早产儿高效给药鼻腔界面选择的体外分析。

IF 2 4区 医学 Q3 RESPIRATORY SYSTEM
Connor Howe, Mohammad A M Momin, Karl Bass, Ghali Aladwani, Serena Bonasera, Michael Hindle, Philip Worth Longest
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引用次数: 7

摘要

背景:最近开发了一种婴儿喷气干粉吸入器(DPI)平台,该平台与高度分散的喷雾干粉配方相结合,可以在低驱动空气量的情况下实现高效雾化。本研究的目的是研究对该平台鼻界面部分的修改,以通过早产鼻-喉(NT)模型改善气溶胶输送性能。方法:采用两种体外早产儿NT模型,评估多种鼻界面流动路径和尖头构型的气溶胶输送性能。研究了以l-亮氨酸和三叶亮氨酸为分散促进剂的两种促生长干粉配方。性能指标包括鼻腔界面的气溶胶沉积损失、NT模型中的沉积和用于估计肺输送效率的气管过滤器沉积。结果:性能最好的鼻接口用刚性弯曲鼻尖(~ 20°曲率)取代了原始逐渐扩展设计的直的柔性鼻尖。根据粉末配方的不同,尖头修饰使肺输送效率提高了5%-10%(绝对差异)。在流动通道中添加金属网以消散湍流射流,也将肺输送效率提高了约5%,同时与原始鼻界面相比,NT沉积损失减少了两倍以上。该平台在两种不同的早产儿NT模型中表现相似,任何性能指标之间没有统计学上的显著差异。结论:对婴儿喷气DPI鼻界面的修改改善了通过多个婴儿NT模型的气溶胶输送,提供高达10%的额外肺输送效率(绝对差异),铅设计向气管过滤器输送约57%的负荷剂量,而两种独特的早产儿气道几何形状的性能保持相似。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

<i>In Vitro</i> Analysis of Nasal Interface Options for High-Efficiency Aerosol Administration to Preterm Infants.

In Vitro Analysis of Nasal Interface Options for High-Efficiency Aerosol Administration to Preterm Infants.

Background: An infant air-jet dry powder inhaler (DPI) platform has recently been developed that in combination with highly dispersible spray-dried powder formulations can achieve high-efficiency aerosolization with low actuation air volumes. The objective of this study was to investigate modifications to the nasal interface section of this platform to improve the aerosol delivery performance through preterm nose-throat (NT) models. Methods: Aerosol delivery performance of multiple nasal interface flow pathways and prong configurations was assessed with two in vitro preterm infant NT models. Two excipient-enhanced growth (EEG) dry powder formulations were explored containing either l-leucine or trileucine as the dispersion enhancer. Performance metrics included aerosol depositional loss in the nasal interface, deposition in the NT models, and tracheal filter deposition, which was used to estimate lung delivery efficiency. Results: The best performing nasal interface replaced the straight flexible prong of the original gradual expansion design with a rigid curved prong (∼20° curvature). The prong modification increased the lung delivery efficiency by 5%-10% (absolute difference) depending on the powder formulation. Adding a metal mesh to the flow pathway, to dissipate the turbulent jet, also improved lung delivery efficiency by ∼5%, while reducing the NT depositional loss by a factor of over twofold compared with the original nasal interface. The platform was also found to perform similarly in two different preterm NT models, with no statistically significant difference between any of the performance metrics. Conclusions: Modifications to the nasal interface of an infant air-jet DPI improved the aerosol delivery through multiple infant NT models, providing up to an additional 10% lung delivery efficiency (absolute difference) with the lead design delivering ∼57% of the loaded dose to the tracheal filter, while performance in two unique preterm airway geometries remained similar.

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来源期刊
CiteScore
6.70
自引率
2.90%
发文量
34
审稿时长
>12 weeks
期刊介绍: Journal of Aerosol Medicine and Pulmonary Drug Delivery is the only peer-reviewed journal delivering innovative, authoritative coverage of the health effects of inhaled aerosols and delivery of drugs through the pulmonary system. The Journal is a forum for leading experts, addressing novel topics such as aerosolized chemotherapy, aerosolized vaccines, methods to determine toxicities, and delivery of aerosolized drugs in the intubated patient. Journal of Aerosol Medicine and Pulmonary Drug Delivery coverage includes: Pulmonary drug delivery Airway reactivity and asthma treatment Inhalation of particles and gases in the respiratory tract Toxic effects of inhaled agents Aerosols as tools for studying basic physiologic phenomena.
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