Revision as of 19:57, 11 December 2014 editQuackGuru (talk | contribs)Extended confirmed users79,978 edits →Regulatory debate: added wikilink to Positions of medical organizations regarding electronic cigarettes to make it a target for this section and and relevant text about "public health".← Previous edit | Revision as of 21:46, 11 December 2014 edit undoAlbinoFerret (talk | contribs)11,178 edits →Regulatory debate: remove off topic sectionNext edit → | ||
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There is insufficient data to determine the impact on ] from e-cigarettes.<ref name=Callahan2014>{{cite journal|last1=Callahan-Lyon|first1=P.|title=Electronic cigarettes: human health effects|journal=Tobacco Control|volume=23|issue=Supplement 2|year=2014|pages=ii36–ii40|issn=0964-4563|doi=10.1136/tobaccocontrol-2013-051470|pmid=24732161}}</ref> A ] published in 2014 by the ] concluded e-cigarettes emit airborne contaminants that may be inhaled by the user and those nearby.<ref name=AIHA2014/> Due to this possible risk, they urged restriction of their use indoors, similar to smoking bans, until research has shown the aerosol does not significantly harm others in the area.<ref name=AIHA2014>{{cite web|title=White Paper: Electronic Cigarettes in the Indoor Environment|url=http://tobacco.ucsf.edu/sites/tobacco.ucsf.edu/files/u9/AIHA-Electronc%20Cig%20Document_Final.pdf|publisher=American Industrial Hygiene Association|date=October 19, 2014}}</ref> A 2014 review indicated that the levels of inhaled contaminants from the e-cigarette vapor are not of significant health concern for human exposures by the standards used in workplaces to ensure safety.<ref name=Bur2014>{{cite journal|last1=Burstyn|first1=I|title=Peering through the mist: systematic review of what the chemistry of contaminants in electronic cigarettes tells us about health risks.|journal=BMC Public Health|date=9 January 2014|volume=14|pages=18|pmid=24406205|doi=10.1186/1471-2458-14-18|pmc=3937158}}</ref> | There is insufficient data to determine the impact on ] from e-cigarettes.<ref name=Callahan2014>{{cite journal|last1=Callahan-Lyon|first1=P.|title=Electronic cigarettes: human health effects|journal=Tobacco Control|volume=23|issue=Supplement 2|year=2014|pages=ii36–ii40|issn=0964-4563|doi=10.1136/tobaccocontrol-2013-051470|pmid=24732161}}</ref> A ] published in 2014 by the ] concluded e-cigarettes emit airborne contaminants that may be inhaled by the user and those nearby.<ref name=AIHA2014/> Due to this possible risk, they urged restriction of their use indoors, similar to smoking bans, until research has shown the aerosol does not significantly harm others in the area.<ref name=AIHA2014>{{cite web|title=White Paper: Electronic Cigarettes in the Indoor Environment|url=http://tobacco.ucsf.edu/sites/tobacco.ucsf.edu/files/u9/AIHA-Electronc%20Cig%20Document_Final.pdf|publisher=American Industrial Hygiene Association|date=October 19, 2014}}</ref> A 2014 review indicated that the levels of inhaled contaminants from the e-cigarette vapor are not of significant health concern for human exposures by the standards used in workplaces to ensure safety.<ref name=Bur2014>{{cite journal|last1=Burstyn|first1=I|title=Peering through the mist: systematic review of what the chemistry of contaminants in electronic cigarettes tells us about health risks.|journal=BMC Public Health|date=9 January 2014|volume=14|pages=18|pmid=24406205|doi=10.1186/1471-2458-14-18|pmc=3937158}}</ref> | ||
==Regulatory debate== | |||
{{further|Legal status of electronic cigarettes|Positions of medical organizations regarding electronic cigarettes}} | |||
The emerging phenomenon of electronic cigarettes has raised concerns among the health community, pharmaceutical industry, health regulators and state governments.<ref name=Saitta2014/> A 2014 review stated that e-cigarette regulation should be determined on the basis of the "reported" adverse ] effects.<ref name=Bekki2014/> For example, they found that "The Food and Drug Administration (FDA) reported that e-cigarettes contain carcinogens and toxic chemicals, such as nitrosamines and diethylene glycol, which have potentially harmful effects on humans."<ref name=Bekki2014/> Additionally, a WHO report in 2009 cautioned that the "safety of e-cigarettes is not confirmed, and e-cigarettes are not an appropriate tool for smoking cessation therapy."<ref name=Bekki2014/> "In a nutshell, the WHO report shows that e-cigarettes and similar devices pose threats to public health," said Douglas Bettcher, director of WHO's prevention of noncommunicable diseases.<ref name=Bettcher2014>{{cite news|title=WHO calls for ban on e-cigarette use indoors|url=http://www.bignewsnetwork.com/index.php/sid/225119529|date=26 August 2014|accessdate=28 August 2014|publisher=''Big News Network.com''}}</ref> | |||
