Metal Concentrations in e-Cigarette Liquid and Aerosol Samples: The Contribution of Metallic Coils

Pablo Olmedo, Walter Goessler, Stefan Tanda, Maria Grau-Perez, Stephanie Jarmul, Angela Aherrera, Rui Chen, Markus Hilpert, Joanna E Cohen, Ana Navas-Acien, Ana M Rule, Pablo Olmedo, Walter Goessler, Stefan Tanda, Maria Grau-Perez, Stephanie Jarmul, Angela Aherrera, Rui Chen, Markus Hilpert, Joanna E Cohen, Ana Navas-Acien, Ana M Rule

Abstract

Background: Electronic cigarettes (e-cigarettes) generate an aerosol by heating a solution (e-liquid) with a metallic coil. Whether metals are transferred from the coil to the aerosol is unknown.

Objective: Our goal was to investigate the transfer of metals from the heating coil to the e-liquid in the e-cigarette tank and the generated aerosol.

Methods: We sampled 56 e-cigarette devices from daily e-cigarette users and obtained samples from the refilling dispenser, aerosol, and remaining e-liquid in the tank. Aerosol liquid was collected via deposition of aerosol droplets in a series of conical pipette tips. Metals were reported as mass fractions (μg/kg) in liquids and converted to mass concentrations (mg/m3) for aerosols.

Results: Median metal concentrations (μg/kg) were higher in samples from the aerosol and tank vs. the dispenser (all p<0.001): 16.3 and 31.2 vs. 10.9 for Al; 8.38 and 55.4 vs. <0.5 for Cr; 68.4 and 233 vs. 2.03 for Ni; 14.8 and 40.2 vs. 0.476 for Pb; and 515 and 426 vs. 13.1 for Zn. Mn, Fe, Cu, Sb, and Sn were detectable in most samples. Cd was detected in 0.0, 30.4, and 55.1% of the dispenser, aerosol, and tank samples respectively. Arsenic was detected in 10.7% of dispenser samples (median 26.7μg/kg) and these concentrations were similar in aerosol and tank samples. Aerosol mass concentrations (mg/m3) for the detected metals spanned several orders of magnitude and exceeded current health-based limits in close to 50% or more of the samples for Cr, Mn, Ni, and Pb.

Conclusions: Our findings indicate that e-cigarettes are a potential source of exposure to toxic metals (Cr, Ni, and Pb), and to metals that are toxic when inhaled (Mn and Zn). Markedly higher concentrations in the aerosol and tank samples versus the dispenser demonstrate that coil contact induced e-liquid contamination. https://doi.org/10.1289/EHP2175.

Figures

Figure 1.
Figure 1.
Boxplots of metal concentrations in e-cigarette dispenser, aerosol, and tank samples. The dispenser sample has not had any contact with the e-cigarette device. The horizontal lines within boxes indicate medians; boxes, interquartile ranges; whiskers, values within 1.5 times the interquartile range from boxes; solid circles outside the boxes, outlier data values. Table 2 lists the raw data for all metals represented in this figure. All metals in Table 2 are represented in this figure except Cd and Sb, as their concentrations were below 1μg/kg for most samples. Note: For samples with ≥25% of the samples below the limit of detection, the minimum and the percentile 25th values are the same and therefore the lower whisker is missing.
Figure 2.
Figure 2.
Correlations between metals in samples from e-cigarette devices: (A) aerosol samples, and (B) tank samples. All metals shown in Figure 1 are shown here. The diagonal panel shows the histograms of the log10-transformed distribution of each metal. The upper part of the panel represents the Spearman pairwise correlation coefficients between metals. The axes indicate the log10 metal concentrations values that are represented in the histograms. Correlations ≥0.50 are bolded.
Figure 2.
Figure 2.
Correlations between metals in samples from e-cigarette devices: (A) aerosol samples, and (B) tank samples. All metals shown in Figure 1 are shown here. The diagonal panel shows the histograms of the log10-transformed distribution of each metal. The upper part of the panel represents the Spearman pairwise correlation coefficients between metals. The axes indicate the log10 metal concentrations values that are represented in the histograms. Correlations ≥0.50 are bolded.

