Abstract
Over half the world’s population, mostly from developing countries, use solid fuel for domestic purposes and are exposed to very high concentrations of harmful air pollutants with potential health effects such as respiratory problems, cardiovascular problems, infant mortality and ocular problems. The evidence also suggests that, although the total percentage of people using solid fuel is decreasing, the absolute number is currently increasing. Exposure to smoke from solid fuel burning increases the risk of chronic obstructive pulmonary disease (COPD) and lung cancer in adults, and acute lower respiratory tract infection/pneumonia in children. Despite the heterogeneity among studies, the association between COPD and exposure to smoke produced by burning different types of solid fuel is consistent. However, there is strong evidence that while coal burning is a risk factor for lung cancer, exposure to other biomass fuel smoke is less so. There is some evidence that reduction of smoke exposure using improved cooking stoves reduces the risk of COPD and, possibly, acute lower respiratory infection in children, so approaches to reduce biomass smoke exposure are likely to result in reductions in the global burden of respiratory disease.
The main activities that contribute significantly to indoor air pollution in low- and middle-income countries are the use of solid fuels for residential energy, active and passive smoking inside the house, oil mists and fumes from cooking, smoke from burning mosquito coils during the summer and incense sticks during religious rituals, and keeping pets and animals in the same dwelling where the individuals live.
Globally, >3 billion people, approximately half of the world’s population, rely on the use of biomass (wood, crop residues, twigs, shrubs, dried dung and charcoal) and coal, collectively known as solid fuels, to meet their basic domestic energy demands for cooking, lighting and heating [1, 2]. The proportion is even more staggering in rural parts of Africa, Central and South America, and Asia, being >90% [3]. The majority of the solid fuels are burnt in inefficient traditional cooking stoves located in places without adequate ventilation, although in sub-Saharan Africa, burning in the open environment is not uncommon [4, 5]. A large variety of harmful substances are released during combustion of solid fuels and remain in the indoor environment at very high levels for a number of hours after cooking and heating has stopped, because of the lack of adequate room ventilation. Most people spend ∼90% of their time indoors, even more in the case of females, children, elderly and those with ill health. Cooking in developing countries is often done by females; and mothers tend to keep their young children, especially infants and toddlers, close by during cooking, therefore placing females and children at risk of both acute and long-term ill health from emissions of solid fuel combustion. The degree of risk is related to the levels of exposure, which, in turn, are determined by a number of factors. For instance, kitchen type and the design of living areas in dwellings in developing countries can increase exposure to indoor air pollutants several-fold through natural (but inadequate) ventilation and lack of flues [6, 7]. Seasonality is also important, as exposures to indoor air pollutants during the winter are several times higher than the rest of the year, as people spend more time gathering around fires to keep warm.
USE OF SOLID FUEL AS HOUSEHOLD ENERGY
Based on the classification by the United Nations Development Programme, there are 140 developing countries, of which 50 are the least developed countries and 45 are sub-Saharan Africa countries. 31 countries belong to both the least developed countries and sub-Saharan Africa categories. Access to clean energy (e.g. electricity and natural gas) is low in developing countries, but the situation is even worse in the least developed countries and in Sub-Saharan Africa (fig. 1), where 82% and 89% of the populations, respectively, rely primarily on solid fuels for domestic purposes, compared with 56% in developing countries [8]. Variation also exists within these countries. In the least developed countries, as much as 97% of the rural population have access only to solid fuels, compared with 73% among urban dwellers. The difference is even more marked in sub-Saharan Africa (95% versus 58%) [8]. Most of the solid fuel users do not limit themselves to a single type of fuel but rather combinations of different types depending upon availability. Worldwide, wood is the most common biomass used, although coal is predominantly used in China while dried cow dung is used by a smaller fraction of the rural South Asian populations.
Trends in biomass fuel use
Although the total population relying primarily on the use of biomass as residential energy will increase from 2.68 billion in 2009 to ∼2.77 billion in 2015, and probably remain at that level until 2030 [9], the proportion of the total population from developing countries will decrease from 54% in 2009 to 51% in 2015, with further reductions to 44% in 2030. In China, the population relying on biomass fuel is readily on the decline and is estimated to fall to 19% by 2030. It is anticipated that this trend will be followed by India after 2020 [9] such that by 2030, just 54% of the Indian population and 52% of other Asian countries will be using traditional biomass fuels. Increase in the price of kerosene and bottled gas in the developing countries is one of the main reasons for this slower transition to cleaner fuels. However, the pace of decline in sub-Saharan Africa will be much lower compared with other developing countries.
Factors preventing the use of clean fuel
The influence on the choice of fuel used is multifactorial, but cost and socioeconomic status appear to be the main drivers (fig. 2). Less well-off households spend most of their income purchasing food and clothes and for medical expenses. Depending upon the availability of biomass fuels and the distance required to travel to acquire these fuels, those living in the least developed countries can spend, on average, 2–3 h per week collecting biomass, leaving little or insufficient time for education [2] and work, thus making it very difficult for these families to improve their socioeconomic status. In rural areas of developing countries, poor families often receive subsidies on clean fuels. However, many switch back to biomass when they cannot afford even the subsidised fuel, making them reliant on the cheaper but dirtier alternatives. The other important factor is the inavailability of clean fuels in rural areas, because of the lack of a sustainable supply-chain mechanism and/or the necessary infrastructure to deliver clean fuels. Consequently, clean fuel is not available at all or the demand for clean fuel cannot be met consistently, forcing rural dwellers to continue their dependence on biomass fuels.