E-cigarettes have been listed as "drug delivery devices" in several countries because they contain nicotine, and their advertising has been monetarily restricted until safety and efficacy ]s are conclusive.<ref name=Cervellin2013/> E-cigarettes are regulated as a ] in some countries, but are not permitted to be used as a cessation aid to help smokers quit.<ref name=Bekki2014/> | |||
==References== | ==References== |
Revision as of 21:46, 11 December 2014
The risks of electronic cigarette use are uncertain. This is due to there being little data regarding their health effects and to the variability of vaporizers and variability in liquid ingredients and in their concentration and quality, and thus variability of the contents of vapor delivered to the user. The limited evidence suggests that e-cigarettes are probably safer than traditional cigarettes. They appear to be similar in toxicity to other nicotine replacement products, but there is not enough data to draw conclusions. The evidence suggests that the US Food and Drug Administration (FDA) accepted products such as a nicotine inhaler may be a safer way to give nicotine than e-cigarettes. A July 2014 World Health Organization (WHO) report cautioned about potential risks of using electronic cigarettes. The report concluded that "the existing evidence shows that ENDS aerosol is not merely "water vapour" as is often claimed in the marketing for these products. ENDS use poses serious threats to adolescents and fetuses." A 2014 systematic review concluded that the risks of e-cigarettes have been exaggerated by health authorities and stated that it is apparent that there may be some remaining risk accompanied with e-cigarette use, though the risk of e-cigarette use is likely small compared to smoking tobacco. As of 2014, e-cigarettes cannot be regarded as harmless. Until additional data is available on the topic, using e-cigarettes cannot be regarded as safe. No long-term studies have shown that e-cigarettes are a "healthier alternative" to traditional cigarettes.
The distribution on the amount of nicotine inhaled by the user is not clear. The risk is probably low from the inhalation of propylene glycol and glycerol. When heated at hotter temperatures glycerol may generate harmful acrolein. There are no studies in respect to the short- and long-term effects of the inhalation for aromatic substances. The levels of chemical constituents in the vapor were found to be 1 to 2 orders of magnitude smaller than in cigarette smoke but greater compared to a nicotine inhaler. The long-term health impacts of e-cigarette use are unknown. There is limited information available on the environmental issues in connection with the production, the usage, and the disposing of e-cigarettes. Less serious adverse effects from e-cigarette use include throat and mouth inflammation, vomiting, nausea, and cough. Long-term studies regarding the effects of e-cigarettes after chronic exposure are unavailable.
The aerosol emitted from an e-cigarette is commonly but inaccurately called vapor. The particle size distribution of particles emitted by e-cigarettes are like traditional cigarettes, with the majority of particles in the ultrafine range (modes, ≈100–200 nm). Exhaled vapor consists of nicotine and some other particles, primarily consisting of flavors, aroma transporters, glycerol and propylene glycol. A 2014 WHO report stated passive exposure was as a concern, indicating that current evidence is insufficient to determine whether the levels of exhaled vapor are safe to involuntarily exposed bystanders. The report concluded that the aerosol emissions are likely to increase the risk of disease to nearby bystanders, especially from those e-cigarettes which produce toxicant levels close to those emitted by certain cigarettes. E-cigarette vapor has notably fewer toxicants than cigarette smoke (other than particulates) and is likely to pose less harm to users or bystanders. There is insufficient data to determine the impact on public health from e-cigarettes. It is recommended that e-cigarettes should be adequately regulated for consumer safety.