References

    1. Aherrera A, Olmedo P, Grau-Perez M, Tanda S, Goessler W, Jarmul S, et al. 2017. The association of e-cigarette use with exposure to nickel and chromium: a preliminary study of non-invasive biomarkers. Environ Res 159:313–320, PMID: 28837903, 10.1016/j.envres.2017.08.014.
    1. Ambrose BK, Rostron BL, Johnson SE, Portnoy DB, Apelberg BJ, Kaufman AR, et al. 2014. Perceptions of the relative harm of cigarettes and e-cigarettes among U.S. youth. Am J Prev Med 47(2 suppl 1):S53–S60, PMID: 25044196, 10.1016/j.amepre.2014.04.016.
    1. ATSDR (Agency for Toxic Substances and Disease Registry). 2004. Toxicological profile for copper. Atlanta, GA:U.S. Department of Health and Human Services, Public Health Service; [accessed 1 November 2016].
    1. ATSDR. 2005a. Toxicological profile for nickel. Atlanta, GA:U.S. Department of Health and Human Services, Public Health Service; [accessed 1 November 2016].
    1. ATSDR. 2005b. Toxicological profile for zinc. Atlanta, GA:U.S. Department of Health and Human Services, Public Health Service; [accessed 1 November 2016].
    1. ATSDR. 2012a. Toxicological profile for chromium. Atlanta, GA:U.S. Department of Health and Human Services, Public Health Service; [accessed 14 December 2016].
    1. ATSDR. 2012b. Toxicological profile for manganese. Atlanta, GA:U.S. Department of Health and Human Services, Public Health Service; [accessed 1 November 2016].
    1. ATSDR. 2016. Minimal Risk Levels (MRLs) List. [accessed 21 December 2016].
    1. Beauval N, Howsam M, Antherieu S, Allorge D, Soyez M, Garçon G, et al. 2016. Trace elements in e-liquids-development and validation of an ICP-MS method for the analysis of electronic cigarette refills. Regul Toxicol Pharmacol 79:144–148, PMID: 27058761, 10.1016/j.yrtph.2016.03.024.
    1. CDC (Centers for Disease Control and Prevention). 2010. How Tobacco Smoke Causes Disease: The Biology and Behavioral Basis for Smoking-Attributable Disease. A Report of the Surgeon General. [accessed 14 October 2017].
    1. Cooper M, Harrell MB, Perry CL. 2016. A qualitative approach to understanding real-world electronic cigarette use: implications for measurement and regulation. Prev Chronic Dis 13:E07, PMID: 26766848, 10.5888/pcd13.150502.
    1. Edwards M, Dudi A. 2004. Role of chlorine and chloramine in corrosion of lead-bearing plumbing materials. J Am Water Works Assoc 96(10):69–81.
    1. Fadrowski JJ, Navas-Acien A, Tellez-Plaza M, Guallar E, Weaver VM, Furth SL. 2010. Blood lead level and kidney function in US adolescents: the Third National Health and Nutrition Examination Survey. Arch Intern Med 170(1):75–82, PMID: 20065202, 10.1001/archinternmed.2009.417.
    1. Farsalinos KE, Voudris V, Poulas K. 2015. Are metals emitted from electronic cigarettes a reason for health concern? A risk-assessment analysis of currently available literature. Int J Environ Res Public Health 12(5):5215–5232, PMID: 25988311, 10.3390/ijerph120505215.
    1. Fuoco FC, Buonanno G, Stabile L, Vigo P. 2014. Influential parameters on particle concentration and size distribution in the mainstream of e-cigarettes. Environ Pollut 184:523–529, PMID: 24172659, 10.1016/j.envpol.2013.10.010.