Characteristics and toxicity of solid fuel use
Traditional stoves burning solid fuels have a very low energy conversion efficiency ranging from 12% to 25% depending upon the types of fuels (fig. 2). Approximately 8–10% of the solid fuels undergo partial combustion, often due to inadequate oxygen supply [10]. As a result, one of the main components of biomass smoke is carbon (5–20% of wood smoke as particulate mass), which is found in the particulate fraction of the smoke and is present across a range of particle sizes. Biomass smoke also contains >250 organic compounds, varying mainly by the type of fuel burnt and the combustion conditions [11]. Partial oxidation of organic matter generates high levels of carbon monoxide, as well as hydrogen cyanide, ammonia and nitrogen oxides. In addition, a large number of other toxic and carcinogenic compounds, such as polycyclic aromatic hydrocarbons (PAHs) (e.g. benzo[a]pyrene (BaP)), aldehydes and free radicals [11], have been demonstrated in biomass smoke. While biomass fuels tend to have low levels of halogenated compounds, they may be contaminated by chemicals such as pesticides, or mixed with plastics. Certain varieties of coal, particularly in China, have particularly high fluoride or silica content [12]. Consequently, burning of these specific fuels may lead to production of toxic halogen compounds, such as hydrogen chloride, phosgene, dioxin, chloromethane, bromomethane and other halocarbons [13–15].
The toxicity of biomass smoke has been studied extensively in the laboratory. Rats exposed subchronically to wood smoke at concentrations of 1–10 mg·m−3 over a period of weeks showed reduced carbon monoxide diffusing capacity and increased airway resistance. There were also mild chronic inflammation and squamous metaplasia in the larynx, alveolar macrophage hyperplasia, and slight thickening of the alveolar septa [16]. Wood smoke can cause greater levels of DNA damage in lymphocytes than exposure to liquefied petroleum gas combustion products [17], and can both impair macrophage function and be mutagenic [11].
Wood smoke condensates may damage the lens in rats, causing discolouration and opacities, probably through oxidation by polycyclic aromatic compounds and metal ions [18], while chemicals such as aldehydes and acrolein found in biomass smoke can cause eye irritation.
Biomass smoke is pro-oxidant and burning of biomass fuel may generate high levels of redox-active components. In one study from India, the oxidative potential of particulate matter (PM) from cow dung cake smoke was found to be increased using an in vitro technique involving a synthetic model of the respiratory tract lining fluid [19].
Inadequate combustion of biomass releases carbon monoxide that binds haemoglobin, producing carboxyhaemoglobin, due to the high affinity of haemoglobin for carbon monoxide (200–250 times) compared with oxygen [2]. Potentially, this can reduce oxygen transport to key organs and the developing fetus, which may result in low birth weight and perinatal death [20].
In humans, acute exposure to sulfur dioxide, which is often released during biomass burning, can increase bronchial reactivity in normal individuals and cause bronchoconstriction in asthmatic individuals at levels of ∼100 ppb. Longer term exposure may increase susceptibility to viral infections of the lung [21].
A few studies have looked at the toxicity of biomass smoke in exposed populations in developing countries. In chronically biomass smoke-exposed Indian females, activation of circulating platelets, neutrophils and monocytes has been reported with high levels of leukocyte–platelet aggregates [22]. As a number of studies on ambient air pollution suggest that particulate pollutants increase fibrinogen levels, thus enhancing blood coagulation [23], it is plausible that biomass smoke exposure could be a risk factor for cardiovascular events. There have been very few controlled biomass smoke-exposure studies in humans, but there is a suggestion that exposure at levels of ∼250 μg·m−3 are associated with an increase in circulating factor VIII and serum amyloid A, both of which confer an elevated cardiovascular risk [24].
The inherent toxicity of the smoke from biomass burning differs by the type of fuel, implying differential health risks conferred by different fuels. Airborne endotoxin concentrations in homes burning different types of biomass fuels in Nepal and Malawi [25] have been reported to be higher than those found in occupational settings [26, 27] and in the indoor environment in developed countries [28]. The median value of endotoxin (in endotoxin units (EU) per cubic metre) was greatest in households burning maize crop residue (1,609 EU·m−3) followed by cow dung (365 EU·m−3) and wood (113 EU·m−3), all values being much greater than 40 EU·m−3 [29], a health-based guidance limit recommended in the Netherlands for an 8-h time-weighted average occupational exposure.
