Immunological and toxicological risk assessment of e-cigarettes

Product engineering of e-cigarette devices

A variety of e-cig device models have emerged over the years; however, the basic design remains the same, consisting of an atomiser, a reservoir containing e-liquid and a rechargeable lithium battery. An overview of the different types of e-cig devices currently available is provided in table 1 [12] and figure 1.

Numerous brands and product designs are available, ranging from simple single-run disposables to highly sophisticated tank-style refillable models. They are engineered to provide automated or manual aerosol formation on inhalation. While the advanced designs and varieties of the vaping devices on the market might be quite an attraction for potential buyers, it makes research in this area an extremely complicated task. Variable voltage, current and temperature from each device may affect the composition of aerosols produced upon inhaling the same e-liquid. Furthermore, the aerosol density of the e-vapours and vaping behaviour and inhalation pattern of the user all might vary and have different toxicological outcomes in humans [13]. Considering this, Trtchounian et al. [14] compared the smoking properties of conventional cigarettes and e-cigs, such as the vacuum required to produce smoke or aerosol and smoke/aerosol density. It was observed that e-cigs require more suction to release aerosols compared to conventional cigarettes. What this means is that the density of aerosol produced by an e-cig declines during smoking because greater pressure needs to be applied by the user to sustain density, thereby sending nonuniform doses of aerosol to the lung tissue. The health implications of this property has not been explored completely, but it is speculated that stronger puffs may cause the aerosols to reach deeper tissues of the lungs, which might have adverse health outcomes in the users.

In another study, Williams and Talbot [15] reported the differences in smoking performance across various brands of e-cigs. In fact, performance (airflow rate required to produce aerosol, pressure drop across e-cigs, aerosol density, etc.) varied between devices of the same model within a brand, which is suggestive of poor quality control during the manufacturing of these devices. Such reports make it evident that the study of the toxicological effects of e-cigs is not as straightforward as that concerning regular cigarettes, and careful design of experiments and interpretation is necessary to get logical answers.

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FIGURE 1

E-cigarette models. a) First generation; b) second generation; c) third generation; d) fourth generation.

Toxicological profile of e-liquids and e-cig aerosols

A major concern associated with the use of e-cigs is the lack of knowledge about their constituents. Although the amounts of harmful chemicals found in e-cig aerosols are far lower than conventional cigarettes (table 2), individual exposure depends on many factors such as device voltage, temperature, e-liquid flavour, nicotine content and smoking behaviour of the vaper. Due to the variable nature of all these factors, it is hard to deduce much from the currently available toxicological data related to e-liquids and e-cig aerosols.

While demonstrating the health impacts of acute exposure to e-liquid aerosols, Flouris et al. [16] found that the serum cotinine levels generated by both active and passive smokers was comparable to those generated upon exposure to conventional cigarette smoke. Cotinine is a metabolite of tobacco and a biomarker for tobacco exposure in humans. Comparable levels of cotinine among both the study groups thus means that e-cigs are no different to regular cigarettes as far as the health risks are concerned. Elaborating on the toxic effects of nicotine present in e-cig aerosols in particular, Farsalinos et al. [17] reported that plasma nicotine levels of healthy e-cig users increased by 35–72% due to the use of new-generation e-cig devices, compared to first-generation devices. In addition, a literature review by Schroeder and Hoffman [18] concluded that the nicotine exposure upon use of e-cigs depends on product experience and the usage behaviour of the vaper. They found that experienced e-cig users could achieve nicotine concentrations comparable to those achieved by conventional cigarette smokers. In fact, while highlighting the addictive properties of e-cigs, Foulds et al. [19] showed that long-term e-cig users have high e-cig dependence scores.

