1

Introduction

Tobacco consumption is one of the main causes of morbidity and mortality globally [ ] with cigarette smoke being a rich source of heavy metals and other toxic elements [ ]. Consequently, various pathological conditions are associated with smoking such as cancer, heart attacks and strokes [ ]. The prevalence of smoking among adults was estimated as 19.2 % of the general population in 2019, with substantial regional variations [ ]. According to the World Health Organization (WHO) report on the global tobacco epidemic, the prevalence rates for cigarette smoking for the United Kingdom is 15.1 %, for the United States of America 19.9 % and for Australia 14.9 %, while it rises to 35 % in the tobacco producing country of Greece [ ]. According to the WHO, tobacco ultimately kills as many as half of its users – more than seven million human beings each year. More than six million of those deaths are the result of direct tobacco use, whilst around 890,000 are due to non-smokers being exposed to ‘second-hand’ smoke. In Europe, it is anticipated that tobacco smoking accounts for 700,000 deaths each year, with an associated cost greater than 100 billion euros [ ].

In addition to its association with systemic disorders and conditions, smoking has been linked to various eye pathologies [ , ], including dry eye disease, which is a significant healthcare problem affecting millions of people [ ]. However, the association between smoking and ocular disease is not well recognized by the public [ , ].

In the last decade, electronic nicotine delivery systems (ENDS), such as electronic cigarettes (ECs), have been introduced as a potentially healthier alternative to conventional cigarettes. This drew the attention of WHO, who included ECs in their 2019 global report on smoking and tobacco use. There is no estimate on a global EC use, probably because out of 195 countries studied, only 39 provided data. The prevalence of ECs use though in United Kingdom is 5.5 %, in Australia 3.2 % and in Greece 1.9 % [ ].

ECs are battery-powered devices which deliver the stimulant nicotine to users by producing a heated vapour which is inhaled. This process is commonly referred to as vaping [ ]. The vapour may contain nicotine and various fruit and other flavours but does not contain tobacco, or other tobacco combustion byproducts. Although ECs owe their popularity to the absence of the harmful chemicals that are identified in the tobacco smoke, there is still a debate about their safety. In this review, we focus on the effects of smoking conventional cigarettes and using ECs, particularly with regard to dry eye disease and other ocular conditions.

2

Conventional cigarettes

There are about 1.2 billion smokers worldwide [ ]. Cigarette smoke causes the intake of heavy metals and toxic mineral elements and can be divided into mainstream smoke , which is inhaled by smokers from the burning tobacco and side stream smoke , which is emitted into the surrounding air during puffs [ ]. It is known that tobacco smoke is a toxic and carcinogenic mixture that contains almost 5,000 chemicals and consists of both vapour and particulate phases [ , ]. Some components, such as CO and CO ₂ are found in the vapour phase, while others, such as phytosterols, are found in the particulate phase. Other compounds, such as phenol and cresols, are found in both phases [ ]. More than seventy human carcinogens have been identified in tobacco smoke [ ]. The best known component of tobacco is nicotine, a psychoactive chemical, but the risk of long term nicotine intake is still being researched.

Almost every organ of the body is affected [ ] by the significant toxicity of smoking. The negative effects on human health include cancerous and non-cancerous lung diseases, other forms of cancer, atherosclerotic diseases of the heart and blood, damage of the reproductive system and interaction with some therapeutic drugs [ , ]. It is also responsible for dyslipidemia, high-density lipoprotein (HDL) reduction and concomitant increase of low-density lipoprotein (LDL) and triglycerides which, in turn, can lead to more rapid thromboembolism [ , ]. Furthermore, smoking tends to affect the immune responses of smokers, causing tissue damage and inflammation. At molecular and cellular levels, the smoking process, in addition to causing hypoxia and oxidative stress, triggers the production of pro-inflammatory cytokines and autoantibodies [ ]. Autoimmune diseases such as rheumatoid arthritis, Crohn’s disease and multiple sclerosis are associated with smoking [ ].

3

Electronic cigarettes

An EC device is comprised of a battery, as a power unit, and an atomizer that includes the heating coil, which produces steam. Most commonly, e-liquids contain water, nicotine, vegetable glycerin (VG), propylene glycerol (PG) and a mix of flavouring additives, in variable concentrations, in order to achieve the desired taste while vaping [ ]. ECs can deliver nicotine, hence managing the chemical part of the addiction, and, at the same time, they offer sensory and motor stimuli much like smoking.

ECs offer an alternative method of nicotine delivery and are used by consumers to reduce, or fully substitute, the smoking of conventional cigarettes. The ability of ECs to deliver nicotine whilst retaining the ‘look and feel’ of conventional cigarettes has led to success in the reduction of conventional cigarette consumption [ ].