Improved cooking stoves
The most effective way of eliminating exposure to smoke from solid fuels is to switch to cleaner fuels, such as electricity, but this option is not always feasible. The most realistic alternative would be to reduce the exposure levels by switching to more efficient, improved cooking stoves. Major projects to produce and disseminate improved cooking stoves in the developing world have been initiated in the last decade. The aims were two-fold. First, by reducing the levels of indoor air pollutants, it was hoped that the health burden would be reduced. Secondly, by improving burning efficiency, fuel use could be economised to help slow down deforestation and desertification. While there is no universal definition, generally speaking, all improved cooking stoves are characterised by a higher efficiency of thermal conversion, a higher heat transfer ratio and a more complete combustion (and therefore a lower emission of smoke and other pollutants) compared with their “traditional” counterparts. Tests (water boiling, kitchen performance and controlled cooking) have been developed and recommended to monitor the performance and efficiency of the improved cooking stoves. Improved cooking stoves can be classified on the basis of: 1) the types of fuel used (operable on single or multiple fuel types), 2) construction materials (made of a single or a combination of materials), 3) portability (fixed or portable) and 4) end-use applications (monofunction for cooking only, or multifunction for cooking, room heating, etc.) [30]. The choice of stove should be customised for the target users, taking into account local cooking requirements, and affordability and availability of fuels. Local availability of construction materials and maintenance are important criteria to long-term self-sustainable projects. In areas where improved cooking stoves are not available, certain modifications of the cooking environment and practices, such as improving ventilation, or even avoiding cooking indoors where possible, could be helpful in reducing the smoke exposure.
At present, ∼27% of the total population using solid fuels (or 38% of the population in developing countries) have access to improved cooking stoves: more than two-thirds (70%) in China, 9% in India and 4% in other south Asian countries. However, in sub-Saharan Africa and the least developed countries, the figures are as low as 5.8% and 6.6%, respectively [3].
Exposure monitoring
Particulate matter
PM is classified on the basis of its aerodynamic diameter (AD), which is a function of particle size, mass and shape. Most of the studies where actual biomass smoke exposures have been measured (as opposed to a simple exposed/unexposed classification) have reported exposures as PM10 (PM with AD <10 μm), although, more recently, PM2.5 (PM with AD <2.5 μm) has been used as a PM metric, reflecting the likelihood that greater toxicity resides in the smaller size fraction. PM can be measured either by gravimetric techniques or by photometric devices. Gravimetric techniques give an aggregate of exposure concentrations over a period of time but photometric techniques are gaining popularity as they measure real-time PM concentrations in a repeated manner, which provides information on the variation of particle concentration over time and in relation to different activities. The downside of this technique is that measurements need to be calibrated against gravimetric results in the environment, where exposure monitoring needs to be performed, as the light scattering method often tends to overestimate PM concentrations [31].
Previous work has shown 24-h indoor concentrations of PM10 generated from solid fuels in different settings to be in the range of 300–3,000 μg·m−3, with peaks reaching as high as 20,000 μg·m−3 during cooking [4, 32–35]. In a wood-using community in Nepal, the 24-h average PM2.5 was found to be 680 μg·m−3 (range 616–744 μg·m−3) [31], which is similar to other studies from Guatemala (22-h average 520 μg·m−3) [4] and China (24-h average 489 μg·m−3) [36]. All these reported concentrations are several-fold higher than the World Health Organization (WHO) global ambient air quality guidelines, which recommend that the 24-h and annual mean PM10 concentration should not exceed 50 and 20 μg·m−3, respectively, with PM2.5 not exceeding 25 and 10 μg·m−3, respectively [37]. These results are several-fold higher than results from the UK (12–34 μg·m−3 for PM10) [38] and USA (≤35 μg·m−3 for total suspended dust) [39].
Carbon monoxide
Carbon monoxide has been suggested as a cheaper but surrogate measure of indoor air pollution caused by burning biomass fuel. Carbon dioxide is measured by using either colour-changing diffusion tubes or electrochemical monitors. Diffusion tubes can only measure total exposure over time and the carbon monoxide concentration is indicated by the stain inside the tubes when in contact with carbon monoxide. More recently, small electrochemical devices (e.g. HOBO® Data Logger (Onset®, Cape Cod, MA, USA) and EL-USB-CO Data Logger (Lascar Electronics, Salisbury, UK)) have been used to measure carbon monoxide concentrations. These devices are cheaper, smaller and require less power to operate over extended time periods than diffusion tubes.
Bruce et al. [40] reported 24-h carbon monoxide concentration in homes using an improved stove of just over 3 ppm, compared with 12.4 ppm with open fires, while our own work in Nepal found broadly similar levels (18 ppm) but with substantial increases to around 200 ppm during cooking (unpublished observations), while results from Guatemala (average 5.9 ppm) were similar [4]. The concentration of carbon monoxide will depend upon the efficiency of fuel combustion and the moisture content of the fuel [41], wet wood fuel generates more smoke, and thus more carbon monoxide, due to incomplete oxidation of the carbon content. WHO recommended time-weighted average guidelines for carbon monoxide are 87 ppm (100 mg·m−3) for 15 min, 52 ppm (60 mg·m−3) for 30 min, 26 ppm (30 mg·m−3) for 1 h and 9 ppm (10 mg·m−3) for 8 h [42].