Toxicology
A preliminary analysis of e-cigarette cartridges by the US Food and Drug Administration (FDA) in 2009 identified that some contain tobacco-specific nitrosamines (TSNAs), known cancer-causing agents. The tobacco specific impurities suspected of being harmful to humans were anabasine, myosmine, and β-nicotyrine. They were detected in a majority of the samples. The amounts of TSNAs present were on par with a nicotine inhaler. The FDA's analysis also detected diethylene glycol, which is poisonous, in a single cartridge manufactured by Smoking Everywhere and nicotine in one cartridge claimed to be nicotine-free. This prompted the FDA to warn that e-cigarettes may present a health risk. While diethylene glycol was found in a cartridge tested in 2009 by the FDA, in 2011 researchers reviewed the data and noted that 15 other studies had failed to find any evidence of this chemical in e-cigarettes. The UK National Health Service noted that the toxic chemicals found by the FDA were at levels one-thousandth that of cigarette smoke, and that while there is no certainty that these small traces are harmless, initial test results are reassuring. Further concerns were raised over inconsistent amounts of nicotine delivered when drawing on the device. They appear to be similar in toxicity to other nicotine replacement products, but there is not enough data to draw conclusions. A 2014 review found that the "Levels of carcinogens and toxins in e-cigarettes typically exceeded those measured in an FDA-approved nicotine inhaler, suggesting that FDA-approved devices may be a safer method of nicotine delivery."
The user inhales an aerosol containing chemicals and very addictive nicotine. The distribution on the amount of nicotine inhaled by the user is not clear. Serum nicotine levels identified are inharmonious and rely upon the user and the device. There was inconsistent labeling of the actual nicotine content on e-liquid cartridges from some brands. Some nicotine has been found in ‘no nicotine' liquids. Due to nicotine content inconstancy, it is recommended that e-cigarette companies develop quality standards with respect to nicotine content. There are safety issues with the nicotine exposure from e-cigarettes, which has the possibility of causing addiction and other adverse effects. Serum cotinine levels are comparable to that of traditional cigarettes. The risk is probably low from the inhalation of propylene glycol and glycerol. Some research states that propylene glycol emissions may cause respiratory irritation and raise the likelihood to develop asthma. E-cigarettes companies use purified water and glycerin instead of propylene glycol for aerosol production to lesson the risks. When heated at hotter temperatures glycerol may generate harmful acrolein. Some e-cigarette products had acrolein identified in the aerosol. If exposure of aerosols to propylene glycol and glycerin rises to levels that one would consider the exposure in association with a workplace setting, it would be sensible to investigate the health of exposed persons. The essential propylene glycol and/or glycerol mixture may consist of natural or artificial substances to provide it flavor. Some of these substances are regarded as toxic and a number of them resemble known carcinogens. Although the majority of aromatic substances that mimic tobacco and others using generally inaccurate terms such as ‘vegetable flavoring' are approved for human use, there are no studies in respect to the short- and long-term effects of the inhalation of these substances. Some unnatural flavors have been demonstrated as being cytotoxic. There is a concern that some flavors could interest children.
A 2014 review found "Various chemical substances and ultrafine particles known to be toxic, carcinogenic and/or to cause respiratory and heart distress have been identified in e-cigarette aerosols, cartridges, refill liquids and environmental emissions." Many toxic chemical compounds have been produced from e-cigarettes, especially carbonyl compounds like formaldehyde, acetaldehyde, acrolein, and glyoxal, which are frequently identified in e-cigarette aerosols. These materials may cause harmful health effects; though, in the majority of cases, the amounts inhaled are less than those in traditional cigarettes. The toxicity of e-cigarettes and e-liquid can vary greatly, as there is potential differences in construction and materials in the delivery device, kind and origin of ingredients in the e-liquid, and the use or non-use of good manufacturing practices and quality control approaches. While there is variability in the ingredients and concentrations of ingredients in e-cigarette liquids, tobacco smoke contains thousands of chemicals, most of which are not understood and many of which are known to be harmful. The levels of chemical constituents in the vapor were found to be 1 to 2 orders of magnitude smaller than in cigarette smoke but greater compared to a nicotine inhaler. The Centers for Disease Control and Prevention (CDC) stated the possible negative impact between nicotine and brain development in youth is a concern. A serious concern is the outcome of nicotine on the growing adolescent brain. There is no long-term research concerning the cancer risk related to the small level of exposure to the identified carcinogens. The short-term toxicity of e-cigarette use appears to be low, with the exception for some people with reactive airways. The long-term health impacts of e-cigarette use are unknown. The long-term toxicity is subject to the additives and contaminants in the e-liquid. There is limited peer-reviewed data about the toxicity of e-cigarettes for a complete toxicological evaluation.