Awareness and use of ECs has grown exponentially over the past few years [ , ]. A number of surveys and studies of users have shown that many smokers succeed in quitting smoking with the use of ECs, while randomized controlled trials have shown modest health benefits [ ]. According to Farsalinos and co-authors [ ], an estimated 48.5 million people have used ECs in all member states of the EU. Existing evidence indicates that EC use is a far less harmful alternative to smoking [ ]. Nevertheless, the latest studies report somewhat harmful levels of toxic chemicals in heated tobacco products/ e-cigarettes [ , ] and similar adverse events [ ], as well as a higher level of addiction to e-cigarettes when compared to traditional cigarettes [ ]. There is no tobacco and no combustion involved in EC use though; therefore, regular vapers may avoid several harmful toxic chemicals that are typically present in the smoke of tobacco cigarettes. Indeed, some toxic chemicals are released in the EC vapour as well, but their levels are substantially lower compared with tobacco smoke [ ], and in some cases (such as nitrosamines) are comparable to the amounts found in pharmaceutical nicotine products [ ].

There is ongoing debate within the public health community as to whether ECs have a potential role in smoking cessation [ , ]; whether use of ECs can reduce harm for individual users; whether widespread use of the devices has the potential to reduce or increase population-level harm; and how to best regulate ECs to minimize both individual and population-level harm [ ]. Producing nicotine aerosol from a solution, rather than burning tobacco, gives rise to fewer harmful substances than cigarette smoke for both users and non-users [ ], but the long-term effects of ECs use are still under investigation. Because the health risks associated with vaping are likely to be smaller, some experts advocate wider availability and softer regulation, and consider ECs to have great potential in helping smokers quit or switch to a harm-reducing way of consuming nicotine [ , ]. Others call for application of the ‘precautionary principle’ in public health, and argue that it is not consistent with public health policy to allow ECs into the market, until robust evidence supporting the safety of ECs and their efficacy in reducing harm would be available [ , ]. They cite the addictiveness of nicotine and the potential for harm from ongoing use of ECs, compared with complete cessation of all nicotine and tobacco products [ ]. There are also concerns that ECs will be used in combination with tobacco products, or that ex-smokers will re-initiate their nicotine addiction or return to smoking [ , ], particularly if exposed to EC advertising that may be perceived as being glamorous [ ]. Other serious issues include the possibilities that ECs might promote nicotine use among non-smokers, especially children; serve to renormalize smoking; or serve as a gateway to the use of combustible cigarettes or illicit drugs [ , , ].

4

Smoking and health hazards

As previously mentioned, the global tobacco epidemic is a major issue [ ]. To sum up, smoking increases the risk of various types of cancer (mainly lung cancer), and cardiovascular and respiratory diseases, reduces fertility and is associated with increased levels of stroke, deafness, blindness, osteoporosis, back pain and peripheral vascular disease. Furthermore, smokers die about 10 years younger than non-smokers, on average [ ].

5

Smoking and ocular conditions

Research data suggest that active and passive smoking are both risk factors for many ophthalmological disorders, such as development of dry eye, anterior ischemic optic neuropathy, age related macular degeneration (AMD), cataract, thyroid ophthalmopathy, open angle glaucoma, diabetic retinopathy or even blindness; furthermore, strabismus in the offspring of pregnant smokers has been reported [ , , ]. Although these conditions can be triggered by other reasons, smoking is considered an important factor and its effects are dose-related [ , ]. However, the public awareness of the relationship between smoking and eye diseases, some of which may even result in blindness, is lower than other smoking related diseases [ ].

6

Smoking and contact lens wear

Epidemiological studies that have examined the links between contact lens wear and smoking, suggest that there is a higher risk of ocular irritation among smokers [ ]. More important is the relationship between smoking and corneal infection (microbial keratitis) which is the major concern amongst contact lens practitioners [ , ]

Microbial keratitis incidence for contact lens wearers is low but consistent over the years [ ]. The disease can vary significantly in severity [ ] and can ultimately lead to blindness via corneal opacification [ ] or even endophtalmitis and enuclation. Zapp et al. in their work report a 7.2 % development of endophtalmitis after microbial keratitis in their subjects; additionally, when they studied the severe microbial keratitis cases in the hospital, they found a lower transformation rate of 0.29 % from microbial keratitis to endophtalmitis overall (11 out of 3773 cases) [ ]. Despite its severity, microbial keratitis, if diagnosed and treated early, can result in no long-term effects of corneal integrity [ ].

Contact lens wearers who are smokers show approximately a 3x higher risk of microbial keratitis and 4x higher risk of corneal infiltrates [ , ]. These studies suggest the excess risk is mainly due to behavioral issues, or poor hygiene among contact lens weares and smokers.

