In silico investigation of inhalation condition impacts on hygroscopic growth and deposition of salbutamol sulphate in human airways

IF 1.9 4区 医学 Q3 PHYSIOLOGY
Sajad Eshaghi, Hassan Khaleghi, Reza Maddahian
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Abstract

The objective of this study is to explore the transport, size growth, and deposition of Salbutamol Sulphate (SS) using Computational Fluid Dynamics (CFD). A CT-based realistic model of human airways from the oral cavity to the 5th generation of the lung was utilized as the computational domain. Four Test Cases (TC) with varying temperature and relative humidity (RH) under two inspiratory waveforms were considered to completely evaluate the impact of inhalation conditions on particle growth. Salbutamol Sulphate (SS) is a β2-adrenergic agonist and has been extensively used for asthma treatment. A monodispersed distribution of SS particles with an initial diameter of 167 nm was considered at the mouth inlet based on pharmaceutical data. Results indicated that inhalation of saturated/supersaturated air (RH>100%) leads to significant hygroscopic growth of SS particles with a factor of 10. In addition, the deposition efficiency of SS particles under the Quick and Deep (QD) inhalation profile was enhanced as the flow temperature and humidity increased. However, the implementation of Slow and Deep (SD) inspiratory waveform revealed that the same particle size growth is achieved in the respiratory system with lower deposition efficiency in the mouth-throat (less than 3%) and tracheobronchial airway (less than 2.18%). For the escaped particles form the right lung, in the SD waveform under TC 3, the maximum particle size distribution was for 600 nm particles with 25% probability. In the left lung, 30% of the particles were increased up to 950 nm in size. For the QD waveform in TC 3 and TC4, the most frequent particles were 800 nm with 36% probability. This holds practical significance in the context of deep lung delivery for asthmatic patients with enhanced deposition efficiency and large particle size. The findings of the present study can contribute to the development of targeted drug delivery strategies for the treatment of pulmonary diseases using hygroscopic dry powder formulations.

吸入条件对硫酸沙丁胺醇吸湿性生长和沉积在人体气道中的影响的硅学研究。
本研究的目的是利用计算流体动力学(CFD)探索硫酸沙丁胺醇(SS)的传输、尺寸增长和沉积。计算域采用了基于 CT 的从口腔到第五代肺的人体呼吸道真实模型。在两种吸气波形下,考虑了四种不同温度和相对湿度(RH)的测试案例(TC),以全面评估吸入条件对颗粒生长的影响。硫酸沙丁胺醇(SS)是一种β2-肾上腺素能激动剂,已被广泛用于治疗哮喘。根据制药数据,考虑了初始直径为 167nm 的 SS 粒子在口腔入口处的单分散分布。结果表明,吸入饱和/过饱和空气(相对湿度>100%)会导致 SS 粒子显著吸湿增长,增长系数为 10。此外,随着气流温度和湿度的增加,在快速深度吸入(QD)条件下 SS 粒子的沉积效率也有所提高。然而,采用慢而深(SD)吸气波形后发现,呼吸系统中的颗粒尺寸增长相同,但口-喉(小于 3%)和气管-支气管气道(小于 2.18%)的沉积效率较低。对于形成于右肺的逸散颗粒,在 TC 3 下的 SD 波形中,最大粒径分布为 600nm 的颗粒,概率为 25%。在左肺中,有 30% 的颗粒增大到 950 纳米。在 TC 3 和 TC4 的 QD 波形中,最常见的颗粒为 800 纳米,概率为 36%。这对于提高沉积效率和粒径大的哮喘患者的肺深部给药具有实际意义。本研究的发现有助于开发使用吸湿干粉制剂治疗肺部疾病的靶向给药策略。
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
CiteScore
4.80
自引率
8.70%
发文量
104
审稿时长
54 days
期刊介绍: Respiratory Physiology & Neurobiology (RESPNB) publishes original articles and invited reviews concerning physiology and pathophysiology of respiration in its broadest sense. Although a special focus is on topics in neurobiology, high quality papers in respiratory molecular and cellular biology are also welcome, as are high-quality papers in traditional areas, such as: -Mechanics of breathing- Gas exchange and acid-base balance- Respiration at rest and exercise- Respiration in unusual conditions, like high or low pressure or changes of temperature, low ambient oxygen- Embryonic and adult respiration- Comparative respiratory physiology. Papers on clinical aspects, original methods, as well as theoretical papers are also considered as long as they foster the understanding of respiratory physiology and pathophysiology.
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