Fate of inhaled electronic nicotine delivery systems (ENDS) puff constituents in the human respiratory tract

IF 3.9 3区环境科学与生态学 Q2 ENGINEERING, CHEMICAL

Journal of Aerosol Science Pub Date : 2024-03-15 DOI:10.1016/j.jaerosci.2024.106363

Bahman Asgharian , Owen Price , Scott Wasdo , Jon Fallica , Gladys Erives , Cissy Li , Raymond Yeager , Susan Chemerynski , Jeffry Schroeter

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引用次数: 0

Abstract

Published research on the fate of a puff from electronic nicotine delivery systems (ENDS) in the lungs is limited; more information would better inform human exposure and potential adverse outcomes from ENDS use. An ENDS puff is a mixture of multiple constituents in droplet and vapor form, including propylene glycol, vegetable glycerin, nicotine, water, and flavor chemicals. Understanding the complexity of the puff aids in developing mechanistic models that can account for the physical, physiological, and thermodynamic processes of the puff while traveling and depositing in lung airways. Previously, we developed a mathematical model to predict deposition and uptake of ENDS constituents in the oral cavity. In this study, we formulated the model for lung airways to extend to the entire respiratory tract and made adjustments to mechanisms such as phase change and nicotine protonation to study effects on droplet pH and nicotine evaporation. We conducted model simulations for two representative inhalation profiles relevant to ENDS users: mouth-to-lung and direct-to-lung inhalation. Simulation results showed that vapor uptake during ENDS use was the primary mechanism of the overall tissue dose for higher vapor pressure constituents. Nicotine protonation was unaffected by the ratio of propylene glycol to vegetable glycerin but changes to vanillin molarity impacted droplet pH and free nicotine fraction. The largest uptake and deposition occurred in the deep lung, where constituents more efficiently reach the arterial blood. Predicted total respiratory tract retention of higher vapor pressure constituents such as nicotine, propylene glycol, and benzaldehyde were 94–95%, whereas retention of lower volatility constituents such as vegetable glycerin and vanillin was 82–83%. Results also indicated regional uptake differences for the constituents evaluated in the two inhalation scenarios. Predictions from the ENDS deposition model can be linked to physiologically based pharmacokinetic (PBPK) models to determine the fate of puff constituents such as nicotine in other tissues and organs of the body and provides further basis for evaluating flavor chemicals and puff constituents based on user-specific exposure characteristics as well as internal dose to inform risk assessment of ENDS.

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吸入式电子尼古丁输送系统（ENDS）粉扑成分在人体呼吸道中的去向

已发表的关于电子尼古丁释放系统（ENDS）吸入的烟雾在肺部的去向的研究很有限；更多的信息将更好地为人类接触和使用ENDS的潜在不良后果提供信息。电子尼古丁给药系统（ENDS）的粉扑是多种成分的混合物，以液滴和蒸汽的形式存在，包括丙二醇、植物甘油、尼古丁、水和调味化学品。了解粉扑的复杂性有助于开发机理模型，以解释粉扑在肺部气道中移动和沉积时的物理、生理和热力学过程。此前，我们建立了一个数学模型来预测 ENDS 成分在口腔中的沉积和吸收。在这项研究中，我们将肺部气道的模型扩展到整个呼吸道，并对相变和尼古丁质子化等机制进行了调整，以研究对液滴pH值和尼古丁蒸发的影响。我们对与ENDS使用者相关的两种代表性吸入情况进行了模型模拟：口对肺吸入和直接对肺吸入。模拟结果表明，对于蒸汽压较高的成分而言，使用 ENDS 期间的蒸汽吸收是造成总体组织剂量的主要机制。尼古丁质子化不受丙二醇和植物甘油比例的影响，但香兰素摩尔浓度的变化会影响液滴的pH值和游离尼古丁含量。最大的吸收和沉积发生在肺深部，那里的成分能更有效地进入动脉血。据预测，尼古丁、丙二醇和苯甲醛等蒸汽压力较高的成分在呼吸道的总滞留率为 94-95%，而植物甘油和香兰素等挥发性较低的成分在呼吸道的滞留率为 82-83%。结果还表明，在两种吸入情况下，被评估成分的吸收存在区域差异。ENDS沉积模型的预测结果可与基于生理的药代动力学（PBPK）模型联系起来，以确定尼古丁等粉扑成分在身体其他组织和器官中的去向，并为根据使用者的特定暴露特征以及内部剂量评估香料化学品和粉扑成分提供进一步的依据，从而为ENDS的风险评估提供信息。

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

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.