Another group of researchers tested 13 kinds of commercially available e-liquids and found the presence of acetaldehyde and formaldehyde in eight of the tested samples [20]. The International Agency for Research on Cancer has classified formaldehyde and acetaldehyde as human carcinogens in groups 1 and 2B, respectively, which should be a reason for concern [21]. Varlet et al. [22] analysed 42 models of refill liquids for e-cigs from 14 different brands to assess their toxicity. High amounts of α- and β-pinene, γ-terpinene and benzene 1-methyl-4-(1-methylethyl) (para-cymene), used to enhance their flavours, were detected in several products. In addition, 2,3-butanedione, a diketone associated with respiratory diseases, was detected in three samples, with concentrations in one sample exceeding the recommended National Institute of Occupational Safety and Health safety limits. Moreover, none of the samples analysed in this study were found to be completely free of potentially toxic compounds. However, these studies only tested the chemical constituents of e-liquids and did not consider their combustion products, which could be even more harmful considering the reactive nature of such carbonyl compounds. These shortcomings were overcome in a recent study conducted by Jensen et al. [23], which used nuclear magnetic resonance to identify the products in e-cig aerosols. This study identified glycidol (carcinogen), vinyl alcohol isomers and dihydroxyacetone (associated with inhalation hazards) in e-cig aerosols and concluded that further investigation is required to define the association between illness and the composition of e-cig aerosols. Furthermore, this group also concluded that variations caused by thermal oxidation, acid/metal-based catalysis of propylene glycol and glycerol and heat transfer efficiencies of the vaping devices should be considered in the design of future studies to eliminate experimental inconsistencies. Overall future toxicological studies need to assess specifically the level of combustible by-products of the carbonyl compounds present in e-liquids as they could be responsible for the formation of reactive oxygen species in the exposed tissues and cause oxidative damage in lungs.

One of the unique selling point of e-cigs is the wide variety of flavours. According to a 2014 report, e-liquids exist in 7764 unique flavours sold under 466 brands [13]; however, these flavouring agents could also lead to toxicity. A study based on determining the cytotoxicity of e-liquids in human embryonic stem cells and in mouse neural stem cells demonstrated its direct correlation with the concentration of flavouring additives [24]. Diacetyl, an artificial butter flavouring found in some flavoured e-liquids, has been associated with a rare and severe lung condition, bronchiolitis obliterans, commonly known as “popcorn lung” [8]. An animal study conducted by Morgan et al. [25] found compromised respiratory epithelium in mice exposed to heated diacetyl vapours. In 2012, Bahl et al. [24] compared the cytotoxicity of various flavours and identified Ceylon cinnamon as the most toxic of the 36 flavourings tested on human embryonic stem cells. Another study demonstrated that flavouring additives containing diacetyl and 2,3-pentanedione cause a reduction in sodium transport in normal human bronchial/tracheal epithelial cells without affecting sodium–potassium pump activity or chloride ion transport [26]. Similarly, 2,5-dimethypyrazine, found in vanillin and chocolate flavourings, was shown to cause alterations in the ion conductance in primary mouse tracheal epithelial cells. Mechanistic evaluation confirmed that the increase in ion conductance evoked by 2,5-dimethylpyrazine was caused due to a protein kinase A-dependent activation of the cystic fibrosis transmembrane conductance regulator ion channel [27].

In a study conducted by Williams et al. [28], the aerosols of e-cigs were demonstrated to have high concentrations of silver, iron, nickel, aluminium and silicate and nanoparticles (<100 nm) of tin, chromium and nickel. Moreover, it was shown that titanium dioxide nanoparticles released in e-cig aerosols impair DNA repair by causing single-strand breaks and oxidative lesions to DNA in A549 cells [29]. These heavy metals could be released by the heating element and could pose serious health implications in users. Advocates of e-cigs believe that aerosols from e-cigs contain only “water vapour”; however, evidence contradicts this. Zhang et al. [30] employed a human deposition model to study the likely deposition of e-liquid aerosol on vaping both propylene glycol- and vegetable glycerin-based e-liquids. In the single-puff experiments performed during this study, both solvents produced comparable sizes of aerosol particles. Interestingly, the study model estimated that ∼20–27% of particles from aerosols could be deposited in the circulatory system and other organs, which is comparable to the 25–35% deposition rate for conventional cigarettes. Along these lines, a recent study conducted by Mikheev et al. [31] measured the particle size distribution of e-cig aerosols using advanced real-time instrumentation. They found that the aerosol size distribution generated by e-cigs is considerably different from that produced by tobacco smoke and exhibits a bimodal distribution of particles ranging from the nanoparticle (in high numbers) to submicron size range. Metals such as lead, chromium and nickel (present at ∼2–100 times higher than in tobacco cigarettes) were found to be responsible for the nanoparticle formation. The study concluded that these e-cig aerosols could have toxicological implications, and, owing to the small size of particles, may affect sensitive sites including the lungs, bone marrow, spleen, heart and even the central nervous system.