A 2013 review found after using a single e-cigarette there was an instant increase in airways resistance and concluded that they can do harm to the respiratory system. The risks, especially to the lungs, are not fully understood and are of concern to public health authorities. The particles are of the ultrafine size similar to that of traditional cigarettes, and can go deep in the lungs and then into the systemic circulation. Reports in the literature have shown respiratory and cardiovascular effects by these smaller size particles, suggesting a possible health concern. A 2014 review found e-cigarettes emissions contain the heavy metals nickel, tin, and chromium. These nanoparticles can deposit in the lung's alveolar sacs, potentially leading to local respiratory toxicity and entering the bloodstream. A 2014 review found it can be concluded that there is no evidence of contamination of the aerosol with metals that justifies a health concern. A 2014 review noted a study had found metal particles in the fluid and aerosol, however that study did not evaluate the relevance of the levels identified. The same review found that these levels were 10-50 times less than that allowed in medicines that are inhaled. A 2014 review found that e-cigarettes used in the short-term on specified cardiovascular and respiratory functional results have demonstrated that even though some minor harmful effects of vaping are documented, these are appreciably milder in comparison to traditional cigarettes. When used in the short-term, an e-cigarette results in a rise of respiratory resistance comparatively to traditional cigarettes. The long-term effects regarding respiratory flow resistance are unknown. E-cigarette use can be associated with a substantial dispersion of nicotine, thus generating a plasma nicotine concentration which can be comparable to that of traditional cigarettes. This is due to the minute nicotine particles in the vapor, which permit quick delivery into the bloodstream. This could explain the increased risk of cardiac arrhythmias and hypertension, which can affect some users, particularly those with atherosclerosis or other cardiovascular risk factors, to developing a significant risk of acute coronary syndrome. The limited evidence suggests that e-cigarettes produce less short-term effects on lung function than traditional cigarettes. Like cancer risk, there is no literature outlining the long-term lung function or cardiovascular consequences. A 2014 review found that e-cigarette aerosol contains far fewer carcinogens than tobacco smoke, and concluded that e-cigarettes "impart a lower potential disease burden" than traditional cigarettes. The affect on population health from e-cigarettes is unknown.
Environmental impact
There is limited information available on the environmental issues in connection with the production, the usage, and the disposing of e-cigarettes. As of 2014, it is uncertain if the nicotine in e-liquid is United States Pharmacopeia-grade nicotine, a tobacco extract, or a synthetic nicotine when examining the environmental impact of how its made. The emissions from making nicotine could be considerable from manufacturing if not appropriately controlled. Some e-cigarette brands state their products are ‘eco-friendly’ or ‘green’, even though in the absence of any supporting studies. Some journalists contend that such marketing may raise sales and increase e-cigarette interest, particularly among minors. It is unclear how many traditional cigarettes are comparable to using one e-cigarette for the average user. It is unclear in the manner that energy and materials used for production equate if e-cigarettes and traditional cigarettes are assessed on the basis of use. Even though some brands have began recycling services for their e-cigarette cartridges, the frequency of these services is unknown. Some brands have also began recycling services for their e-cigarette batteries. The frequency of recycling information on expendable e-cigarette finished product containers, along with how often expendable e-cigarettes are recycled, is unknown.
Adverse effects
E-cigarettes use lithium batteries most of the time; improper use may result in accidents. Rare major injuries have occurred from battery malfunctions such as explosions and fires. The explosions resulted either by extended charging and use of unsuitable chargers or by design flaws have occurred. It is recommended manufacturing quality standards be employed in order to prevent such accidents. Some of the risks from e-cigarette use could probably be reduced by better product design and standards. Use-related concerns with e-liquids involve leaks or spills and contact with contaminants in the e-liquid.
