Air pollution and its effect on health

An experimental study of the effect of air pollutants on health can be undertaken only subsequent to the creation of synthetically polluted atmosphere in exposure chambers as a readily available and easily controllable laboratory tool. The many and varied pollutants must be studied singly and in combination so as to reproduce any synergistic or antagonistic effects that may exist. A study of pollutant substances at their source is wholly inadequate in view of the pronounced photo-chemical activity in the atmosphere. The products of this activity may well be the significant ones insofar as morbid effects are concerned. In the acute and subacute biological studies, both in vitro and in vivo systems are being used with the experimental progression being from the simple to the complex.     

Air pollution and allergic airway diseases

In the last decades, many studies have shown an increase in the prevalence of allergic rhinitis and asthma mainly in urban communities, especially in industrialized countries. Airborne pollutants such as diesel exhaust particles, ozone, nitrogen dioxide and sulphur dioxide have been implicated in the initiation and exacerbation of allergic airway diseases. Epidemiologic studies have shown clear associations between air pollution and allergic diseases, in vivo and in vitro studies have provided biologic link and potential molecular mechanisms. Particulate and gaseous pollutants can act both on the upper and lower airways to initiate and exacerbate cellular inflammation through interaction with the innate immune system. As a consequence, increased non-specific airway hyper-responsiveness and airway resistance have been observed in man. Diesel exhaust particles can both induce and exacerbate in vivo allergic responses. They can also modify the immune system's handling of the allergen. The effects of gaseous pollutants on immune responses to allergens are not fully understood. We review the different mechanisms involved in the enhancement of allergic inflammation by urban air pollutants, including effects on cytokine and chemokine production, as well as activation of different immune cells. We discuss the hypothesis that pollutants' effects on the immune system involve hierarchical oxidative stress. Susceptibility genes to air pollution inducing allergic diseases are also discussed.     

Atmospheric photochemical transformations enhance 1,3-butadiene-induced inflammatory responses in human epithelial cells: The role of ozone and other photochemical degradation products

Chemistry of hazardous air pollutants has been studied for many years, yet little is known about how these chemicals, once reacted within urban atmospheres, affect healthy and susceptible individuals. Once released into the atmosphere, 1,3-butadiene (BD) reacts with hydroxyl radicals and ozone (created by photochemical processes), to produce many identified and unidentified products. Once this transformation has occurred, the toxic potential of atmospheric pollutants such as BD in the ambient environment is currently unclear. During this study, environmental irradiation chambers (also called smog chambers), utilizing natural sunlight, were used to create photochemical transformations of BD. The smog chamber/in vitro exposure system was designed to investigate the toxicity of chemicals before and after photochemical reactions and to investigate interactions with the urban atmosphere using representative in vitro samples. In this study, we determined the relative toxicity and inflammatory gene expression induced by coupling smog chamber atmospheres with an in vitro system to expose human respiratory epithelial cells to BD, BDs photochemical degradation products, or the equivalent ozone generated within the photochemical mixture. Exposure to the photochemically generated products of BD (primarily acrolein, acetaldehyde, formaldehyde, furan and ozone) induced significant increases in cytotoxicity, IL-8, and IL-6 gene expression compared to a synthetic mixture of primary products that was created by injecting the correct concentrations of the detected products from the irradiation experiments. Interestingly, exposure to the equivalent levels of ozone generated during the photochemical transformation of BD did not induce the same level of inflammatory cytokine release for either exposure protocol, suggesting that the effects from ozone alone do not account for the entire response in the irradiation experiments. These results indicate that BDs full photochemical product generation and interactions, rather than ozone alone, must be carefully evaluated when investigating the possible adverse health effects to BD exposures. The research presented here takes into account that photochemical transformations of hazardous air pollutants (HAPs) does generate a dynamic exposure system and therefore provides a more realistic approach to estimate the toxicity of ambient air pollutants once they are released into the atmosphere.     

