al. 2013

Computational and Mathematical Methods in Medicine

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This research focuses on creating a standardized nasal cavity model of adult Malaysian females. The methodology implemented in this research is a new approach compared to other methods used by previous researchers. This study involves 26 females who represent the test subjects for this preliminary study. Computational fluid dynamic (CFD) analysis was carried out to better understand the characteristics of the standardized model and to compare it to the available standardized Caucasian model. This comparison includes cross-sectional areas for both half-models as well as velocity contours along the nasal cavities. The Malaysian female standardized model is larger in cross-sectional area compared to the standardized Caucasian model thus leading to lower average velocity magnitudes. The standardized model was further evaluated with four more Malaysian female test subjects based on its cross-sectional areas and average velocity magnitudes along the nasal cavities. This evaluation shows that the generated model represents an averaged and standardized model of adult Malaysian females.

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Section: Methodssupporting

confidence: 76%

Standardization of Malaysian Adult Female Nasal Cavity

Lee

Abdullah

Ahmad

et al. 2013

Computational and Mathematical Methods in Medicine

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“…Velocity distributions in the coronal planes provide better visualization for the direction of the main stream as shown in figure 7, where coloured levels denote the amplitude of average and RMS velocities. Flow characteristics related to abnormalities in nasal cavities can be conjectured from two-dimensional velocity and RMS data in the sagittal plane, as shown in figure 8 for the case of adenoid vegetation [8]. There are two re-circulating zones in the case of 70%, but there is only one in the case of 50% and the excessive value of RMS for the 70% adenoid vegetation case indicates the sharp increase in the flow resistance.…”

Section: Resultsmentioning

confidence: 99%

“…Creating accurate transparent flow passages is essential for analysing the inward flow through a complex flow passage by PIV. Kim and Son [7] improved the procedure for producing a better cavity model with high-resolution computerized tomogram (CT) scan data and surface rendering and extended this work to deal with airflow in an abnormal nasal cavity with adenoid vegetation and asymmetry [8]. Some conjectures are obtained as follows: adenoid vegetation exceeding 60% causes a rapid increase in the pressure drop between nares and nasopharynx.…”

Section: Introductionmentioning

confidence: 99%

An investigation on airflow in disordered nasal cavity and its corrected models by tomographic PIV

Kim¹,

Chung²

2004

Meas. Sci. Technol.

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Knowledge of airflow characteristics in nasal cavities is essential to understand the physiology and pathology aspects of nasal breathing. Several studies have utilized physical models of the healthy nasal cavity to investigate the relationship between nasal anatomy and airflow. Since the final goal of these works is their contribution to the diagnosis and treatment of nasal diseases, therefore, the next step in this topic must be followed by the studies for disordered nasal cavities. In this paper, airflows in normal and abnormal nasal cavities and surgically created models, which simulate surgical treatment, are investigated experimentally by PIV. High-resolution computerized tomogram data and careful manipulation of the model surface by the ear, nose and throat doctor provide more sophisticated nasal cavity models. The correlation based correction PIV algorithm with window offset is used for PIV flow analysis. Average and RMS distributions in sagittal and coronal sections are obtained for inspiratory and expiratory nasal airflows. Comparisons in nasal airflows for both normal and abnormal cases are also examined. Airflow characteristics that are related to the abnormalities in the nasal cavity are proposed. In the case of simulations of surgical operations, velocity and RMS distributions in coronal section change locally, this may cause some difficulties in physiologic functions of noses and may hurt mucosal surface.

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“…Fresconi et al (2003) presented experimental results on expiration flow in a symmetric bifurcation by using PIV and LIF techniques. And, Kim et al (2004) carried out an investigation on airflow in pathological nasal airway by PIV. However, the analysis on gas transfer and exchange mechanism related to flow pattern in the airways, especially at the respiratory zones from bronchioles to alveoli, has not been clarified in detail.…”

Section: Introductionmentioning

confidence: 99%

Experimental investigation of oscillatory air flow in a bronchial tube model with HFOV mode

Lee

Kawahashi

Hirahara

2006

J Vis

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Mechanical ventilations for artificial respiration have been developed to improve the medical treatment of the patients showing respiratory disorder. In various types of ventilation, High Frequency Oscillatory Ventilation (HFOV) is one of the most effective techniques of medical care for pulmonary disease patients, especially, infants or premature infants. HFOV is a ventilation technique with high breathing rate in comparison with the normal breathing rate. Some successful studies have focused on the effect of treatment using HFOV. However, the mechanism of gas exchange in bronchial tube under the medical treatment by HFOV has not been clarified. In this study, the oscillatory flow in a micro-channel model of bronchial with single bifurcation in HFOV mode has been investigated experimentally with micro Particle Image Velocimetry (micro PIV) technique. The phase averaged velocity profiles changing with the driving frequency of HFOV have been investigated.

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An investigation on airflow in pathological nasal airway by PIV

Cited by 7 publications

References 7 publications

Standardization of Malaysian Adult Female Nasal Cavity

Standardization of Malaysian Adult Female Nasal Cavity

An investigation on airflow in disordered nasal cavity and its corrected models by tomographic PIV

Experimental investigation of oscillatory air flow in a bronchial tube model with HFOV mode

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