HEALTH EFFECTS FROM EXPOSURE TO SOLID FUEL SMOKE
It is estimated that 1.9 million people die prematurely due to exposure to smoke from solid fuel burning [43]. According to WHO, exposure to smoke from solid fuel burning is ranked as the top environmental risk factor worldwide, being responsible for 3.3% of all mortality and 2.7% of all disability-adjusted life-years per year [44]. Long-term exposure to solid fuel smoke is clearly associated with chronic obstructive pulmonary disease (COPD), increased risk of acute respiratory infections/pneumonia, lung cancer, tuberculosis (TB) and cataracts [45–51]. The evidence is weaker for end-points such as asthma, adverse pregnancy outcomes, cancer of the upper aerodigestive tract, interstitial lung disease and ischaemic heart disease. More research, both from animal and human studies, is needed to establish the causal association between these health effects and exposure to biomass smoke. Some of the health effects associated with solid-fuel smoke exposure are acute, and include oxygen desaturation [52] and acute lower respiratory infection (ALRI)/pneumonia [53].
Here we discuss in detail the respiratory health effects associated with smoke from solid-fuel burning.
The epidemiological data on biomass use from Asia (most of them from south Asia), sub-Saharan Africa, and central and south America have provided substantial evidence to suggest that there is an association between exposure to biomass smoke and COPD in adults, and ALRI/pneumonia in children.
Chronic obstructive pulmonary disease
COPD, once regarded as a disease of developed countries, is now recognised as a common disease in developing countries. COPD is the fourth leading cause of all deaths: ∼3 million people died from the condition in 2004, of whom 90% were from low- and middle-income countries [54]. While the main contributing factors to COPD in developed countries are cigarette smoke and occupational causes, exposure to solid fuel smoke is a major contributing factor in developing countries. According to WHO estimates, ∼700,000 out of the 2.7 million global deaths due to COPD could be attributable to indoor air pollution from solid fuels [55], particularly in females. However, the purported link between exposure to solid fuel smoke and COPD has often been based on surrogate measures of exposure and no studies have shown a relationship between direct measurement of biomass smoke exposure and the incidence or prevalence of COPD. Lower socioeconomic status increases the risk of developing COPD, although which component factors (e.g. poor housing, poor nutrition, low income and no/poor education) are the most important in influencing COPD and to what extent is unclear. Nevertheless, one indicator of low socioeconomic status, the use of solid fuel, has been suggested as a key causal factor [56–58]. Although the underlying mechanisms for the development of COPD among nonsmokers exposed to biomass fuels are still unknown, some human challenge [59] and toxicological studies [19, 60] have reported that biomass burning produces chemicals with high oxidative potential, and have implicated that oxidative stress and DNA damage are underlying mechanisms responsible for the pathogenesis of COPD [61, 62] in those exposed to biomass smoke. Rivera et al. [63] compared the lung morphology in COPD secondary to cigarette and biomass smoke, and reported that smokers with COPD had a larger extent of emphysema and goblet cell metaplasia than females exposed to biomass smoke, but the latter presented more local scarring and pigment deposition in the lung parenchyma, and more fibrosis in the small airways. In contrast, Moran-Mendoza et al. [64] found that wood smoke-exposed, nonsmoking females had histopathological findings (dyspnoea, airway obstruction, air trapping, increased airway resistance, pathological evidence of anthracosis, chronic bronchitis, centrilobular emphysema, bronchial squamous metaplasia and pulmonary hypertension) similar to smokers.
Studies on solid fuel use and COPD are often observational, small in sample size with insufficient statistical power to show a clear relationship, and have relevant confounding factors that are often inadequately addressed. A further issue is the use of nonstandard definitions of COPD or chronic bronchitis. Therefore, the findings across studies should be viewed with some caution, as the published estimates may be either under- or overestimates of the true burden. A systematic review and meta-analysis [45] identified 23 studies, 10 reporting COPD based on both physician diagnosis and spirometric definitions, 11 reporting chronic bronchitis based on respiratory questionnaire data, and two reporting both COPD and chronic bronchitis. The pooled effect estimate for lung function diagnosed COPD (OR 2.96, 95% CI 2.01–4.37) was greater than those diagnosed by a doctor in hospital (OR 2.29, 95% CI 0.70–7.52), with a combined pooled effect estimate of 2.80 (95% CI 1.85–4.23) for COPD (fig. 3). Similarly, the pooled effect estimate for chronic bronchitis (fig. 4) was 2.32 (95% CI 1.92–2.80). The findings, published in 2010 [45], are similar to a recent meta-analysis [87] published for both chronic bronchitis (OR 2.52, 95% CI 1.88–3.38) and COPD (OR 2.40, 95% CI 1.47–3.93).
It is likely that exposure to biomass smoke from an early age will be important in retarding lung growth. In a study from Nepal where lung function was compared between a biomass smoke-exposed population and an unexposed population [88], the absolute values for various indices of lung function were significantly lower in both males and females in the biomass smoke-exposed group, the difference being evident even in the youngest age group studied (16–25 yrs). This suggests an effect of biomass smoke exposure on lung growth in addition to any effect on rate of decline of lung function in later years. The prevalence of airflow obstruction (defined as forced expiratory volume in 1 s/forced vital capacity ratio <0.70) in the biomass smoke-exposed group was almost doubled compared with the unexposed (20% versus 11%).