Overall, the toxicological studies conducted thus far show some concerning results and point towards probable ill-effects of e-cigs on the general population. However, various shortcomings in study design render the outcomes inconclusive. Many of the toxicological analyses are performed on e-liquids, which are not the inhaled product of vaping and thus they do not provide the complete picture. The chemicals released on vaping depends on multiple variable factors such as the type of device used, the flavour of the e-liquid and its composition, and the smoking behaviour of the vaper. It is impossible to simulate all these conditions for toxicity testing. Furthermore, very few in vivo studies have been conducted to test the long-term effect of e-cig aerosols in mammals. In future, well-designed research models and experimental plans will be required to deduce the toxicological impact of e-cigs on short-term and long-term users.

Immunological effects of e-cig use

The adverse health effects of conventional cigarette smoking are well known; however, the immunological responses to e-liquid vaping remain elusive. Few reports have been published, but the results seem to be contradictory. A study comparing the effects of e-cigs and traditional cigarettes on pulmonary function and nitric oxide release in exhaled air of smokers versus nonsmokers found that short-term use of e-cigs did not lead to any adverse health effects in nonsmokers [32]. In addition, Misra et al. [33] found no evidence of genotoxicity, cytotoxicity or adverse inflammatory responses caused by e-liquids in human alveolar epithelial cells (A549). Moreover, as per this report, varying the nicotine content of the e-liquids caused no significant effect on interleukin (IL)-8 production, cytotoxicity or mutagenicity of A549 cells. These findings led the authors to conclude that the presence of nicotine in e-liquids does not affect mutagenicity in in vitro study models. However, the downside of these findings was that this was an in vitro study employing direct treatment of human alveolar epithelial cells with e-liquids or pad-collected aerosols, and thus the model did not completely mimic in vivo exposure conditions. Use of a puffing system to expose the cells or animals to e-vapours would be a more effective means of studying the real-life scenario. In contrast, exposure of human umbilical cord vein endothelial cells to e-cig aerosols from 11 different e-liquid flavours revealed a concentration-dependent and temporal increase in cell death in response to exposure to five of the flavours tested. Moreover, the highly toxic e-liquids were found to contain flavouring agents from plant extracts [34]. Cervellati et al. [35] reported that exposure to e-cig vapours (balsamic flavour with and without nicotine) induces the production of pro-inflammatory cytokines and chemokines (such as IL-1 receptor-α, IL-8, IL-10, granulocyte colony-stimulating factor, interferon-γ, RANTES, tumour necrosis factor (TNF)-α and vascular endothelial growth factor) by human alveolar epithelial cells (A549) and keratinocytes (HaCaT cells). Furthermore, in a recent study, e-cig vapour extracts were reported to induce the expression of CD11b and CD66b in neutrophils isolated from peripheral blood of healthy nonsmokers, which play a critical role in their adhesion and migration to the site of inflammation. In addition, e-cig vapour extract induces neutrophil elastase and matrix metalloproteinase-9 release by neutrophils, which may cause tissue destruction leading to the development of emphysematous lung tissue in patients with COPD. This study also reported a subsequent increase in p38 mitogen-activated protein kinase activation (figure 2). The observed effects were dose-dependent and in accordance with the findings from smoke-exposed models [36].

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FIGURE 2

Inflammatory responses elicited by e-liquid vaping. E-liquid vaping results in recruitment of immune cells to the site of exposure, i.e. nasal and throat epithelial cells. Tissue macrophages are among the first lines of defence activated by exposure to e-cigarette vapours. Activated macrophages participate in phagocytosis and release pro-inflammatory cytokines such as interleukin (IL)-6, IL-10, IL-1β, etc. a) In turn, these cytokines lead to B-cell and T-cell differentiation and participate in downstream signalling mechanisms. b) IL-6 mediated activation of the JAK–STAT (Janus tyrosine kinase/signal transducer and activator of transcription) pathway is one such downstream pathway that is known to be activated by the action of e-vapours. IL-6 production by exposure to e-vapours causes STAT3 phosphorylation which further elicits production of other cytokines and chemokines, and, most importantly promotes neutrophil adhesion and migration into the lungs. c) Neutrophil migration into the tissue results in release of neutrophil elastase and matrix metallopeptidase-9, which in turn causes tissue destruction in emphysematous lungs and chronic obstructive pulmonary disease. d) Furthermore, neutrophils release various cytokines and chemokines such as tumour necrosis factor (TNF)-α, IL-10 and IL-1β, which activate p38 and nuclear factor (NF)-кB mediated signalling pathways that might result in inflammation or apoptosis. e) Exposure to e-vapours further results in release of β-defensins by epithelial cells. β-defensins have antimicrobial actions and participate in eliciting an inflammatory response; however, production of the SPLUNC1 (short palate, lung and nasal epithelium clone 1) protein known to induce innate immunity in airway epithelial cells is lowered on exposure to e-vapours. ICAM: intercellular adhesion molecule.