Health risk assessment of volatile organic compounds in urban areas

The atmosphere is the first medium containing hazardous compounds entering the living environment. Metropolitan areas contain many industrial complex areas with high emissions of volatile organic compounds (VOCs), and consequently also large-scale exposure groups. As respiration is the most important part of the human exposure pathway, the atmosphere should be treated with greater importance than other media. It is therefore very important to monitor the emission of hazardous air pollutants (HAPs) and measure the concentration of VOCs in the atmosphere of such areas. It is essential to establish basic measures in order to protect public health as part of overall national safety management. This study utilized the national air pollution monitoring network data from Seoul, Incheon, and Gyeonggi, and investigated the differences in risk levels for humans considering various factors of the receptors, including gender and age. A total of 13 VOCs were categorized into carcinogens and noncarcinogens for risk assessment. The carcinogens 1,3-butadiene and benzene demonstrated a high level of cancer risk, ranging between 10^?4 and 10^?6, respectively. Noncarcinogens did not exceed Hazard Quotient (HQ) 1 in any area. The results will serve as important references for managing urban air environments and setting air quality standards.     

Accumulation of particulate matter,heavy metals,and polycyclic aromatic hydrocarbons on the leaves of Tilia cordata Mill. in five Polish cities with different levels of air pollution

Urbanized areas are struggling with the problem of air pollution and as the number of people living in cities is increasing, the situation is likely to deteriorate. One of the most harmful pollutants is particulate matter (PM). Increased levels of PM in the atmosphere are likely to have a negative impact on human health. Phytoremediation technology could be a solution. It involves plants acting as bio-filters by accumulating particles on, and in the leaves, thus removing the particles from the atmosphere. This study investigates the accumulation of PM including heavy metals (HMs) and polycyclic aromatic hydrocarbons (PAHs), on the foliage of small-leaved lime (Tilia cordata Mill.) in five Polish cities. There were significantly different PM amounts found in the trees between the cities which related to the different quantities of PM in the atmosphere at these cities. Significant differences were found between cities for the amounts of the different particulate size fractions, and the HMs and PAHs in leaves. Strong winds reduced the amount of PM on leaves, especially the smallest fractions, but no relationship with precipitation was found. The results suggest that T. cordata improves the air quality in cities and can be used as an effective bioindicator for PM air pollution.     

Flared gases and other pollutants associated with air quality in industrial areas of Nigeria: an overview

Nigeria, like any other developing nation, is faced with the twin problem of development without destruction. Industrialization, though an important component of development, has had a large share in the despoilation of air quality in the country by the release of high amounts of pollutants into the atmosphere. Petroleum hydrocarbons from refineries, flared gases, dusts, and fumes of metal-smelting and cement works, odorous gases of chemical and allied industries, carbon monoxide and oxides of sulfur and nitrogen of internal combustion engines, the charred particulates and sulfur dioxide emissions of the steel industries etc., all constitute pollutants or co-pollutants of the Nigerian atmosphere. This review article gives an insight into the phenomenal concentrations of some of these pollutants in the Nigerian atmosphere, which point to their unsafe levels and concomitant health risks. It is against this background that there should be continuous but sound monitoring exercise of the Nigerian environment, devoid of the peculiar mix of politics and science, in order to properly audit the quality of air, especially in areas of heavy industrial pollution. Such checks and balances would provide empirical data to assess the various trade-offs of atmospheric pollution in industrial areas of the country such as the Niger Delta region where oil and gas are produced. There should also be enforcement, thereof, of all existing and/or revised standards or regulations such as the compliance limits of the Department of Petroleum Resources (DPR) or the erstwhile Federal Environmental Protection Agency (FEPA).     

Effects of diesel exhaust, heavy metals and pesticides on various organ systems: possible mechanisms and strategies for prevention and treatment

Environmental pollutants have a significant impact on the ecosystem and disrupt balance between environment, human and non-human components that result in deleterious effects to all forms of life. Identifying environmental factors for potential imbalance are extremely crucial for devising strategies for combating such toxic dysregulation. Automobile exhaust (in air), heavy metals (in food and water) and pesticides (in air, food, soil and water) are the most common environmental pollutants and their short and long-term exposures can cause hazardous effects in humans leading to systemic disorders involving lungs, kidney and immune systems. Mechanisms involved in genesis of such toxic effects have revealed complex, interactive pathways. Strategies for the protection of homeostasis and health, viz., general preventive measures, nutritional supplements and herbal agents have been described, to counter these pollutants induced damaging effects on various body systems.     

