But we’re only human: Heroic Olympians no exception to air pollution health effects (2)

Previously, we explored the potential effects of air pollution on Olympic athletes’ respiratory health through studying two key pollutants: ozone and particulate matter. While we might now know the health risks that these athletes face, this then begets the question of whether they can be trained to adapt to these risks and maintain their sporting standards.

Achieving this is possible, at least in theory. As argued by Mullins (2018), athletes with recent exposure to high ozone levels experience the acclimatisation effect, where they develop weaker respiratory complications in high-ozone environments. This corresponds with Sandford, Stellingwerff and Koehle’s (2020) findings that endurance runners from high-ozone environments display more consistent performance as they have become desensitised to irritant exposure. Such phenomena thus suggest that to minimise respiratory irritation and optimise performance, athletes can engage in short ozone adaptation training sessions to pre-acclimatise themselves. While this is inapplicable to particulate matter as there is no identifiable threshold below which respiratory illnesses do not develop, particulate matter exposure is harmless unless it exceeds the guideline value of 15 micrograms per cubic metre (World Health Organisation, 2021).

Figure 1: An infographic outlining how Olympic athletes should train for competitions in high-ozone environments (Sandford, Stellingwerff and Koehle, 2020)

Nevertheless, such adaptation strategies have proven ineffective as they jeopardise the health of high-risk athletes, specifically those with asthma. As reported by Burns et al. (2015), asthma is a chronic respiratory disorder that affects approximately 10% of athletes, and mostly those in endurance sports due to vigorous respiratory activity. It is precisely this correlation between sports intensity and asthma occurrence that explains why — despite the well-established nature of asthma treatment methods — pollution adaptation is not a foolproof solution. While adaptation training sessions admittedly require lower sports intensity than actual competitions in consideration of athlete safety exposure (Sandford, Stellingwerff and Koehle, 2020), they also involve longer training periods to facilitate the stabilisation of inflammatory symptoms. This is highly unsafe for asthmatic endurance athletes, as prolonged exposure to pollutants — even in small amounts — can exacerbate exercise-induced bronchospasms (Braniš and Vetvicka, 2010) and strain the lungs. Consequently, this increases the severity of asthma attacks, making it difficult for athletes to train and eventually compete properly.   

In fact, these concerns turned into reality during the 1984 Los Angeles Olympic Games, when top British track athlete Steve Ovett collapsed from pollution-induced asthma during the 800 metre finals. Despite Ovett’s ozone exposure in Britain, where heavy coal use for industrial activity sparked record-high ozone levels (National Atmospheric Emission Inventory, 2010), the pre-acclimatisation effect was not observed as the severe buildup of smog in Los Angeles (Elsom, 2016) significantly increased aerobic demand. This, coupled with the high level of sports intensity required for short-distance sprinting, resulted in severe bronchospasms that triggered Ovett’s asthma.    

British elite runner Steve Ovett (first from left) competing at the 1984 Los Angeles Olympic Games, moments before he collapsed from a pollution-induced asthma attack (Walters, 2012)

While Ovett eventually recovered and went on to compete at other mega sports events, many Olympic athletes remain fearful of pollution-induced health hazards, with some nearly dropping out of the Olympic Games. This reinforces the critical need for host cities to manage air pollution during the Olympic Games, so that athletes can compete without fear of health complications and even break Olympic records. After all, as Elsom (2016) warns, athletes cannot perform their best under polluted conditions, no matter how comprehensive their adaptation strategies are.

References

Braniš, M., & Vetvicka, J. (2010). PM10, ambient temperature and relative humidity during the XXIX Summer Olympic Games in Beijing: were the athletes at risk?. Aerosol and Air Quality Research, 10(2), 102-110. https://doi.org/10.4209/aaqr.2009.09.0055   

Burns, J., Mason, C., Mueller, N., Ohlander, J., Zock, J. P., Drobnic, F., … & European Community Respiratory Health Survey. (2015). Asthma prevalence in Olympic summer athletes and the general population: an analysis of three European countries. Respiratory Medicine, 109(7), 813-820. https://doi.org/10.1016/j.rmed.2015.05.002 

Elsom, D. (2016, August). Los Angeles 1984: The Olympics under a cloud. Geographical. https://geographical.co.uk/places/cities/item/1855-los-angeles-1984-the-olympics-under-a-cloud 

Mullins, J. T. (2018). Ambient air pollution and human performance: Contemporaneous and acclimatization effects of ozone exposure on athletic performance. Health economics, 27(8), 1189-1200. https://doi.org/10.1002/hec.3667 

National Atmospheric Emission Inventory. (2010). UK Emissions of Air Pollutants 1970 to 2008. https://uk-air.defra.gov.uk/assets/documents/reports/cat07/1009030925_2008_Report_final270805.pdf 

