Numerical Simulation of Nasal Resistance Using Three-dimensional Models of the Nasal Cavity and Paranasal Sinus.

Q3 Medicine

Tokai Journal of Experimental and Clinical Medicine Pub Date : 2023-07-20

Shoji Kaneda, Fumiyuki Goto, Kenji Okami, Reo Mitsutani, Yoko Takakura

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引用次数: 0

Abstract

Objective: Previously, we used a nasal cavity model to analyze the intranasal airflow dynamics and numerically calculate the nasal resistance value. In this study, We attempted clarify the parameters influencing nasal resistance by newly developed computer model.

Methods: The computer simulation model was developed from the structures of nasal airway tract adopted from 1.0-mm slice computed tomography (CT) obtained from the 2 of the healthy volunteers. (model 1: the one at 35-year-old man, model 2: 25-year-old man.) We have calculated the nasal resistance by computer simulation calculations of both model 1 and model 2. These calculated values were compared with the values obtained from the established method of rhinomanometry. For the simulation, Fluent 17.2® (ANSYS, American) was employed for f luid a nalysis u sing the continuity equation for 3D incompressible flow and the Navies-Stokes equation for the basic equations. Both models were laminar models. The SIMPLE calculation method using the finite volume method was employed here, and the quadratic precision upwind difference method was used to discretize the convection terms.

Results: The measured (simulation) values in Model 1 were 0.69 (0.48), 1.10 (0.41), and 0.42 (0.22) Pa/cm³/s on the right, left, and both sides, whereas those in Model 2 were 0.72 (0.21), 0.32 (0.09), and 0.22 (0.06) Pa/cm³/s, respectively.

Conclusion: Our results suggest that nasal resistance is possibly affected by the length of the inferior turbinate and the cross-sectional area of the choana and nasopharynx. Further experiments using additional nasal cavity and paranasal sinus models are warranted.

本刊更多论文

基于鼻腔和副鼻窦三维模型的鼻阻力数值模拟。

目的:利用鼻腔模型分析鼻内气流动力学，并对鼻腔阻力值进行数值计算。在本研究中，我们试图通过新建立的计算机模型澄清影响鼻阻力的参数。方法:采用2例健康志愿者的1.0 mm CT所示的鼻道结构，建立计算机模拟模型。(模型1:35岁男性，模型2:25岁男性。)我们通过模型1和模型2的计算机模拟计算计算了鼻阻力。将这些计算值与所建立的鼻测法所得值进行比较。仿真采用Fluent 17.2®(ANSYS, American)软件进行流体分析，采用三维不可压缩流动的连续性方程和naves - stokes方程作为基本方程。两个模型都是层流模型。本文采用有限体积法的SIMPLE计算方法，采用二次精度迎风差分法对对流项进行离散化。结果:模型1右、左、两侧的测量(模拟)值分别为0.69(0.48)、1.10(0.41)、0.42 (0.22)Pa/cm3/s，模型2的测量(模拟)值分别为0.72(0.21)、0.32(0.09)、0.22 (0.06)Pa/cm3/s。结论:鼻阻力可能与下鼻甲的长度、鼻咽喉的横截面积有关。进一步的实验使用额外的鼻腔和副鼻窦模型是必要的。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Tokai Journal of Experimental and Clinical Medicine Medicine-Medicine (all)

CiteScore

1.10

自引率

0.00%

发文量

期刊介绍： The Tokai Journal of Experimental and Clinical Medicine, also referred to as Tokai Journal, is an official quarterly publication of the Tokai Medical Association. Tokai Journal publishes original articles that deal with issues of clinical, experimental, socioeconomic, cultural and/or historical importance to medical science and related fields. Manuscripts may be submitted as full-length Original Articles or Brief Communications. Tokai Journal also publishes reviews and symposium proceedings. Articles accepted for publication in Tokai Journal cannot be reproduced elsewhere without written permission from the Tokai Medical Association. In addition, Tokai Journal will not be held responsible for the opinions of the authors expressed in the published articles.