Fate and Transport of Contaminants in Indoor Air

Significant media and regulatory attention has been given to hazardous waste sites and to the remediation of such sites to protect nearby building occupants. Soil vapor intrusion (SVI) can be a major factor contributing to increased occupant expo sure to chemicals. However, there are many possible sources of indoor air pollution, thus complicating routine assessments. The intent of this paper is to provide an overview of the state of understanding related to chemical fate in the indoor environment. A generalized model is presented in the form of an ordinary differential equation that includes several terms that are not commonly accounted for in models involving the effects of SVI in indoor air. In addition to soil vapor intrusion several other sources of indoor contamination are described. Typical air exchange rates for residential dwellings are presented. Finally, recent findings related to the sorptive interactions between indoor air pollutants and indoor materials, as well as homogeneous and heterogeneous chemical reactions that can affect indoor air pollutants are described.     

Stretching the stress boundary: Linking air pollution health effects to a neurohormonal stress response

Inhaled pollutants produce effects in virtually all organ systems in our body and have been linked to chronic diseases including hypertension, atherosclerosis, Alzheimer's and diabetes. A neurohormonal stress response (referred to here as a systemic response produced by activation of the sympathetic nervous system and hypothalamus–pituitary–adrenal (HPA)-axis) has been implicated in a variety of psychological and physical stresses, which involves immune and metabolic homeostatic mechanisms affecting all organs in the body. In this review, we provide new evidence for the involvement of this well-characterized neurohormonal stress response in mediating systemic and pulmonary effects of a prototypic air pollutant — ozone. A plethora of systemic metabolic and immune effects are induced in animals exposed to inhaled pollutants, which could result from increased circulating stress hormones. The release of adrenal-derived stress hormones in response to ozone exposure not only mediates systemic immune and metabolic responses, but by doing so, also modulates pulmonary injury and inflammation. With recurring pollutant exposures, these effects can contribute to multi-organ chronic conditions associated with air pollution. This review will cover, 1) the potential mechanisms by which air pollutants can initiate the relay of signals from respiratory tract to brain through trigeminal and vagus nerves, and activate stress responsive regions including hypothalamus; and 2) the contribution of sympathetic and HPA-axis activation in mediating systemic homeostatic metabolic and immune effects of ozone in various organs. The potential contribution of chronic environmental stress in cardiovascular, neurological, reproductive and metabolic diseases, and the knowledge gaps are also discussed. This article is part of a Special Issue entitled Air Pollution, edited by Wenjun Ding, Andrew J. Ghio and Weidong Wu.     

Absorption of air pollution by plants, and consequences for growth

There is now great concern that air pollutants (especially sulfur dioxide, ozone, and oxides of nitrogen) can alter the physiological processes of plants, thereby affecting patterns of growth. Air pollutants cause damage to leaf cuticles and affect stomatal conductance. They can also have direct effects on photosynthetic systems, leaf longevity, and patterns of carbon allocation within plants. Pollutants interact with other environmental factors, and may alter plant-environment relationships on a regional scale. In this article, Winner and Atkinson summarize current knowledge of the effects of air pollutants on plant growth and physiology, and indicate the new directions of research now under way in North America and Europe.     

Urban air pollution and climate change: “The Decalogue: Allergy Safe Tree” for allergic and respiratory diseases care

Background

According to the World Health Organization, air pollution is closely associated with climate change and, in particular, with global warming. In addition to melting of ice and snow, rising sea level, and flooding of coastal areas, global warming is leading to a tropicalization of temperate marine ecosystems. Moreover, the effects of air pollution on airway and lung diseases are well documented as reported by the World Allergy Organization.

Methods

Scientific literature was searched for studies investigating the effect of the interaction between air pollution and climate change on allergic and respiratory diseases.