Sandford, G. N., Stellingwerff, T., & Koehle, M. S. (2020). Ozone pollution: a ‘hidden’ environmental layer for athletes preparing for the Tokyo 2020 Olympic & Paralympics. British Journal of Sports Medicine, 55(4), 189-190. https://doi.org/10.1136/bjsports-2020-103360  

Walters, M. (2012, June 7). Coe v Ovett: A battle of Britain fought out behind the Iron Curtain. [Online image]. Mirror. https://www.mirror.co.uk/sport/other-sports/athletics/london-2012-looking-back-at-coe-865439 

World Health Organisation. (2021, September 22). Ambient (outdoor) air pollution. https://www.who.int/news-room/fact-sheets/detail/ambient-(outdoor)-air-quality-and-health

But we’re only human: Heroic Olympians no exception to air pollution health effects (1)

Picture this: you are the school’s cross-country representative, running around the track in preparation for the upcoming inter-school championships. You typically enjoy running; it leaves your senses feeling refreshed. Yet you find yourself dreading today’s run. Acrid smoke fills the air, with every breath feeling like a punch to the airways. Dust and fine particles enter your eyes, clouding up your vision. You want to speed up, but your suffocating lungs are crying out for rest. Running has never felt so difficult.

The above scenario may seem far-fetched, but it depicts the reality of many Olympic athletes who struggle to perform amidst polluted conditions in host cities. As you might recall, city-level air pollution is caused by high levels of road traffic stemming from short-term surges in tourist numbers (Gruben, Moss and Moss, 2012). Specifically, ozone and particulate matter are mainly emitted, altering the chemical composition of surrounding air which not only causes atmospheric change, but also worsens air quality. It is precisely the latter that poses health risks to athletes, hence inhibiting their potential to break Olympic records.

Athletes face risks of breathing problems and worsened performance when competing in polluted host cities (Owton, 2015).

While mostly studied for its radiation-trapping abilities, ozone remains notorious for causing respiratory irritation. The United States Environmental Protection Agency (EPA, 2021a) has found that ozone inhalation results in the constriction of airway muscles, subsequently inflaming the airways and causing breathing difficulties. Similarly, Lippi, Guidi and Maffulli (2008) report that ozone intake reduces expiratory volume, leading to constrained exhalation and wheezing. The most alarming discovery, however, is that these effects are strongest in the afternoon when endurance sports competitions are mostly held, thus putting athletes at risk. As ozone is formed when nitrogen oxides and hydrocarbons react under ultraviolet radiation, ozone levels peak at midday when ultraviolet radiation levels are highest (Sandford, Stellingwerff and Koehle, 2020). This increases the severity of respiratory symptoms, thus making it difficult for endurance athletes to perform as endurance sports require high aerobic demand.

Endurance sports athletes are particularly susceptible to respiratory irritation, given their high exposure to ozone at midday when competitions are held (Woodward, 2021)

Similarly, particulate matter — which refers to inhalable solid particles suspended in the air (EPA, 2021b) — can impair respiratory functions and athletes’ long-term physical abilities if overly inhaled. Particulate matter combines with sulfur dioxide and water vapour, which are gases also emitted by fuel-consuming vehicles, forming acid-coated particles that deposit in athletes’ lungs and cause irritation (Lippi, Guidi and Maffulli, 2008). Under prolonged inhalation, such inflammation can extend to other nerve tissues (Van Hee, 2012), eventually threatening athletes’ coordination and agility. 

Given the sheer potency of these pollutants, it is thus unsurprising that even elite athletes have fallen victim to air pollution-induced health effects. The next post will explore the ineffectiveness of pollution adaptation measures and case studies of athletes whose performance has been hindered due to respiratory complications, so stay tuned!

References

Gruben, K. H., Moss, S. E., & Moss, J. (2012). Do the Olympics create sustained increases in international tourism?. Journal of International Business Research, 11(1), 135-150. 

Lippi, G., Guidi, G. C., & Maffulli, N. (2008). Air pollution and sports performance in Beijing. International journal of sports medicine, 29(8), 696-698. https://doi.org/10.1055/s-2008-1038684 

Owton, H. (2015, September 8). Polluted host cities are putting our champion athletes at risk [Online image]. The Conversation. https://theconversation.com/polluted-host-cities-are-putting-our-champion-athletes-at-risk-46830 

Sandford, G. N., Stellingwerff, T., & Koehle, M. S. (2020). Ozone pollution: a ‘hidden’ environmental layer for athletes preparing for the Tokyo 2020 Olympic & Paralympics. British Journal of Sports Medicine, 55(4), 189-190. https://doi.org/10.1136/bjsports-2020-103360  

United States Environmental Protection Agency (2021, May 5). Health Effects of Ozone Pollution. https://www.epa.gov/ground-level-ozone-pollution/health-effects-ozone-pollution#:~:text=Ozone%20can%20cause%20the%20muscles,and%20sore%20or%20scratchy%20throat 