Less serious adverse effects of throat and mouth inflammation, vomiting, nausea, and cough have resulted from e-cigarette use. Short-term adverse effects include mouth and throat inflammation, dry cough, and nausea. Adverse effect are mostly associated with short-term of use. Long-term studies regarding the effects of e-cigarettes after chronic exposure are unavailable. Some case reports found harms to health brought about by e-cigarettes in many countries, such as the US and in Europe. Many of the observed negative effects from e-cigarette use concerning the nervous system and the sensory system are probably related to nicotine overdose or withdrawal. In youth, e-cigarette use risks involve accidental nicotine exposure and are possible choking dangers in youth. In pediatric patients, accidental exposures include ingesting of e-liquids and inhaling of e-cigarette vapor. The US Food and Drug Administration Center for Tobacco Products reported between 2008 and the beginning of 2012, 47 cases of adverse effects associated with e-cigarettes, and eight were considered serious. A causal relationship between e-cigarettes and the reported adverse effects was not established with the exception of two severe outcomes in the United States: a death when an infant choked on the cartridges and burns when one blew up.
In the United States the number of calls to poison control centers related to electronic cigarettes have increased between 2010 and 2014 such that they now represent 42% of reported cases due to either cigarettes and e-cigarettes up from 0.3%. These calls were in connection to both adults and children. E-cigarettes were associated with fewer adverse effects than nicotine patches. Calls to U.S. poison control centers related to e-cigarette exposures were inhalations, eye exposures, skin exposures, and ingestion, which included adults and young children. The California Poison Control System reported from 2010 to 2012, 35 cases of e-cigarette contact. 14 were from children and 25 were from accidental contact. The majority of adverse effects reported were nausea, vomiting, dizziness and oral irritation.
Ultrafine particles
E-cigarettes produce particles, in the form of an aerosol. The aerosol produced by an e-cigarette is commonly but inaccurately called vapor. In physics, a vapor is a substance in the gas phase whereas an aerosol is a suspension of tiny particles of liquid, solid or both within a gas. The word "vaping" is not technically accurate when applied to e-cigarettes. The aerosol is made-up of liquid sub-micron particles of condensed vapor; thus, the users of these devices are rather "aerosolizing." The aerosol the e-cigarette produces resembles cigarette smoke. A 2014 review found "Following a puff, the aerosol is delivered into the user's mouth and lungs by inhalation, after which the remaining aerosol is exhaled into the environment." E-cigarettes provide nicotine by creating liquid particles. E-cigarette vapor mostly consist of propylene glycol, glycerol, water, flavorings, nicotine, and chemicals.
Fine particles can be chemically intricate and not uniform, and what a particle is made of, the exact harmful elements, and the importance of the size of the particle is mostly unknown. Because these things are uncertain, it is not clear whether the ultrafine particles in e-cigarette vapor have health effects similar to those produced by traditional cigarettes. The nature and chemical composition of the components of e-cigarette vapor is entirely distinct from those in cigarette smoke. Though, the particle size distribution and sum of particles emitted by e-cigarettes are like traditional cigarettes, with the majority of particles in the ultrafine range (modes, ≈100–200).
Aerosol
Since e-cigarettes do not burn (or contain) tobacco, no side-stream smoke or any cigarette smoke is produced. Only what is exhaled by electronic cigarettes users enters the surrounding air. E-cigarettes used in indoor environments can put at risk nonsmokers to elevated levels of nicotine and aerosol emissions. A 2014 review of limited data concluded this vapor can cause indoor air pollution and is not just "water vapor" as is frequently stated in the advertising of e-cigarettes. Exhaled vapor consists of nicotine and some other particles, primarily consisting of flavors, aroma transporters, glycerol and propylene glycol. Bystanders are exposed to these particles from exhaled e-cigarette vapor. A mixture of harmful substances, particularly nicotine, ultrafine particles, and volatile organic compounds can be exhaled into the air. The dense vapor consists of liquid sub-micron droplets. The liquid particles condenses into a viewable fog. The vapor is in the air for a short time, with a half-life of about 10 seconds; traditional cigarette smoke is in the air 100 times longer. This is because of fast revaporization at room temperature. Some of the few studies examining the effects on health shown that being exposed to e-cigarette vapor may produce biological effects. Since e-cigarettes have not been widely used long enough for evaluation, the long-term health effects from the second-hand vapor are not known.
As of 2013, the only clinical study currently published evaluating the respiratory effects of passive vaping found no adverse effects were detected. A 2014 review found it is safe to infer that their effects on bystanders are minimal in comparison to traditional cigarettes. A 2014 WHO report stated passive exposure was as a concern, indicating that current evidence is insufficient to determine whether the levels of exhaled vapor are safe to involuntarily exposed bystanders. The report concluded that the aerosol emissions are likely to increase the risk of disease to nearby bystanders, especially from those e-cigarettes which produce toxicant levels close to those emitted by certain cigarettes. E-cigarette vapor has notably fewer toxicants than cigarette smoke (other than particulates) and is likely to pose less harm to users or bystanders.