In 2014, Wu et al. [37] conducted a study to demonstrate the role of e-liquids in inducing inflammatory responses and regulating innate defence in primary airway epithelial cells. It was observed that nicotine-free e-liquid induced IL-6 production and promoted human rhinovirus (HRV) infection in human primary airway epithelial cells from nonsmokers. It was found that the observed effects were amplified by the presence of nicotine. In contrast, the expression of the host-defence molecule SPLUNC1 (short palate, lung and nasal epithelium clone 1) was abrogated in human airway epithelial cells following treatment with nicotine-free e-liquid. Additionally, it was observed that SPLUNC-1 deficiency significantly increased HRV burden in the lungs of C57Bl/6 mice (figure 2). This study indicates that exposure to e-liquids can lead to an immune-compromised state and an increase in susceptibility to microbial infection. Sussan et al. [38] reported that 2 weeks' exposure of C57BL/6 mice to e-cig vapours causes impairment of pulmonary viral and bacterial clearance. Furthermore, researchers observed that exposure to e-cig vapours results in increased virulence of methicillin-resistant Staphylococcus aureus and concluded that e-liquids can boost drug resistance in bacteria by promoting biofilm formation and causing alterations in surface charge [39]. Such studies, though preliminary, present a newer and graver problem of increased bacterial infection and drug resistance due to increased use of e-cigs.

Transcriptome sequencing of human bronchial epithelial cells following exposure to e-cig vapours and traditional cigarette smoke demonstrated the induction of distinct gene expression profiles. The results demonstrate that compared to tobacco smoke, the use of e-vapours elicits subdued cellular toxic responses. However, e-vapours were reported to cause a significant enrichment in the expression of genes associated with phospholipid and fatty acyl triacylglycerol metabolism, which remained unaffected in traditional smoke-treated samples. Since e-liquids are enriched in glycerin and phosphatidate, the upregulation of the glycerophospholipid biosynthetic pathway is not surprising. Nevertheless, it would be interesting to further explore the consequences of such upregulation as it may have effects on the formation of membrane microdomains (lipid rafts) leading to altered signalling. It was observed in the same study that exposure of human bronchial epithelial cells to e-vapours resulted in the significant upregulation of DEFB1 and DEFB4, genes associated with the β-defensins pathway (figure 2). β-defensins are antimicrobial peptides expressed during inflammation, and interestingly, the expression of these genes was further induced in response to challenge with nicotine-containing e-vapours [40]. Although the readouts from this study did not reveal alarmingly harmful effects from human use of e-cigs, it certainly raised concerns over the health issues that may arise from the long-term use of such devices. Furthermore, a group of researchers from Boston University (Boston, MA, USA) suggested that exposure to e-vapours might increase the risk of lung cancer. Their findings using immortalised human bronchial epithelial cells (SV40) exposed to e-cig vapours showed a similar pattern of gene expression as tobacco smoke-exposed cultures [41]. A recent study was conducted to determine the effect of whole-body exposure of male Sprague Dawley rats to e-cig aerosols for 11 cycles·day^-1 of 17-s puffs for five consecutive days per week for 4 weeks. The study reported that e-cig exposure has a booster effect on the expression of phase 1 carcinogen-bioactivating enzymes in the lungs of exposed animals. Furthermore, both free radical production in the lungs and oxidation-induced DNA damage in peripheral blood were increased. These findings suggest that there is a significant increase in DNA mutations and cancer-causing changes in rats exposed to e-cig aerosols under experimental conditions [42]. However, studies demonstrating the effects of e-cigs are exploratory at present and further investigations will be required to prove the carcinogenicity of e-vapours.