Overall, there is good evidence that exposure to biomass smoke is associated with airflow obstruction and an at least doubling of the risk of COPD, the effect being detected by young adulthood.
Asthma
There is a wide variation in the prevalence of asthma worldwide [89]. Asthma has been less widely studied in developing countries compared with developed countries, and understanding of the very different set of risk factors in these countries associated with its development, notably indoor environment and lifestyle, is limited. There is evidence that growing up in an agricultural environment is associated with a reduced risk of developing asthma, perhaps mediated by exposure to endotoxin [90], so it might be expected that exposure to biomass, which largely occurs in rural communities, might not be associated with development of asthma per se, but could be associated with exacerbations of existing asthma or with respiratory symptoms that might lead to a mistaken diagnosis of asthma. Some studies in developing countries have considered possible associations with biomass/solid fuel pollutant exposures [91–93]. Samuelsen et al. [94] studied allergy adjuvant effect of particles from wood smoke and road traffic in laboratory animals, and found that particles generated from wood burning had about the same capacity to enhance allergic sensitisation as road traffic particles, but less than diesel exhaust particles. Acute exposure to biomass smoke causes bronchial irritation, inflammation and increases bronchial reactivity that is possibly responsible for exacerbation of asthma [20].
Published effect sizes for asthma in relation to biomass exposure are presented in table 1. All these studies adopted different techniques to determine asthma and none measured actual biomass exposure levels. While this limits the ability to compare the studies, all show positive associations between indoor air pollution and asthma, at least in children.
A case–control study in Nepal assessed the home environment of schoolchildren in relation to asthma, using the International Study of Asthma and Allergies in Childhood questionnaire, and found that passive smoking and use of biomass fuels was separately associated with an increased risk of asthma in males only, but keeping animals in the home was associated with a lower risk of asthma (OR 0.2, 95% CI 0.1–0.5) [97]. This finding is supported by a similar case–control study from Kenya [95], which found that dampness in the child’s sleeping area, indoor air pollution and presence of rugs or carpets in the child’s bedroom were strongly associated with asthma (OR 2.0–4.9), and by a study from Guatemala in relation to asthma symptoms in 4–6-yr-old children [89]. In contrast, a study from Malaysia only found an association of asthma with environmental tobacco smoke (ETS) and exposure to mosquito coil smoke [96].
A meta-analysis of these four studies showed that exposure to indoor air pollution approximately doubles the risk of developing asthma in children (OR 1.96, 95% CI 1.29–2.99) but some caution needs to be taken in interpretation, as the methodology was imperfect in some way in all studies.
Only one study has considered biomass smoke exposure and asthma in adults [89]. Using a simple approach to defining asthma (a positive response by the head of household to the question “Does anyone listed suffer from asthma?”), the study found that people living in houses using biomass as a domestic fuel and who were active smokers had a significantly higher risk of asthma. Although this study found that asthma in elderly males and females (≥60 yrs) is associated with use of biomass fuel, the exposure was based on a crude yes/no response and there is a high possibility of misclassifying asthma.
In summary, the evidence possibly supports a role for biomass exposure being causally related to asthma in children, but formal, well-designed studies are needed to confirm this possibility. In particular, methods should ensure as tight a diagnosis of asthma as possible (perhaps including measures of bronchial reactivity, e.g. using mannitol challenge or exercise) to determine whether these findings simply reflect a pattern of asthma-like symptoms or true asthma.
Acute respiratory infection
Acute respiratory infection (ARI) can be divided into two types, upper respiratory tract infections (URTIs) and lower respiratory tract infections (LRTIs), which can, in turn, be categorised on clinical conditions, aetiology and markers of severity [58]. Although there are clinical and epidemiological criteria to separate URTI from LRTI worldwide, there are no uniformly accepted definitions used in epidemiological research. The lack of a uniformly accepted definition of ARI may cause bias that would contribute to the heterogeneity in reporting across different studies. The possible mechanism related to respiratory infection from acute exposure to PM from biomass burning might be due to reduced mucociliary clearance, and long-term exposure increasing susceptibility to bacterial and viral lung infections [20].
LRTIs are major causes of morbidity and mortality, leading to >4 million deaths per year worldwide, ∼69% of which occur in developing countries [100, 101]. After neonatal deaths, ARI (17%) is the second leading cause of deaths in children <5 yrs of age and the fourth leading cause of death in the world, where 7.4% of females and 7.1% of males die annually due to respiratory infections [101]. In low-income countries, respiratory infection is the leading cause of deaths (2.94 million, 11.2%) [101].
Mortality due to respiratory infection is higher in the <5 and ≥60 yrs age groups. Young children exposed to solid fuel smoke have two to three times more risk of serious ARI than unexposed children [58]. Deaths due to respiratory diseases are highest in African countries followed by eastern Mediterranean and then south-east Asian countries [101], where most of the people are of low socioeconomic status. In these areas, >70% of the population use solid fuels for domestic purposes and respiratory deaths from respiratory tract infections could well be attributed to the high exposure from the burning of biomass/solid fuel. Exposure to air pollutants might increase the incidence of ARI by adversely affecting specific and nonspecific defences of the respiratory tract against pathogens [102]. It is important to emphasise that death due to ARI is mainly associated with LRTI rather than URTI.