Nonsmokers exposed to e-cigarette aerosol produced by a machine and pumped into a room were found to have detectable levels of the nicotine metabolite cotinine in their blood. The same study stated that 80% of nicotine is normally absorbed by the user, so these results may be higher than in actual second hand exposure. A 2014 review stated there are concerns about pregnant women exposure to e-cigarette vapor through direct use or via exhaled vapor. As of 2014, there is no conclusions on the possible hazards of pregnant women using e-cigarettes, and there is a developing research on the negative effects of nicotine on prenatal brain development. A 2014 review concluded no amount of nicotine is safe for pregnant women. As of 2014, the long-term issues of e-cigarettes on both mother and unborn baby are unknown. There are concerns about the health impacts of pediatric exposure to second-hand and third-hand e-cigarette vapor.
There is insufficient data to determine the impact on public health from e-cigarettes. A white paper published in 2014 by the American Industrial Hygiene Association concluded e-cigarettes emit airborne contaminants that may be inhaled by the user and those nearby. Due to this possible risk, they urged restriction of their use indoors, similar to smoking bans, until research has shown the aerosol does not significantly harm others in the area. A 2014 review indicated that the levels of inhaled contaminants from the e-cigarette vapor are not of significant health concern for human exposures by the standards used in workplaces to ensure safety.
References
- ^ Odum, L. E.; O'Dell, K. A.; Schepers, J. S. (December 2012). "Electronic cigarettes: do they have a role in smoking cessation?". Journal of pharmacy practice. 25 (6): 611–4. doi:10.1177/0897190012451909. PMID 22797832.
- Harrell, PT; Simmons, VN; Correa, JB; Padhya, TA; Brandon, TH (4 June 2014). "Electronic Nicotine Delivery Systems ("E-cigarettes"): Review of Safety and Smoking Cessation Efficacy". Otolaryngology—head and neck surgery : official journal of American Academy of Otolaryngology-Head and Neck Surgery. doi:10.1177/0194599814536847. PMID 24898072.
These devices are unregulated, of unknown safety, and of uncertain benefit in quitting smoking.
- Palazzolo, Dominic L. (Nov 2013), "Electronic cigarettes and vaping: a new challenge in clinical medicine and public health. A literature review.", Frontiers in Public Health, 1 (56), doi:10.3389/fpubh.2013.00056, PMC 3859972, PMID 24350225
{{citation}}
: CS1 maint: unflagged free DOI (link) - ^ Grana, R; Benowitz, N; Glantz, SA (13 May 2014). "E-cigarettes: a scientific review". Circulation. 129 (19): 1972–86. doi:10.1161/circulationaha.114.007667. PMC 4018182. PMID 24821826.
- ^ O'Connor, RJ (March 2012). "Non-cigarette tobacco products: what have we learnt and where are we headed?". Tobacco control. 21 (2): 181–90. doi:10.1136/tobaccocontrol-2011-050281. PMC 3716250. PMID 22345243.
- ^ Caponnetto P; Russo C; Bruno CM; Alamo A; Amaradio MD; Polosa R. (Mar 2013). "Electronic cigarette: a possible substitute for cigarette dependence". Monaldi archives for chest disease. 79 (1): 12–19. PMID 23741941.
- ^ Drummond, MB; Upson, D (February 2014). "Electronic cigarettes. Potential harms and benefits". Annals of the American Thoracic Society. 11 (2): 236–42. doi:10.1513/annalsats.201311-391fr. PMID 24575993.
- ^ WHO. "Electronic nicotine delivery systems" (PDF). Retrieved 28 August 2014.
- ^ Farsalinos, K. E.; Polosa, R. (2014). "Safety evaluation and risk assessment of electronic cigarettes as tobacco cigarette substitutes: a systematic review". Therapeutic Advances in Drug Safety. 5 (2): 67–86. doi:10.1177/2042098614524430. ISSN 2042-0986. PMC 4110871. PMID 25083263.
- Pisinger, Charlotta; Døssing, Martin (December 2014). "A systematic review of health effects of electronic cigarettes". Preventive Medicine. 69: 248–260. doi:10.1016/j.ypmed.2014.10.009.