While these reports certainly point towards harmful health effects of e-liquids, examining their impact on inflammatory responses is highly challenging due to the wide variety of flavours, which themselves may pose substantial threats to human health. The limitations of currently published work include the use of small sample sizes, which does not provide true understanding about the health impact of e-cig use on human cells. Substantial use of in vitro model systems without much in vivo replication or clinical evidence is another matter of concern. Most of these studies can only be extrapolated to understand the responses by electronic nicotine delivery systems (ENDS) users with no former history of smoking. It should be noted that most e-cig users also smoke traditional cigarettes, which increases the complexity of their responses. Thus, the marketing and popularisation of these products to alleviate tobacco addiction makes it necessary to extend studies to include populations or groups with compromised immune systems. A detailed understanding of the ill-effects of e-cig use including mutagenicity, carcinogenicity and effects on growth and reproductive health of an individual needs to be gained [43–45].

Vaping: is it safe for health?

Currently, there is limited understanding of the full health impacts of e-cig usage, and only scant reports associating e-cig use with cardiovascular, gastrointestinal and neurological risks are available. A study conducted by Monroy et al. [46] suggests that the use of e-cigs containing nicotine may have a damaging effect on heart cells, as acute e-cig use was found to affect left ventricular function and cause a delay in myocardial relaxation in a 70-year-old female. In addition, there have been other reports of pulmonary atrial fibrillation and acute myocardial infarction in e-cigs users, suggesting that e-cig use might pose a risk to the cardiovascular system [47]. There are case reports involving diagnosis of relapsed ulcerative colitis and enterocolitis in developing infants in association with e-cig aerosol exposure [48].

Compared to other associated health risks, it is more apparent that there are considerable pulmonary health risks associated with continued e-cig usage. To this end, Vardavas et al. [49] reported an increase in total respiratory impedance and flow respiratory resistance, in addition to a significant decline in exhaled nitric oxide fraction (F_eNO) levels, a marker for eosinophilic inflammation on short-term exposure (ad lib for 5 min) of 30 healthy individuals aged 19–56 years to e-cig vapours. On the downside, this study did not include a treatment group of individuals smoking conventional cigarettes only, making it hard to compare the safety of e-cigs with tobacco cigarettes. F_eNO is a biomarker for lung inflammation, which is affected by multiple factors including duration of exposure, smoking habits and current medication of the user [50]. Thus, it is difficult to predict probable decline in lung inflammation due to vaping just by measuring the F_eNO levels in the lungs. Furthermore, there are contradictory reports in relation to the F_eNO levels on e-vapour exposure. Several studies have reported an increase in F_eNO levels [51], while others observed no change [16]. As a part of an online study Hua et al. [5] analysed online forums to gather information about the positive and negative health effects of e-cig use. Most of the symptoms included mouth/throat irritation, dry cough, insomnia, increased palpitation, tightening of the lungs and difficulty breathing. The major disadvantage of this kind of study is that it relies on the individual's assessment of health effects without a proper control or health history. Nevertheless, it still suggests an association between e-cig use and health risks. Overall, the currently available clinical data do not associate serious health risks with e-cig use, but it should be noted that the current studies have not assessed the long-term effects of e-cig use and lack the proper study design required to gather conclusive outcomes.

Regulations imposed on the use of e-cigs

In 2016, the US FDA finalised its regulations concerning ENDS (e-cigs, vape pens, hookah tobacco and pipe tobacco), placing them under the category of tobacco products. The US FDA now regulates the manufacture, import, packaging, labelling, promotion, sales and distribution of ENDS. Moreover, the sale of e-cigs to minors (aged ≤18 years) is prohibited and photo-identification is mandatory for the buyers aged <26 years [52], and the sale of e-cigs or related products at vending machines (except in adult-only facilities) and free sample distribution for promotions is prohibited by law. Devices introduced after 2007 are required to undergo the same level of US FDA review that applies to conventional cigarettes for safety, warning labels and other restrictions. Under the current regulations, the US FDA will have the authority to review the design, nicotine content, delivery, voltage and formulations of all ENDS and flavoured tobacco products that have not yet been released onto the market. This legislation is intended to result in the evaluation and communication of all e-liquid ingredients and their potential risks [52, 53]. However, there is recent speculation that a United States House of Representatives bill might weaken the controls imposed by the US FDA and exempt the e-cigs from the tobacco regulations [54], a move that would be welcomed by e-cig manufacturers.

Future directions and conclusions

Overall, it could be said that our current knowledge about e-cigs and related products is very limited and their growing popularity serves to widen the gap between the impending effects and our lack of information regarding the effects on human health. There are many factors that require streamlining and serious consideration before drawing conclusions in relation to these products.