A longitudinal study in rural Kenya studied ARI and acute LRTI (ALRI) in children under the age of 5 yrs [5, 103]. The study measured biomass exposure as PM10 and found a dose–response relationship between PM10 and the increase in ARI and ALRI frequency. The rates of ARI and ALRI were higher for exposures of PM10 below 1,000–2,000 μg·m−3 but the rate of increase declined where exposure concentrations were >2,000 μg·m−3.
A longitudinal study (1984–1985) in Nepal of children <2 yrs of age showed a possible relationship between ARI and average number of hours spent in the kitchen (OR 2.2) reported by the mother [104]. A suggestion of a dose–response relationship was found in this study but the exposure assessment was not validated.
A case–control study from urban Nigeria did not find significant associations between age, nutritional status, ETS exposure, location of cooking and crowding with ALRI [105]. Mishra [106] studied acute respiratory infection in preschool children (<5 yrs of age) in Zimbabwe and found that ∼16% of the children had ARI at the time of their survey. The study reported that, after adjusting for appropriate confounders, children in households using biomass were more than twice (OR 2.2) as likely to suffer from ARI as children from households using clean fuel for domestic purposes. A 1-yr cohort study carried out in 500 Gambian children <5 yrs of age reported that parental smoking appeared (nonsignificantly) to increase the risk of ALRI [107]. However, the risk of ALRI was six times higher in females than in males, perhaps due to the fact that females are carried on their mother’s back more often than boys during cooking and, hence, are exposed more to biomass exposure.
A meta-analysis of 24 studies relating to pneumonia in children <5 yrs of age who were exposed to smoke from solid fuels showed the exposure to solid fuel smoke approximately doubles the risk of pneumonia (OR 1.78, 95% CI 1.45–2.18) [108]. There is thus consistent evidence that biomass smoke exposure is associated with an increased risk of ARI/pneumonia in children.
Tuberculosis
There is inconsistent evidence that exposure to biomass smoke increases the risk of TB [109, 110]. The proposed mechanism is that biomass smoke compromises the respiratory system’s ability to resist infection by Mycobacterium tuberculosis or to resist development of active TB in already infected persons [111]. There is enough evidence to support the belief that current and/or former smoking is associated with TB [110, 112–116] and some evidence to suggest that passive smoking is also a risk factor [117, 118] acting via a range of potential immune mechanisms. Similarly, biomass exposure interferes with mucociliary clearance [119] and decreases several antibacterial properties of lung macrophages, such as adherence and phagocytic rate [120, 121], providing theoretical mechanistic reasons to support the possibility that biomass smoke might be a risk factor for TB.
The available data suggest (table 2) that there might be a causal link between exposure to biomass smoke and either an increased risk of acquiring TB or progression of TB to clinical disease. There are very few studies that have explored this link, and there is heterogeneity in design, measurement of outcome and the magnitude of risk estimates, which need to be explored further to come to a firm conclusion. Most of the studies related to biomass use and TB suggest that prevalence of TB is higher in communities with poor sanitation and lower socioeconomic status, and these communities primarily use solid fuel for domestic purposes. A meta-analysis on the 10 studies mentioned in table 2 revealed a pooled effect estimate (OR 1.55, 95% CI 1.11–2.18) suggesting that individuals exposed to solid fuel smoke are 55% more likely to get TB than an unexposed group. While there was significant heterogeneity among the studies (I2 70%, p<0.001), no significant publication bias was reported.
Lung cancer
Lung cancer is one of the leading causes of death, accounting for 1.3 million deaths annually worldwide [129]. While smoking is the major risk factor, as many as a quarter of cases are not attributable to tobacco use [130]. Lung cancer in never-smokers is more common in females than males, although there is considerable regional variation in the proportions of nonsmoking females with lung cancer; for instance, in east and south Asia, up to 83% of female lung cancer cases are never-smokers, compared with 15% in the USA [130]. Emissions from combustion of solid fuels have been shown to have high concentrations of PAHs, BaP and PM2.5, which in turn have been associated with high lung cancer rates [130].
A meta-analysis of 28 studies relating to lung cancer in subjects exposed to solid fuel smoke showed a greater effect of coal smoke on lung cancer rates (OR 1.82, 95% CI 1.60–2.06) with biomass smoke, predominantly wood (OR 1.50, 95% CI 1.17–1.94) and mixed biomass fuel smoke (OR 1.13, 95% CI 0.52–2.46), showing lesser effects. The higher risk of lung cancer in coal users was not surprising as combustion products obtained from in-home coal burning contain a range of PAHs classified as group 1 carcinogens [131]. The general mechanism emerging from the study of PAHs such as BaP is genotoxicity, where BaP is metabolised to an electrophilic form that adducts DNA. The International Agency for Research on Cancer (IARC) has classified combustion products from biomass (primarily wood) use as probably carcinogenic to humans (group 2A) for lung cancer due to “limited evidence” in humans and experimental animals [131].