- ^ Bertholon, J.F.; Becquemin, M.H.; Annesi-Maesano, I.; Dautzenberg, B. (2013). "Electronic Cigarettes: A Short Review". Respiration. doi:10.1159/000353253. ISSN 1423-0356. PMID 24080743.
- ^ Hajek, P; Etter, JF; Benowitz, N; Eissenberg, T; McRobbie, H (31 July 2014). "Electronic cigarettes: review of use, content, safety, effects on smokers and potential for harm and benefit" (PDF). Addiction (Abingdon, England). 109 (11): 1801–10. doi:10.1111/add.12659. PMID 25078252.
- ^ Chang, H. (2014). "Research gaps related to the environmental impacts of electronic cigarettes". Tobacco Control. 23 (Supplement 2): ii54–ii58. doi:10.1136/tobaccocontrol-2013-051480. ISSN 0964-4563. PMC 3995274. PMID 24732165.
- ^ Gualano, M. R.; Passi, S.; Bert, F.; La Torre, G.; Scaioli, G.; Siliquini, R. (9 August 2014). "Electronic cigarettes: assessing the efficacy and the adverse effects through a systematic review of published studies". Journal of Public Health. doi:10.1093/pubmed/fdu055. PMID 25108741.
- ^ Cheng, T. (2014). "Chemical evaluation of electronic cigarettes". Tobacco Control. 23 (Supplement 2): ii11–ii17. doi:10.1136/tobaccocontrol-2013-051482. ISSN 0964-4563. PMC 3995255. PMID 24732157.
- ^ Callahan-Lyon, P. (2014). "Electronic cigarettes: human health effects". Tobacco Control. 23 (Supplement 2): ii36–ii40. doi:10.1136/tobaccocontrol-2013-051470. ISSN 0964-4563. PMID 24732161.
- ^ Saitta, D; Ferro, GA; Polosa, R (Mar 2014). "Achieving appropriate regulations for electronic cigarettes". Therapeutic advances in chronic disease. 5 (2): 50–61. doi:10.1177/2040622314521271. PMC 3926346. PMID 24587890.
- Arnold, Carrie (2014). "Vaping and Health: What Do We Know about E-Cigarettes?". Environmental Health Perspectives. 122 (9): A244–A249. doi:10.1289/ehp.122-A244. PMC 4154203. PMID 25181730.
- ^ "Safety Watch: Electronic Cigarettes". FDA.
- FDA (22 July 2009). "Summary of Results: Laboratory Analysis of Electronic Cigarettes Conducted By FDA". Retrieved 22 July 2009.
- ^ FDA (4 May 2009). "FDA 2009 Study Data: Evaluation of e-cigarettes" (PDF). Food and Drug Administration (US) -center for drug evaluation and research. Retrieved 4 May 2009.
- Palmer, Roxanne (8 September 2013). "E-Cigarettes As Effective As Nicotine Patches in Helping Smokers Quit: Study". International Business Times. Retrieved 15 December 2013.
- "E-cigarettes to be regulated as medicines". National Health Service. 12 June 2013. Retrieved August 2013.
{{cite web}}
: Check date values in:|accessdate=
(help) - "Public Health Focus: Electronic Cigarettes (e-Cigarettes)". FDA. 24 April 2014.
- ^ Oh, Anne Y.; Kacker, Ashutosh (December 2014). "Do electronic cigarettes impart a lower potential disease burden than conventional tobacco cigarettes?: Review on e-cigarette vapor versus tobacco smoke". The Laryngoscope. 124 (12): 2702–2706. doi:10.1002/lary.24750. PMID 25302452.
- ^ Burstyn, I (9 January 2014). "Peering through the mist: systematic review of what the chemistry of contaminants in electronic cigarettes tells us about health risks". BMC Public Health. 14: 18. doi:10.1186/1471-2458-14-18. PMC 3937158. PMID 24406205.
{{cite journal}}
: CS1 maint: unflagged free DOI (link) - Etter, J. F.; Bullen, C.; Flouris, A. D.; Laugesen, M.; Eissenberg, T. (May 2011). "Electronic nicotine delivery systems: a research agenda". Tobacco control. 20 (3): 243–8. doi:10.1136/tc.2010.042168. PMC 3215262. PMID 21415064.