United States Environmental Protection Agency (2021, May 26). Particulate Matter (PM) Basics. https://www.epa.gov/pm-pollution/particulate-matter-pm-basics#:~:text=PM%20stands%20for%20particulate%20matter,seen%20with%20the%20naked%20eye 

Van Hee, V. C. (2012). From Olympians to mere mortals: the indiscriminate, global challenges of air pollution. American journal of respiratory and critical care medicine, 186(11), 1076-1077. https://doi.org/10.1164/rccm.201209-1594ED 

Woodward, A. (2021, August 12). Runners wearing Nike ‘super shoes’ dominated in the Olympics, taking more than 60% of podium spots [Online image]. Business Insider. https://www.businessinsider.com/nike-runners-trounce-olympics-competitors-super-spike-shoe-technology-2021-8 

Steering towards environmental disaster: Transport-induced air pollution at the Olympic Games

“It is the things you cannot see coming that are strong enough to kill you,” award-winning author Jodi Picoult had once said. This could not be further from the truth for air pollution, which is one of the least visible but most harmful types of pollution. Not only are key pollutants such as nitrogen dioxide and particulate matter highly toxic (Bonsu et al., 2020), they are also widely embedded in modern life.


Air pollution is omnipresent in various aspects of urban lifestyles, particularly transport (Organisation for Economic Co-operation and Development, 2014)

It is thus unsurprising that the Olympic Games — being a mega event involving the large-scale consolidation of urban activity from transportation to construction — significantly generates air pollution. While exact statistics remain uncertain as mentioned previously, the presence of smoggy skies and high respiratory infection rates suggest that air pollution at the Olympic Games is a clear cause for concern. It is hence instrumental to identify the biggest underlying triggers, so that authorities can work towards mitigating their impacts.

One of such triggers is transport, which facilitates the movement of those involved in the Olympic Games at different spatial scales. At the global scale, air transport is used to transport athletes and spectators from their home countries to the host city. While this transport mode is efficient given its relatively high speed and load capacity, enabling the large-scale transnational movement of people, it is also highly pollutive. Commercial aircraft emit significant amounts of nitrogen dioxide when flying in the free troposphere, forming the greenhouse gas ozone which traps outgoing solar radiation at the ground level (Colvile et al., 2001). Carbon dioxide, a pollutant which is produced during fuel combustion for aircraft engines, exacerbates such warming by absorbing outgoing infrared radiation (Colvile et al., 2001). While air travel at the Olympic Games only generates 65000 tons of carbon dioxide, constituting barely one month’s worth of emissions from a coal plant (Jacobo, 2021), its environmental and health-related impacts remain worrying as these pollutants have long residence times.

The emission of nitrogen dioxide by aeroplanes in the free troposphere exacerbates the greenhouse effect (Hotten, 2019)

Land transport at the city scale is equally, if not more, pollutive. During the Olympic Games, road traffic is remarkably high, not only because of the need for vehicles to transport athletes and staff to Olympic venues, but also the surge in tourists travelling there. This produces substantial vehicle emissions which not only contain radiation-trapping ozone, but also particulate matter that jeopardises air quality and causes respiratory illnesses when overly inhaled (He, Fan and Zhou, 2016).

It is hence crucial to be mindful of the significant role that transport plays in causing air pollution at the Olympic Games — only then can we foresee air pollution and its associated impacts, and take mitigation measures. Otherwise, we will be literally and figuratively steering towards environmental disaster.

References

Bonsu, N. O., Pope, F., Ababio, M. O., Appoh, E., Ashinyo, M. E., Essuman, S. N., Donkor, L. CS., & Thomson, I. (2020). How Coronavirus (COVID-19) has made the invisible silent killer of air pollution visible: lessons for building resilient communities. Biomedical Journal of Scientific & Technical Research, 28(1), 21219-21220. https://doi.org/10.26717/bjstr.2020.28.004587 

Colvile, R. N., Hutchinson, E. J., Mindell, J. S., & Warren, R. F. (2001). The transport sector as a source of air pollution. Atmospheric environment, 35(9), 1537-1565. https://doi.org/10.1016/s1352-2310(00)00551-3 

He, G., Fan, M., & Zhou, M. (2016). The effect of air pollution on mortality in China: Evidence from the 2008 Beijing Olympic Games. HKUST Institute for Emerging Market Studies Working Paper No. 2015-03. Available at: https://iems.ust.hk/publications/iems-working-papers/guojun-he-effect-air-pollution-mortality-china-olympic 

Hotten, R. (2019). Could aviation ever be less polluting? [Online image]. BBC. https://www.bbc.com/news/business-48185337 

Jacobo, J. (2021, August 2). How the Tokyo Olympics could affect climate change. ABC News. https://abcnews.go.com/International/tokyo-olympics-ban-spectators-affect-environment/story?id=78151177 

Organisation for Economic Co-operation and Development (2014). The Cost of Air Pollution [Online image]. Organisation for Economic Co-operation and Development. https://www.oecd.org/env/the-cost-of-air-pollution-9789264210448-en.htm