One methodological issue in such analyses is the use of appropriate comparison populations. The pooled effect size obtained from studies using population-based controls (carrying 56% weight) (OR 1.83, 95% CI 1.51–2.21) were greater than those using hospital-based controls (39% weight) (OR 1.63, 95% CI 1.34–1.97). This suggests the evidence of the carcinogenicity of biomass smoke is still not conclusive, supporting the IARC evaluation.
Cigarette smoking has been widely identified as the main contributory factor for lung cancer worldwide [132, 133] but no objective measurement of smoking was carried out in any of the studies included here. However, all studies included in this review either adjusted for smoking or studied a population of nonsmokers. While it is accepted that self-reported smoking history is the best that can be achieved when considering life-long smoking details, objective measurement of smoking, such as salivary cotinine, is becoming more easily usable in field studies and, at least, provides information on current smoking and will help reduce exposure misclassification slightly.
Almost 75% of the studies included in this meta-analysis did not adjust for ETS but studies dealing with coal smoke exposure with ETS adjusted (OR 1.47, 95% CI 1.13–1.91) had lower pooled effect sizes compared to those where ETS was not adjusted for (OR 1.74, 95% CI 1.60–1.89). Only one study out of eight related to biomass smoke exposure adjusted for ETS and had an effect size higher than the others that were not adjusted for ETS. Thus, ambiguity regarding the combined effect of smoking, combustion products of solid fuel and ETS exposure still prevails and future studies need to address this issue. There is evidence from occupational studies that smoking and some occupational exposures (e.g. asbestos and PAHs) have a multiplicative, rather than simply an additive, effect on lung cancer risk [134, 135], and it is therefore possible that such a potentiating effect may be seen with respect to smoke from solid fuel burning, especially that from coal.
Most of the cooking in developing countries is done by females, who are therefore more likely to be exposed to indoor air pollution than males. The pooled effect size shows that the risk of lung cancer is greater in females (OR 1.81, 95% CI 1.54–2.12) compared with males (OR 1.16, 95% CI 0.79–1.69), similar to that reported in a limited earlier meta-analysis for females only (OR 1.83, 95% CI 0.62–5.41) [136].
There may be an effect on cell type, as the pooled effect size for squamous cell carcinoma was greatest (OR 3.58, 95% CI 1.58–8.12) followed by adenocarcinoma (OR 2.33, 95% CI 1.72–3.17) and unspecified lung cancer type (OR 1.57, 95% CI 1.38–1.80). Squamous cell lung cancer is more commonly associated with cigarette smoking [137], although reported series of lung cancers have recently shown an increase in the proportion of adenocarcinomas, which is thought not to be simply an issue of changes in classification/grading [138].
INDOOR AIR POLLUTION FROM OTHER SOURCES AND ASSOCIATED HEALTH EFFECTS
There are number of other sources that contribute to the worsening of indoor air pollution in developing countries and may thus contribute to ill health.
Cooking oil fumes
Cooking emissions
Cooking is the treatment of food with heat. High temperature initiates volatilisation as well as a number of chemical reactions in the food ingredients, generally involving decomposition of lipids and amino acids [139]. The resulting emissions have been found to contain PM [140], volatile organic compounds (VOCs) [141] and other organic compounds, including PAHs [142] and heterocyclic amines [143], some of which are potent mutagens and carcinogens. The types and levels of pollutants in cooking emissions are highly heterogeneous and depend on food ingredients [144, 145]. For example, beef steak fried with margarine generated significantly higher levels of PM and aldehydes than when rapeseed oil, olive oil or soybean oil was used under the same cooking procedures [144]. However, Chiang and co-workers [146, 147] analysed emission samples in Taiwan and reported nonsignificant variations of levels of PAHs and aromatic amines using different types of cooking oil. In a controlled environment, Fullana et al. [145] reported higher levels of acetaldehyde and acrolein emissions from heated canola oil and olive oil, and suggested this might be related to their difference in fatty acid composition, where canola oil contains a higher proportion of linolenic acid and a small proportion of oleic acid than that in olive oil. The same report also provided evidence that the levels of pollutants are positively correlated with heating time and temperature [145]. Not surprisingly, different methods of cooking, such as frying (pan, stir and deep frying), grilling and baking, can affect the levels of emission. For instance, when stir frying meat, the concentration of BaP (2.64 μg per 100 m3) can be four times as high as that when it was boiled (0.65 μg per 100 m3) [148].
Chinese cooking appears to be of particular concern because the techniques involved generally require high temperature cooking with oil, such as in stir frying and deep frying. This is supported by a study in Taiwan, which found the annual rate of PAH emission was highest from Chinese restaurants compared with Western, fast food and Japanese restaurants, after taking into account a number of factors including cooking oil consumption and cooking methods [149]. A study in Singapore compared the concentrations of PM2.5 and PAHs in three ethnic food stalls and found the levels of both pollutants to be highest in Malay, followed by Chinese and Indian stalls. The difference in the levels could be explained by the frying processes predominantly used at the Malay (deep frying) and the Chinese (stir frying) stalls, whereas simmering (at lower temperature) was mostly used at the Indian stall [150].