- ^ Bekki, Kanae; Uchiyama, Shigehisa; Ohta, Kazushi; Inaba, Yohei; Nakagome, Hideki; Kunugita, Naoki (2014). "Carbonyl Compounds Generated from Electronic Cigarettes". International Journal of Environmental Research and Public Health. 11 (11): 11192–11200. doi:10.3390/ijerph111111192. ISSN 1660-4601. PMID 25353061.
{{cite journal}}
: CS1 maint: unflagged free DOI (link) - ^ Orr, M. S. (2014). "Electronic cigarettes in the USA: a summary of available toxicology data and suggestions for the future". Tobacco Control. 23 (Supplement 2): ii18–ii22. doi:10.1136/tobaccocontrol-2013-051474. ISSN 0964-4563. PMID 24732158.
- Centers for Disease Control and Prevention, (CDC) (6 September 2013). "Notes from the field: electronic cigarette use among middle and high school students – United States, 2011–2012". MMWR. Morbidity and mortality weekly report. 62 (35): 729–30. PMID 24005229.
- Edgar, Julie. "E-Cigarettes: Expert Q&A With the CDC". WebMD. Retrieved 17 November 2013.
- Britton, John; Bogdanovica, Ilze (15 May 2014), Electronic cigarettes – A report commissioned by Public Health England (PDF), Public Health England
- "Electronic cigarettes (e-cigarettes) or electronic nicotine delivery systems". World Health Organization. 3 June 2014.
- "Position Statement on Electronic Cigarettes [ECs] or Electronic Nicotine Delivery Systems [ENDS]" (PDF). The International Union against Tuberculosis and Lung Disease. October 2013.
- ^ "White Paper: Electronic Cigarettes in the Indoor Environment" (PDF). American Industrial Hygiene Association. October 19, 2014.
- ^ Cervellin, Gianfranco; Borghi, Loris; Mattiuzzi, Camilla; Meschi, Tiziana; Favaloro, Emmanuel; Lippi, Giuseppe (2013). "E-Cigarettes and Cardiovascular Risk: Beyond Science and Mysticism". Seminars in Thrombosis and Hemostasis. 40 (01): 060–065. doi:10.1055/s-0033-1363468. ISSN 0094-6176. PMID 24343348.
- ^ Yang, L.; Rudy, S. F.; Cheng, J. M.; Durmowicz, E. L. (2014). "Electronic cigarettes: incorporating human factors engineering into risk assessments". Tobacco Control. 23 (Supplement 2): ii47–ii53. doi:10.1136/tobaccocontrol-2013-051479. ISSN 0964-4563. PMID 24732164.
- Lauterstein, Dana; Hoshino, Risa; Gordon, Terry; Watkins, Beverly-Xaviera; Weitzman, Michael; Zelikoff, Judith (2014). "The Changing Face of Tobacco Use Among United States Youth". Current Drug Abuse Reviews. 7 (1): 29–43. doi:10.2174/1874473707666141015220110. ISSN 1874-4737. PMID 25323124.
- ^ Durmowicz, E. L. (2014). "The impact of electronic cigarettes on the paediatric population". Tobacco Control. 23 (Supplement 2): ii41–ii46. doi:10.1136/tobaccocontrol-2013-051468. ISSN 0964-4563. PMID 24732163.
- ^ Orr, KK; Asal, NJ (November 2014). "Efficacy of Electronic Cigarettes for Smoking Cessation". The Annals of pharmacotherapy. 48 (11): 1502–1506. doi:10.1177/1060028014547076. PMID 25136064.
- Centers for Disease Control and Prevention (CDC) (April 2014). "Notes from the field: calls to poison centers for exposures to electronic cigarettes--United States, September 2010-February 2014". MMWR Morb. Mortal. Wkly. Rep. 63 (13): 292–3. PMID 24699766.
- ^ Offermann, Francis (June 2014). "The Hazards of E-Cigarettes" (PDF). ASHRAE Journal. 56 (6).
- ^ Suter, Melissa A.; Mastrobattista, Joan; Sachs, Maike; Aagaard, Kjersti (2014). "Is There Evidence for Potential Harm of Electronic Cigarette Use in Pregnancy?". Birth Defects Research Part A: Clinical and Molecular Teratology: n/a–n/a. doi:10.1002/bdra.23333. ISSN 1542-0752. PMID 25366492.
External links
- Media related to Electronic cigarettes at Wikimedia Commons
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