气道壁运动对新生儿气管中颗粒沉积和输送的影响

IF 3.9 3区 环境科学与生态学 Q2 ENGINEERING, CHEMICAL
Chamindu C. Gunatilaka , Christopher McKenzie , Qiwei Xiao , Nara S. Higano , Jason C. Woods , Alister J. Bates
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引用次数: 0

摘要

利用计算流体动力学(CFD)模拟对气道中的肺部给药进行建模,可跟踪整个气道中的药物颗粒,为吸入药物的沉积位置提供有价值的信息。然而,大多数研究都是在静态气道模型中模拟微粒传输,没有考虑气道的生理运动;这种选择限制了准确性,因为气道运动会直接影响微粒传输和沉积,尤其是在气道异常(如气管畸形)的新生儿中。本研究的目的是确定气道运动对患有和未患有气道疾病的新生儿药物输送的影响。在这项研究中,我们招募了两名没有任何气道疾病的对照组受试者和三名患有气管畸形(动态气管狭窄)的受试者。每个受试者都在月龄后约 40 周时接受了磁共振成像(MRI)检查。对核磁共振成像数据进行回顾性重建,以获得与呼吸不同时间点(即呼气末和吸气末)相关的静态气道图像,以及代表所有时间点(非相关)综合数据的图像。根据每张磁共振图像制作虚拟气道表面(咽部至主支气管)。根据这些表面的表面注册创建移动气道表面,并将其作为一次吸气的 CFD 模拟边界,同时生成特定受试者的吸气流量波形。为了评估气道壁运动对粒子沉积的影响,还使用相同的气流边界条件,根据吸气末、呼气末的气道表面和未关闭的气道表面进行了静态气道壁模拟。在吸气过程中,对模拟结果中的颗粒传输(颗粒直径范围为 0.5-15 μm)进行了比较。与静壁模拟相比,气道表面运动对进入小气道的颗粒传输的影响平均为 65%(0.5-5 μm- 22%,5-15 μm- 86%),而静态呼气末与使用在不同呼吸阶段获得的几何图形进行的其他静壁模拟之间的比较平均相差 500% 以上(0.5-5 μm- 45%,5-15 μm- 741%)。在粒子沉积方面,与静壁模拟相比,气道表面运动平均受到 43% 的影响(0.5-5 μm- 86%,5-15 μm- 21%),而静态呼气末与其他静壁模拟相比,平均相差 47%(0.5-5 μm- 58%,5-15 μm- 41%)。气道疾病患者和非气道疾病患者的动态和静态沉积结果之间以及不同时间点的静态模拟结果之间存在差异。这项研究表明,在 CFD 模拟中使用气道壁运动来模拟气溶胶药物在气道中的输送非常重要。如果 CFD 模拟仅局限于没有生理运动的静态气道图像,粒子沉积图可能会产生明显不准确的结果,从而可能导致药物剂量高于或低于预期剂量。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Effect of airway wall motion on particle deposition and delivery in the neonatal trachea

Modeling pulmonary drug delivery in the airway using computational fluid dynamics (CFD) simulations tracks drug particles throughout the airway, providing valuable information on the deposition location of inhaled drugs. However, most studies simulate particle transport within static airway models that do not incorporate physiological airway motion; this choice limits accuracy since airway motion directly affects particle transport and deposition, notably in newborns with airway abnormalities such as tracheomalacia. The objective of this study is to determine the effect of airway motion on drug delivery in neonates with and without airway disease. For this study, two control subjects without any airway disease and three subjects with tracheomalacia (dynamic tracheal narrowing) were enrolled. Each subject was imaged at approximately 40-weeks post-menstrual age using magnetic resonance imaging (MRI). MRI data were retrospectively reconstructed to obtain static airway images gated to different time points of the breath (i.e., end expiration and end inspiration) and an image representing combined data from all timepoints (ungated). Virtual airway surfaces (pharynx to main bronchi) were made from each MR image. A moving airway surface was created from surface registration of these surfaces and used as the boundary for a CFD simulation of one inhalation, along with subject-specific inspiratory flow waveforms. To assess the effect of airway wall motion on particle deposition, static-walled simulations, based on the airway surfaces at end inspiration, end expiration, and the ungated airway surface, were also performed using the same flow boundary conditions. Particle transport (particles diameter range 0.5–15 μm) was compared between the simulations during the inhalation. Airway surface motion affected particle transport into the small airways by 65% on average (0.5–5 μm– 22%, 5-15 μm– 86%) compared to static-walled simulations, while comparison between static end expiration and other static-walled simulations using geometries acquired during different phases of breathing differed by more than 500% on average (0.5–5 μm– 45%, 5-15 μm– 741%). For particle deposition, airway surface motion affected by 43% on average (0.5–5 μm– 86%, 5-15 μm– 21%) compared to static-walled simulations and comparison between static end expiration and other static-walled simulations differed by 47% on average (0.5–5 μm– 58%, 5-15 μm– 41%). Differences between dynamic and static deposition results and between static simulations from different timepoints occurred in patients with and without airway disease. This study suggests the importance of using airway wall motion in CFD simulations to model aerosolized drug delivery in the airway. If a CFD simulation is limited to only a static airway image without physiological motion, particle deposition mapping may yield markedly inaccurate results, potentially resulting in higher or lower drug dosing than intended.

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来源期刊
Journal of Aerosol Science
Journal of Aerosol Science 环境科学-工程:化工
CiteScore
8.80
自引率
8.90%
发文量
127
审稿时长
35 days
期刊介绍: Founded in 1970, the Journal of Aerosol Science considers itself the prime vehicle for the publication of original work as well as reviews related to fundamental and applied aerosol research, as well as aerosol instrumentation. Its content is directed at scientists working in engineering disciplines, as well as physics, chemistry, and environmental sciences. The editors welcome submissions of papers describing recent experimental, numerical, and theoretical research related to the following topics: 1. Fundamental Aerosol Science. 2. Applied Aerosol Science. 3. Instrumentation & Measurement Methods.
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