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不同吸入条件下鼻腔内喷雾粒子的沉积。

Nasal sprayed particle deposition in a human nasal cavity under different inhalation conditions.

机构信息

Barcelona Supercomputing Center (BSC-CNS), Department of Computer Applications in Science and Engineering, Barcelona, Spain.

School of Engineering (Mechanical & Automotive), RMIT University, Bundoora, Victoria, Australia.

出版信息

PLoS One. 2019 Sep 6;14(9):e0221330. doi: 10.1371/journal.pone.0221330. eCollection 2019.

DOI:10.1371/journal.pone.0221330
PMID:31490971
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6730903/
Abstract

Deposition of polydisperse particles representing nasal spray application in a human nasal cavity was performed under transient breathing profiles of sniffing, constant flow, and breath hold. The LES turbulence model was used to describe the fluid phase. Particles were introduced into the flow field with initial spray conditions, including spray cone angle, insertion angle, and initial velocity. Since nasal spray atomizer design determines the particle conditions, fifteen particle size distributions were used, each defined by a log-normal distribution with a different volume mean diameter (Dv50). Particle deposition in the anterior region was approximately 80% when Dv50 > 50μm, and this decreased to 45% as Dv50 decreased to 10μ m for constant and sniff breathing conditions. The decrease in anterior deposition was countered with increased deposition in the middle and posterior regions. The significance of increased deposition in the middle region for drug delivery shows there is potential for nasal delivered drugs to reach the highly vascularised mucosal walls in the main nasal passages. For multiple targeted deposition sites, an optimisation equation was introduced where deposition results of any two targeted sites could be combined and a weighting between 0 to 1 was applied to each targeted site, representing the relative importance of each deposition site.

摘要

在嗅吸、恒流和屏气等瞬态呼吸模式下,对代表鼻腔喷雾应用的多分散颗粒在人体鼻腔中的沉积进行了研究。使用大涡模拟(LES)湍流模型来描述流场中的流体相。通过初始喷雾条件将颗粒引入流场,包括喷雾锥角、插入角和初始速度。由于鼻腔喷雾雾化器的设计决定了颗粒的条件,因此使用了十五种粒径分布,每种粒径分布都由不同体积平均直径(Dv50)的对数正态分布定义。当 Dv50>50μm 时,前区的颗粒沉积约为 80%,而当 Dv50 降低至 10μm 时,对于恒流和嗅吸呼吸条件,前区沉积减少至 45%。前区沉积的减少被中区和后区沉积的增加所抵消。在药物输送中,中区沉积增加的重要性表明,鼻腔给药有潜力使药物到达主要鼻道中血管丰富的黏膜壁。对于多个靶向沉积部位,引入了优化方程,其中可以组合任何两个靶向部位的沉积结果,并对每个靶向部位应用 0 到 1 之间的权重,代表每个沉积部位的相对重要性。

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