AIR POLLUTION, GREENHOUSE GASES AND HUMAN HEALTH

AIR POLLUTION, GREENHOUSE GASES AND HUMAN HEALTH Paul Wilkinson London School of Hygiene & Tropical Medicine Montreal, 23 November 2007 Deaths, London AC, 1-15 December 1952 Deaths 0 200 300 400 500 Deaths Black smoke 0 2 4 6 8 10 Smoke, County Hall, mg.m-3 30 Nov 52 05 Dec 52 10 Dec 52 15 Dec 52 1

Reduction, especially in industrial and domestic combustion sources, with substantial decline in particle (mass) concentration & SO 2 Change from classical to photochemical smog (transport sources) Emergence of new toxicological and epidemiological evidence, incl. - time-series - semi-ecological cohorts Identified risks at the (lower) ambient concentrations in modern cities Evidence strongest for respirable particles (<10μm), but also for SO 2, ozone, NO 2, CO HEALTH EFFECTS OF OUTDOOR AIR POLLUTION Patho-physiological/functional changes Inflammation of airways & lung Lung function Reduce lung growth Heart rate (variability), blood pressure Coagulation?Atherosclerosis, calcification of the arteries by ~60% Symptom/disease exacerbations (acute) Respiratory symptoms (asthma, COPD), cardiac (arrhythmia?) Thrombosis: myocardial infarction, stroke Hospitalization (cardio-respiratory) Death (cardio-respiratory) Chronic disease Chronic obstructive pulmonary disease, asthma Lung Cancer Reduced life expectancy 2

Estimated PM 10 Concentration in World Cities (pop >=,000) PM 10 (µg/m 3 ). 5-14. 15-29. 30-59. 60-99. -254 Source: Cohen AJ et al. 2004 Excess deaths from selected environmental factors Environmental risk Unsafe water Urban outdoor pollution Indoor air Lead Global estimate 1,730,000 799,000 1,619,000 234,000 Asian estimate (S, SE Asia + W Pacific) 730.000 487,000 1,025,000 88,000 Asia as a percent of global 42% 65% 63% 37% 3

Fuel supply and cost Combustion of fossil fuels Other fuel sources Direct and indirect effects on health (1) (2) +ve Lifestyles -ve (3) (Access to) energy services: the home, transport, industry/commerce, agriculture Climate change Energy security (national, household) Primary energy consumption (EJ), Mauna Loa CO2 concentrations (ppmv) & CO2 emissions (x 10^7 tonnes of carbon) 0 200 300 400 500 600 700 // Pre-industrial CO 2 concentrations: 2 ppm Primary energy CO2 emissions Mauna Loa CO2 1900 1920 1940 1960 19 2000 Year 4

Projected change in global mean temperatures in selected IPCC scenarios. Lines beyond 2000 are multi-model global averages of surface warming, relative to 19 99, for SRES scenarios A2, A1B, and B1. Source: IPCC, 2007 CLIMATE CHANGE & HEALTH Moderating influences HEALTH EFFECTS CLIMATE CHANGE REGIONAL WEATHER CHANGES: -temperature/ heatwaves -extreme weather -precipitation Contamination pathways Transmission dynamics Crop production Air pollution levels Temperature-related illness, death Extreme weatherrelated health effects Air pollution-related health effects Allergies Water- and food borne diseases Vector-borne and rodent-borne dis. Malnutrition Based on Patz et al. 2000 Adaptation measures 5

MORTALITY: ENGLAND AND WALES CVD RESPIRATORY MORTALITY AS PERCENT OF ANNUAL AVERAGE CVD MEAN TEMPERATURE TODAY RESPIRATORY MEAN TEMPERATURE OF LAST WEEK Time lag of temperature-related mortality London: Cold=>19% deaths Heat=>0.6% deaths 0.000 Lag 27.000 1.173 RR 0.987-6.000 Temperature 29.000 6

Daily mortality in relation to mean temperature during preceding two days Mortality (% of annual average) LJUBLJANA -10 0 10 20 30 40 MONTERREY -10 0 10 20 30 40 SALVADOR -10 0 10 20 30 40 BUCHAREST -10 0 10 20 3040 MEXICO -10 0 10 20 3040 SAO PAULO -10 0 10 20 3040 SOFIA -10 0 10 20 3040 CHIANGMAI -10 0 10 20 3040 SANTIAGO -10 0 10 20 3040 Mean daily temperature in degrees Celsius DELHI -10 0 10 20 30 40 BANGKOK -10 0 10 20 30 40 CAPE TOWN -10 0 10 20 30 40 Daily count 0 50 150 CV DEAT HS, MAX. DAILY TEMPERATURE & OZONE, 2003 Ozone Temperature Deaths 01jan2003 01apr2003 01jul2003 01oct2 003 01jan2004 Date - -50 0 50 o3 7

Deaths per day 150 200 250 300 DEATHS, LONDON, 2001-2003 0 10 20 30 Mean temperature / Celsius Total excess deaths (risk x freq) 0 200 300 400 500 600 TEMPERATURE-RELATED DEATHS, LONDON, 2001-2003 0 25 50 75 125 150 Frequency / Predicted excess deaths a day 0 5 10 15 20 25 30 Mean temperature / Celsius 8

FLOODING: EAST ANGLIA & SOUTH EAST ENGLAND, 31 JAN - 1 FEB 1953 Wind force 10, gusts > 50 m/s Storm surge 2.6 m (King s Lynn 3 m) Waves > 4.9 m on top of high tide 0 miles of coastline, Spurn Head - Kent 0 breaches 307 deaths (1,795 in Holland) 32,000 evacuated Many people drowned 65 Dead > 40 dead 58 dead 36 dead London VECTOR-BORNE DISEASE (per day) Biting frequency 0.3 0.2 0.1 0 10 15 20 25 30 35 40 Temp ( C) Mosquito (per day) Survival probability 1 0.8 0.6 0.4 0.2 0 10 15 20 25 30 35 40 Temp ( C) (days) Parasite Incubation period 50 40 30 20 10 0 15 20 25 30 35 40 Temp ( C) TRANSMISSION POTENTIAL 1 0.8 0.6 0.4 0.2 0 14 17 20 23 26 29 32 35 38 41 Temperature ( C) 9

