Toxicity of Humectants Propylene Glycol and Vegetable Glycerin in Electronic Nicotine Delivery Systems.

IF 2.9 3区医学 Q2 TOXICOLOGY

Toxicology letters Pub Date : 2025-10-01 DOI:10.1016/j.toxlet.2025.111739

Yehao Sun, Karen Lin, Felix Effah, Francisco Cartujano Barrera, Dongmei Li, Scott McIntosh, Matthew D McGraw, Irfan Rahman

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引用次数: 0

Abstract

Background: E-cigarettes and other electronic nicotine delivery systems (ENDs) remain a significant public health risk. Although deployed as tobacco smoking cessation tools, e-cigarettes have gained greater popularity among non-smokers, specifically adolescents and young adults. Previous research has focused primarily on toxicities associated with nicotine, flavorings, and other chemicals generated from e-cigarette liquid aerosolization; however, little attention has been given to the two primary and most abundant chemicals found in most e-cigarette liquids - propylene glycol (PG) and vegetable glycerin (VG).

Purpose: The purpose of this review is to assess the toxicity associated with PG/VG in e-cigarettes to inform future ENDS regulations.

Methods: Database searches were performed using PubMed for relevant literature published from 1/1/2014 to 1/1/2025. Cited articles about the prevalence, toxicities, and public perceptions of PG/VG.

Results: Toxicity associated with PG/VG inhalation is primarily due to thermal degradation byproducts (TDBs) generated by PG/VG-containing e-liquids. More specifically, high-power ENDS devices with sub-ohm power capabilities generate aerosols with larger mass and higher concentrations of TDBs. The most common TDBs identified in e-cigarette aerosols include formaldehyde, acetaldehyde, acrolein, acetone, acetoin/diacetyl, as well as benzene. These TDBs, along with other chemical adducts, contribute significantly to the e-cigarette aerosols' potential to cause oxidative stress, airway inflammation, and increase risks for cancer. Mechanistically, the toxicity associated with e-cigarette aerosols is mediated through the activation of the NF-κB and MAPK pathways, as well as the dysfunction of ion channels responsible for mucus hydration. These effects of e-cigarette aerosol exposures, whether induced by TDBs or other chemicals, can be affected by factors involved in the aerosolization process, including the ratio of PG/VG, the device power, and the resistance of the coil.

Conclusions: E-cigarettes are often considered a harm-reduction alternative to combustible cigarettes due to propylene glycol and vegetable glycerin's FDA designation as "Generally Recognized as Safe" (GRAS) for consumption. However, when heated and inhaled, mixtures of PG/VG in e-cigarette liquids have their toxicities independent of the other constituents of e-liquids. Future regulations that focus on the PG/VG ratios, set limits on thermal degradation byproducts, and establish exposure thresholds for e-cigarette aerosols will help reduce toxic exposures associated with PG/VG inhalation. As such, further research is needed on PG/VG alone to understand its long-term health effects better and to inform evidence-based public health policies.

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湿润剂丙二醇和植物甘油在电子尼古丁传送系统中的毒性。

背景：电子烟和其他电子尼古丁传递系统（ENDs）仍然是一个重大的公共卫生风险。尽管电子烟被用作戒烟工具，但它在不吸烟者，特别是青少年和年轻人中越来越受欢迎。以前的研究主要集中在与尼古丁、香料和电子烟液体雾化产生的其他化学物质相关的毒性；然而，很少有人关注大多数电子烟液体中发现的两种主要和最丰富的化学物质——丙二醇（PG）和植物甘油（VG）。目的：本综述的目的是评估电子烟中PG/VG相关的毒性，为未来的ENDS法规提供信息。方法：使用PubMed检索2014年1月1日至2025年1月1日发表的相关文献。引用了关于PG/VG的流行、毒性和公众认知的文章。结果：与吸入PG/VG相关的毒性主要是由于含有PG/VG的电子液体产生的热降解副产物（tdb）。更具体地说，具有亚欧姆功率能力的大功率ENDS设备产生的气溶胶质量更大，tdb浓度更高。电子烟气雾剂中最常见的tdb包括甲醛、乙醛、丙烯醛、丙酮、乙酰/二乙酰以及苯。这些tdb与其他化学加合物一起，极大地增加了电子烟气溶胶引起氧化应激、气道炎症和增加癌症风险的可能性。从机制上讲，与电子烟气溶胶相关的毒性是通过NF-κB和MAPK途径的激活以及负责粘液水化的离子通道的功能障碍介导的。电子烟气溶胶暴露的这些影响，无论是由tdb还是其他化学物质引起的，都可能受到雾化过程中涉及的因素的影响，包括PG/VG的比例、设备功率和线圈的电阻。结论：电子烟通常被认为是可燃香烟的一种减少危害的替代品，因为丙二醇和植物甘油被FDA指定为“公认安全”（GRAS）。然而，当加热和吸入时，电子烟液体中PG/VG的混合物具有独立于电子烟液体其他成分的毒性。未来的法规将重点关注PG/VG比率，设定热降解副产物的限制，并建立电子烟气溶胶的暴露阈值，这将有助于减少与PG/VG吸入相关的毒性暴露。因此，需要对PG/VG单独进行进一步研究，以更好地了解其长期健康影响，并为基于证据的公共卫生政策提供信息。

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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