    1. Garza A, Vega R, Soto E. 2006. Cellular mechanisms of lead neurotoxicity. Med Sci Monit 12(3):RA57–RA65, PMID: 16501435.
    1. Giovenco DP, Hammond D, Corey CG, Ambrose BK, Delnevo CD. 2015. E-cigarette market trends in traditional U.S. retail channels, 2012–2013. Nicotine Tob Res 17(10):1279–1283, PMID: 25542918, 10.1093/ntr/ntu282.
    1. Goniewicz ML, Knysak J, Gawron M, Kosmider L, Sobczak A, Kurek J, et al. 2014. Levels of selected carcinogens and toxicants in vapour from electronic cigarettes. Tob Control 23(2):133–139, PMID: 23467656, 10.1136/tobaccocontrol-2012-050859.
    1. Hess CA, Olmedo P, Navas-Acien A, Goessler W, Cohen JE, Rule AM. 2017. E-cigarettes as a source of toxic and potentially carcinogenic metals. Environ Res 152:221–225, PMID: 27810679, 10.1016/j.envres.2016.09.026.
    1. IARC (International Agency for Research on Cancer). 2012a. Chromium (VI) compounds. IARC Monographs 100C:147–167.
    1. IARC 2012b. Nickel and nickel compounds. IARC Monographs 100C:169–218.
    1. Jaishankar M, Tseten T, Anbalagan N, Mathew BB, Beeregowda KN. 2014. Toxicity, mechanism and health effects of some heavy metals. Interdiscip Toxicol 7(2):60–72, PMID: 26109881, 10.2478/intox-2014-0009.
    1. Johnson A, Moira CY, MacLean L, Atkins E, Dybuncio A, Cheng F, et al. 1985. Respiratory abnormalities among workers in an iron and steel foundry. Br J Ind Med 42(2):94–100, PMID: 2982392, 10.1136/oem.42.2.94.
    1. Lin JL, Lin-Tan DT, Li YJ, Chen KH, Huang YL. 2006. Low-level environmental exposure to lead and progressive chronic kidney diseases. Am J Med 119(8):707.e1–707.e9, PMID: 16887418, 10.1016/j.amjmed.2006.01.005.
    1. Long W, Hilpert M. 2009. A correlation for the collector efficiency of Brownian particles in clean-bed filtration in sphere packings by a lattice-Boltzmann method. Environ Sci Technol 43(12):4419–4424, PMID: 19603656, 10.1021/es8024275.
    1. McCarthy M. 2015. “Alarming” rise in popularity of e-cigarettes is seen among US teenagers as use triples in a year. BMJ 350:h2083, PMID: 25896797, 10.1136/bmj.h2083.
    1. McQueen N, Partington EJ, Harrington KF, Rosenthal EL, Carroll WR, Schmalbach CE. 2015. Smoking cessation and electronic cigarette use among head and neck cancer patients. Otolaryngol Head Neck Surg 154(1):73–79, PMID: 26519457, 10.1177/0194599815613279.
    1. Mikheev VB, Brinkman MC, Granville CA, Gordon SM, Clark PI. 2016. Real-time measurement of electronic cigarette aerosol size distribution and metals content analysis. Nicotine Tob Res 18(9):1895–1902, PMID: 27146638, 10.1093/ntr/ntw128.
    1. Moon K, Guallar E, Navas-Acien A. 2012. Arsenic exposure and cardiovascular disease: an updated systematic review. Curr Atheroscler Rep 14(6):542–555, PMID: 22968315, 10.1007/s11883-012-0280-x.
    1. Navas-Acien A, Guallar E, Silbergeld EK, Rothenberg SJ. 2007. Lead exposure and cardiovascular disease–a systematic review. Environ Health Perspect 115(3):472–482, PMID: 17431501, 10.1289/ehp.9785.
    1. Olmedo P, Navas-Acien A, Hess C, Jarmul S, Rule A. 2016. A direct method for e-cigarette aerosol sample collection. Environ Res 149:151–156, PMID: 27200479, 10.1016/j.envres.2016.05.008.