PREDICTED CHANGE IN MONTHS PER YEAR OF FALCIPARUM MALARIA TRANSMISSION BY 20 Difference in months of transmission 20s and baseline >+1 month +1 month -1 month <-1 month From Martens et al. 1999 [Climate change scenario developed by the UK Hadley Centre] If we could be absolutely sure that nothing more drastic than linear changes in the climate could occur, it would be reassuring. The small chance of something really catastrophic is more worrying than the greater chance of less extreme events [which] could negate decades of economic and social advance Rees, M. Our final century. London: Arrow Books. 2004 Reversal of carbon sinks (Amazon); deep ocean circulations; gas hydrates (clathrates); other Beware the Paleocene-Eocene Thermal Maximum! 10

Paleo-climate & CO 2 record, Vostock ice cores, Antarctica Temperature (degrees Celsius) relative to today -10-5 0 5 10-400 -350-300 -250-200 -150 - -50 0 Thousands of years relative to present Hoped for stabilization (CO 2 equivalent) Current CO 2 equivalent Current CO 2 Pre-industrial CO 2 150 200 250 300 350 400 450 500 550 CO 2 concentrations, ppmv THE CHALLENGE Limiting of global impact Reduction in GHG emissions by ~90% in high income countries by mid century Major shift towards low emissions energy (electricity from renewables, electricity or H2 as energy carriers for transport ) Behavioural change: active transport 11

BENEFITS TO HEALTH Mitigation of health effects of climate change Co-benefits Reduced ambient air pollution Built environment: protection against low and high temperatures Active transport: physical activity, obesity, road injuries Quality of urban environment AIR POLLUTION IMPACTS VS CO 2 EMISSIONS Deaths from air pollution and accidents/twh 0 10 20 30 40 A lignite coal oil biomass gas nuclear 0 500 0 1500 Cases of serious illness from air pollution /TWh 0 200 300 B lignite coal oil biomass gas nuclear 0 500 0 1500 Equivalent CO 2 emissions g/kw.hr -1 12

Ratio of winter:non-winter deaths 1 1.2 1.4 1.6 RATIO OF WINTER:NON-WINTER DEATHS Relationship between winter- and cold-related mortality and standardized indoor temperature <14.8 14.8-16.6-18.7-19.4- Percent increase in death / degree Celsius -2.5 0 2.5 5 PERCENT INCREASE IN DEATHS PER DEGREE CELSIUS FALL IN OUTDOOR TEMPERATURE <14.8 14.8-16.6-18.7-19.4- Mortality Cold slope flattens with warmer homes Outdoor temperature Standardized indoor temperature / degrees Celsius 13

PM 10 concentration (μg m -3 ) URBAN AIR POLLUTION AIR POLLUTION SOURCES IN LONDON: SOUTH-NORTH TRANSECT 65 60 55 50 45 40 35 30 25 20 15 10 5 IRR Charing Cross New Oxford Street - CD3 IRR Bloomsbury 0 177000 1700 179000 1000 1 182000 183000 184000 Northing (m) local (mainly transport) emissions sources urban area sources (within London) long-range transport Sources of pollution: transect of central London (modelled) URBAN INTERVENTIONS Urban layout, building design and renovation, transport system changes Combined technology and behaviour change Switch to cleaner energy carriers (electricity, hydrogen?) Modelling change in PM 10 in London 14

Hypothetical impact on pollutant emissions, concentrations and years of life gained Baseline Scenario 1 Scenario 2 Scenario 3 Scenario 4 Description Business as usual Bus fleet +20% of cars to H 2 * or electric 40% lower building emissions Half journeys <10km by walking/ cycling (50%) or publ trans Combined Emissions difference $ (%) PM NO x CO 2 (tonnes/yr) (3564) (78994) (39.5x10 6) -4.5% -7.9% -5.3% -3.1-11.6-15.1-3.4% -1.5% -2.2% -10.6% -20.8% -22.1% Change in concentrations PM 10 NO 2 (μg.m-3) (23.7) (36.8) -0.4% -4.6% -0.4% -7.0% -0.4% -0.5% -1.3% -12.0% Gain in life years over 10 yrs: PM 10 Total YLG YLG per,000 pop NO 2 Total YLG YLG per,000 pop (baseline) 2527 35 26445 366 1389 19 38223 529 1736 24 3970 55 5532 77 68834 953 * -- assumed to be hydrogen fuel cell $ -- difference from baseline ACTIVE TRANSPORT : HEALTH GAINS For an average car driving women 35-44 years 15 g fat tissue per day 5.6 kg fat tissue per year Decrease 20 40% in risk of premature mortality 25% in breast cancer risk >20% all cancer risk >30% diabetes mellitus 15

CONCLUSIONS Air pollution and climate changed are linked by society s dependence on fossil fuels The magnitude of the climate change challenge demands major and rapid reduction in greenhouse gas emissions Technology alone is an insufficient solution; altered behaviours are needed and often beneficial Measures to achieve GHG reduction targets would be expected to yield appreciable benefits to public health CONTACT DETAILS Paul Wilkinson Public & Environmental Health Research Unit London School of Hygiene & Tropical Medicine Keppel Street London WC1E 7HT paul.wilkinson@lshtm.ac.uk Tel: +44 (0)20 7927 2444 16