Results

Since 1990s, a multitude of articles and reviews have been published on this topic, with many studies confirming that the warming of our planet is caused by the “greenhouse effect” as a result of increased emission of “greenhouse” gases. Air pollution is also closely linked to global warming: the emission of hydrocarbon combustion products leads to increased concentrations of biological allergens such as pollens, generating a mixture of these particles called particulate matter (PM). The concept is that global warming is linked to the emission of hydrocarbon combustion products, since both carbon dioxide and heat increase pollen emission into the atmosphere, and all these particles make up PM10. However, the understanding of the mechanisms by which PM affects human health is still limited. Therefore, several studies are trying to determine the causes of global warming. There is also evidence that increased concentrations of air pollutants and pollens can activate inflammatory mediators in the airways. Our Task Force has prepared a Decalogue of rules addressing public administrators, which aims to limit the amount of allergenic pollen in the air without sacrificing public green areas.

Conclusions

Several studies underscore the significant risks of global warming on human health due to increasing levels of air pollution. The impact of climate change on respiratory diseases appears well documented. The last decades have seen a rise in the concentrations of pollens and pollutants in the air. This rise parallels the increase in the number of people presenting with allergic symptoms (e.g., allergic rhinitis, conjunctivitis, and asthma), who often require emergency medical care. Our hope is that scientists from different disciplines will work together with institutions, pharmaceutical companies and lay organizations to limit the adverse health effects of air pollution and global warming.

     

The influence of rising tropospheric carbon dioxide and ozone on plant productivity

Human activities result in a wide array of pollutants being released to the atmosphere. A number of these pollutants have direct effects on plants, including carbon dioxide (CO₂), which is the substrate for photosynthesis, and ozone (O₃), a damaging oxidant. How plants respond to changes in these atmospheric air pollutants, both directly and indirectly, feeds back on atmospheric composition and climate, global net primary productivity and ecosystem service provisioning. Here we discuss the past, current and future trends in emissions of CO₂ and O₃ and synthesise the current atmospheric CO₂ and O₃ budgets, describing the important role of vegetation in determining the atmospheric burden of those pollutants. While increased atmospheric CO₂ concentration over the past 150 years has been accompanied by greater CO₂ assimilation and storage in terrestrial ecosystems, there is evidence that rising temperatures and increased drought stress may limit the ability of future terrestrial ecosystems to buffer against atmospheric emissions. Long‐term Free Air CO₂ or O₃ Enrichment (FACE) experiments provide critical experimentation about the effects of future CO₂ and O₃ on ecosystems, and highlight the important interactive effects of temperature, nutrients and water supply in determining ecosystem responses to air pollution. Long‐term experimentation in both natural and cropping systems is needed to provide critical empirical data for modelling the effects of air pollutants on plant productivity in the decades to come.     

Enhancement of luminol-dependent chemiluminescence in an aqueous NaCl/H2O2 solution by argon

It was found that the bubbling of argon through NaCl/H2O2 aqueous solutions results in the development of intense sustained luminol-dependent chemiluminescence. Bubbling of nitrogen and air through similar solutions does not result in such effect. The relationship between argon-supported chemiluminescence and initial concentrations of NaCl and H2O2 is characterized by threshold effects. In NaCl/H2O2 solutions blown with argon, hypochlorite was found, indicating that argon intensifies the reaction of chloride oxidation with H2O2. It is suggested that the enhancement of this reaction in aqueous solutions saturated with argon is related to specific changes in the properties of water, which is a highly nonequilibrium system. Possible consequences of relatively high concentrations of argon in the atmosphere for the chemical processes that occur in aqueous systems and, in particular, living systems are discussed.     

多溴二苯醚的环境暴露与生态毒理研究进展

多溴二苯醚(PBDEs)是一类具有生态风险的新型环境有机污染物.作为阻燃剂,PBDEs已经被愈来愈广泛地添加到工业产品中,并因此对大气、水体、沉积物和土壤等环境介质及相关生态系统产生日益广泛的污染.鉴于这一环境新问题的产生,本文基于有限的资料,初步探讨了PBDEs的人为来源和环境暴露途径,大致给出了PBDEs在不同生物和人体不同组织器官中可能的存在及含量水平;在扼要介绍其基本性质的基础上,从甲状腺、神经系统和生殖发育毒性等三个方面分析了PBDEs对动物和人体可能产生的毒性效应与生态影响,以及PBDEs在生态系统中可能具有的生物积累和生物放大风险;并对今后研究PBDEs的环境暴露与生态效应以及人体健康影响等方面的工作重点进行了展望.     