Another point of view suggests that lipopolysaccharides that contaminate tobacco smoke can easily travel from tobacco to smokers hands and then the contact lens and consequently reach the eye. There, they may initiate an immune response, in a similar way that they induce proliferative changes in the airway of smokers [ ].

As mentioned above, smoking may be associated with dry eye [ , , ] and of course, soft contact lens wear is itself a risk factor for dry eye disease [ ]. Dissociating these relationships is problematic because reports exploring links between both contact lens wear and smoking and dry eye disease in the same subjects are limited. In a study performed in 2010 in Japan, Ward et al. reported significantly worse tear evaporation rates, tear break up times and corneal staining in soft contact lens wearers versus non-wearers, when they were passively exposed to only five minutes of cigarette smoke [ ]. Tityal et al. in a multivariate analysis on risk factors for dry eye disease, correlate smoking and contact lens usage and report “increased odds of developing severe DED (P < 0.001)” among smokers [ ]. On the contrary, Lee et al. in 2012 reported a lack of association when studying dry eye severity under smoking and/or contact lens wearing conditions [ ].

7

ECs and health hazards

Reports of fires and burn injuries, ascribed mainly to EC battery explosions, are growing in numbers, probably due to the fact that the popularity and use of ECs has increased worldwide [ ]. In the UK, about 113 fires caused by e-cigarettes over a three-year period (2013–2015), have been reported, while there have been over 16,000 smoking related fires over the same period. These reports indicate that, while ECs do cause combustive problems, these events are quite rare relative to those associated with smoking. Nevertheless, in US hospital emergency departments, between 2015 and 2017, an analysis of ECs explosion and burn injuries concluded that past reports appeared to have significantly underestimated the actual numbers of events. As those with less severe injuries may not present in emergency departments, the true number of cases is likely to exceed these primary estimates [ ].

Regarding the site of burn injuries associated with EC batteries, it was found that the lower extremities and hands were most frequently involved. Nearly 50 % of the reported incidents required surgical management as a result of the depth of injury [ ]. Many of the EC related burn injuries presenting to US emergency departments in 2016 occurred to the upper leg/lower trunk and were as a result of devices being carried in users’ pockets [ ]. There have also been case reports of EC explosions causing fractures [ ] and ocular injuries [ , ].

Although ECs manufacturers have tried to attribute blame for explosions to the user for charging the devices improperly, a 2017 report from the US Fire Administration found that only 25 % of explosions occurred during the charging process [ ]. Sixty-two per cent of the devices exploded when being carried in a pocket or being actively in use. Etiologically, these accidents seem to be related to the shape and construction of ECs, wherein the lithium-ion battery is installed in a cylindrical tube. Internal pressure, generated by battery failures, forces the battery out of the tube at the weakest points, which are at either end [ ]. As a consequence, it would be prudent to avoid ECs powered by lithium-ion batteries.

8

ECs vaping and ocular conditions

Current knowledge about ECs and related “harm reduction” products is very limited and the long-term effects are yet to be established. However, there are some early indications that ECs can cause irritation to the eyes in the form of dry eye, cataract or other ocular irritation. Yet, there are still many factors that require rationalization and serious consideration before firm conclusions can be drawn in relation to these products.

9

Conclusion

This work has reviewed the relationships between traditional and new ways of nicotine uptake and a range of ophthalmic diseases. The relationship between smoking and dry eye disease remains unproven [ ] although stronger relationships are evident for cataract, AMD, glaucoma and Graves’ ophthalmopathy. A detailed causal pathway between smoking and any of these diseases has yet to be established however.

Smoking is strongly associated with higher risks of microbial keratitis and corneal infiltrates in contact lens wearers. Independently, smoking is associated with ocular irritation in contact lens wear and so, potentially, smoking and contact lens wear combined may increase the risk of ocular irritation. This hypothesis requires further investigation.

Vaping is a recently introduced method of nicotine delivery. As such, research is actively being pursued on its safety and impact on human health. As there is no tobacco in ECs, unquestionably the harmful toxic chemicals of traditional cigarette smoking are avoided. Whether there are residual effects of EC vapour inhalation remains to be seen, however. Up to the present time, vaping has been correlated with dry eye in only one report [ ] and with general eye irritation in two [ , ]. Vaping and cataract are possibly correlated, hypothetically due to the toxic compounds found in EC vapour, but a clear, causal route has yet to be reported. Some evidence exists connecting vaping with AMD, glaucoma, Graves’ ophthalmopathy and contact lens related complications but the literature relating to health problems in general, and ocular conditions in particular, is currently limited. Otherwise, the human hazard posed by EC use is mainly that of burns, due to battery overheating.

Funding

This research did not receive any specific grant from funding agencies in the public, commercial, or not-for-profit sectors.