Respiratory effects
Compared with the wealth of knowledge on the respiratory effects of biomass and solid fuels, far fewer studies have been dedicated to cooking-related emissions. Of those that did, the majority focused on lung cancer. A recent monograph from the IARC identified 17 case–control studies exploring the association between exposure to cooking emissions and lung cancer, and all were conducted exclusively in the Chinese population [131]. Among these 17 studies, only four allowed the cooking-related effects to be distinguished from those related to fuels [151–154]. In a group of nonsmoking females in Hong Kong, Yu et al. [152] found an escalating dose–response relationship between cumulative exposure (frequency and duration, in dish-years) and lung cancer risk, with a relative risk of ∼3 for 101–150 and 150–200 dish-yrs exposure, and >8 for >200 dish-yrs (referent exposure being ≤50 dish-yrs). In the two studies from Shanghai, those females who stir fried most frequently were 2.6 times [154] and 2.3 times [155] as likely to have lung cancer compared with those who stir fried least often. Similarly, a study in Gansu, China reported a relative risk of 2.2 [153]. These findings might explain the observed high nonsmoking lung cancer incidence in Chinese females, which could be attributed to their high cumulative exposure to cooking emissions. However, confounding by cooking fuel could not be ruled out because of the history of using biomass or solid fuels in the study populations in the latter three studies. In addition, recall and other forms of bias that are found in case–control studies could be operating, and contributing to the positive findings in some of these studies. Therefore, the causal relationship has not yet been totally confirmed.
There are few data on respiratory diseases other than lung cancer and none was derived from developing countries. A survey of 239 kitchen workers from 67 restaurants found a four- and two-fold increase in risk of dyspnoea for females and males, respectively, compared with controls [156]. However, the results could have been confounded by combustion products, although relatively clean fuel (gas) was used in these restaurants. Assessing the possibility of acute responses, the lung function of 12 healthy volunteers were monitored over a 24-h period with and without exposure to cooking fumes for 2 and 4 h but found no significant changes on spirometry [156].
Burning of incense sticks
Incense is regularly burnt in homes and offices for religious or ceremonial rituals and fragrance, particularly in developing countries. Incense is available in various forms, including sticks, joss sticks, cones, coils, powder, rope, rocks/charcoal and smudge bundles. The substances widely used to produce incense are resins (such as frankincense and myrrh), spices, aromatic wood and bark, herb seeds, roots, flowers, essential oils, and synthetic substitute chemicals used in the perfume industry [157]. Burning of incense releases different air pollutants, such as PM, VOCs, carbonyl compounds, carbon monoxide, nitrogen oxides, methane, nonmethane hydrocarbons, organic carbon, elemental carbon and inorganic ions (chloride, nitrate, sulfate, sodium, ammonium and potassium ions), depending on the types of incense sticks and aroma used, the concentration being much higher during the peak burning time of incense sticks [157–159]. The types of compounds present in the smoke released after burning incense suggest that they can cause a number of acute and chronic health effects. Although a number of studies has suggested that smoke released from burning can cause respiratory health effects [160, 161], lung cancer [162–164] and dermatological allergic reactions, and could be mutagenic and or genotoxic [165–167], the evidence is inconsistent, with some studies finding inverse relationships for lung cancer [168, 169] and COPD [66].
Burning of mosquito coils
Annually, 45–50 billion mosquito coils are used by ∼2 billion people worldwide [170], particularly in rural and semirural communities of developing countries, to prevent mosquito bites. Liu et al. [171] estimated that burning a mosquito coil can release a mass concentration of PM2.5 equivalent to burning of 75–137 cigarettes, depending upon the types of base material used to make the mosquito coil, and release formaldehyde equivalent to 51 cigarettes. The smoke released from burning mosquito coil contains some carcinogenic PAHs, including BaP, benzo[a]anthracene, benzo[b]fluoranthene, benzo[k]fluoranthene, dibenzo[a,h]anthracene and indeno[1,2,3-cd]pyrene [171, 172]. People in developing countries tend to burn mosquito coils during the summer nights and are therefore regularly exposed to the smokes released for about 6–8 h daily. Inhalation of the smoke has been reported to cause breathing difficulties, eye irritation, bronchial irritation, itching, cough and asthma [171, 173, 174].
CONCLUSION
The available evidence suggests that, despite heterogeneity among published studies, there is sufficient evidence and consistency among published studies to conclude that exposure to solid fuel smoke is a risk factor to COPD in adults and pneumonia in children, particularly those <5 yrs of age. Although the field has been hampered by methodological weaknesses, such as exposure not being measured directly and inadequate accounting of possible confounding factors, the overall data are sufficient to be sure that the effects size for COPD is around a three-fold risk for those exposed and around a two-fold risk for ALRI in children.
The available evidence also suggests that exposure to coal smoke is a risk factor to lung cancer whereas the evidence from biomass smoke exposure on lung cancer is not conclusive. As for asthma, there remains uncertainty as to whether biomass smoke does increase the risk of developing asthma in childhood and tighter methodological studies are needed to determine any true causal association. While there is limited information suggesting that deep frying, and using incense and mosquito coils are risk factors for respiratory problems, these risk factors should be regarded only as suggestive at this stage and need to be explored further (table 3).
Footnotes
For editorial comments see page 12.
Statement of Interest
None declared.
- Received November 1, 2011.
- Accepted February 4, 2012.
- ©ERS 2012