    1. O’Neal SL, Zheng W. 2015. Manganese toxicity upon overexposure: a decade in review. Curr Environ Health Rep 2(3):315–328, PMID: 26231508, 10.1007/s40572-015-0056-x.
    1. Orr KK, Asal NJ. 2014. Efficacy of electronic cigarettes for smoking cessation. Ann Pharmacother 48(11):1502–1506, PMID: 25136064, 10.1177/1060028014547076.
    1. Pappas RS, Fresquez MR, Martone N, Watson CH. 2014. Toxic metal concentrations in mainstream smoke from cigarettes available in the USA. J Anal Toxicol 38(4):204–211, PMID: 24535337, 10.1093/jat/bku013.
    1. Robinson RJ, Hensel EC, Morabito PN, Roundtree KA. 2015. Electronic cigarette topography in the natural environment. PLoS One 10(6):e0129296, PMID: 26053075, 10.1371/journal.pone.0129296.
    1. Saffari A, Daher N, Ruprecht A, De Marco C, Pozzi P, Boffi R, et al. 2014. Particulate metals and organic compounds from electronic and tobacco-containing cigarettes: comparison of emission rates and secondhand exposure. Environ Sci Process Impacts 16(10):2259–2267, PMID: 25180481, 10.1039/c4em00415a.
    1. Saint-Jacques N, Parker L, Brown P, Dummer TJ. 2014. Arsenic in drinking water and urinary tract cancers: a systematic review of years of epidemiological evidence. Environ Health 13:44, PMID: 24889821, 10.1186/1476-069X-13-44.
    1. Schoenborn CA, Gindi RM. 2015. Electronic cigarette use among adults: United States, 2014. NCHS Data Brief 217:1–8, PMID: 26555932.
    1. Sleiman M, Logue JM, Montesinos VN, Russell ML, Litter MI, Gundel LA, et al. 2016. Emissions from electronic cigarettes: key parameters affecting the release of harmful chemicals. Environ Sci Technol 50(17):9644–9651, PMID: 27461870, 10.1021/acs.est.6b01741.
    1. St Helen G, Havel C, Dempsey DA, Jacob P III, Benowitz NL. 2016. Nicotine delivery, retention and pharmacokinetics from various electronic cigarettes. Addiction 111(3):535–544, PMID: 26430813, 10.1111/add.13183.
    1. Tien C, Ramarao BV. 2007. Granular Filtration of Aerosols and Hydrosols. 2nd Edition. Amsterdam, Netherlands:Elsevier Science.
    1. U.S. EPA (U.S. Environmental Protection Agency). 2000a. Nickel Compounds. [accessed 19 December 2017].
    1. U.S. EPA. 2000b. Chromium Compounds. [accessed 5 October 2016].
    1. U.S. EPA. 2012. Inhalation Health Effect Reference Values for Manganese and Compounds. [accessed 14 December 2017].
    1. U.S. EPA. 2016. NAAQS Table. [accessed 5 October 2016].
    1. Williams M, Bozhilov K, Ghai S, Talbot P. 2017. Elements including metals in the atomizer and aerosol of disposable electronic cigarettes and electronic hookahs. PLoS One 12(4):e0175430, PMID: 28414730, 10.1371/journal.pone.0175430.
    1. Williams M, To A, Bozhilov K, Talbot P. 2015. Strategies to reduce tin and other metals in electronic cigarette aerosol. PLoS One 10(9):e0138933, PMID: 26406602, 10.1371/journal.pone.0138933.
    1. Williams M, Villarreal A, Bozhilov K, Lin S, Talbot P. 2013. Metal and silicate particles including nanoparticles are present in electronic cigarette cartomizer fluid and aerosol. PLoS One 8(3):e57987, PMID: 23526962, 10.1371/journal.pone.0057987.

Source: PubMed

Sponzoři a spolupracovníci

Zdravotní podmínky

Drogové intervence

3
Předplatit