Natural and man-made selection for air pollution resistance

All manner of domestic and industrial activities lead to the injection of potentially toxic contaminants in to the air. Most have little or no discernible impact on the environment, because the resulting concentrations in the atmosphere fall well below the threshold for effects. Others attain levels that are known to exceed the recognized thresholds for damage to both fauna and flora. In this review the focus is on two of the most ubiquitous air pollutants-sulphur dioxide (SO2) and ozone (O3). In many industrialized regions, ground-level concentrations of these gases are know to be high enough to depress crop yields and cause subtle shifts in the composition of natural (and semi-natural) plant communities. Consequently, these pollutants constitute a novel evolutionary challenge for natural and managed ecosystems. Herein, evidence is presented that some species are capable of responding to this challenge by evolving the ability to grow and reproduce in areas subjected to potentially phytotoxic pollutant concentrations. The prospects for breeding plants with enhanced resistance to the most common air pollutants are discussed and the tangible prospects of incorporating modern molecular approaches into existing strategies for the identification, isolation and manipulation of air pollution resistance in new stock are highlighted.     

Epidemiological studies regarding the effects of air pollution

Studies on large samples of the population are an indispensable prerequisite for investigations into the validity and reliability of threshold levels stipulated for atmospheric pollutants purity under real conditions. Children represent suitable groups for such studies, also in the context of meaningful and effective prophylaxis. Epidemiological studies conducted over several years show that there are differences between the anthropometric, hematological and immunological parameters of subjects living in regions with major pollution loads and in so-called "clean air" regions. Conclusions are drawn regarding the work performed by national hygiene authorities, and a method is proposed for the continuation of epidemiological studies in qualitatively and quantitatively differently loaded regions as a contribution to establishing a uniform register of effects.     

Dynamics of plant responses to combinations of air pollutants

The focus of this review is on how plants respond to combinations of multiple air pollutants. Global pollution trends, plant physiological responses and ecological perspectives in natural and agricultural systems are all discussed. In particular, we highlight the importance of studying sequential or simultaneous exposure of plants to pollutants, rather than exposure to individual pollutants in isolation, and explore how these responses may interfere with the way plants interact with their biotic community. Air pollutants can alter the normal physiology and metabolic functioning of plants. Here we describe how the phenotypic and molecular changes in response to multiple pollutants can differ compared to those elicited by single pollutants, and how different responses have been observed between plants in the field and in controlled laboratory conditions and between trees and crop plants. From an ecological perspective, we discuss how air pollution can result in greater susceptibility to biotic stressors and in direct or indirect effects on interactions with organisms that occupy higher trophic levels. Finally, we provide an overview of the potential uses of plants to mitigate air pollution, exploring the feasibility for pollution removal via the processes of bio‐accumulation and phytoremediation. We conclude by proposing some new directions for future research in the field.     

The importance of air quality in human biometeorology

Often we encounter a misunderstanding based on the assertion that the criterion of air quality is excluded from studies into meteorology and climatology. In contrast to this, it must be stressed that the admixtures and pollutants pertaining to air quality criteria belong to the atmosphere and therefore, of course, to the field of meteorology, and due to their possible effects also to human biometeorology. A normal weather forecast should include data concerning the concentrations of ozone, nitrogen dioxide, and other substances. Biometeorological weather classifications should also include mention of air quality rather more than previously. For instance, the classification after Bucher used in Germany is referred to and supplemented with respect to air quality. Analogous relationships hold true for the global classification of climates. As an example, the well-known classification after Koeppen is supplemented according to air quality.     

环境污染物对水生生物产生氧化压力的分子生物标志物

为了能够建立一种简单、快速、准确的环境污染监测预警体系，人们进行了广泛的研究，其中有关环境污染物对分子生物标志物的影响已成为研究热点。生物体内的氧自由基和其它活性氧分子（ROS）对组织和细胞成分造成的伤害，称之为氧化压力，环境中的有毒物质能够对生物体产生不同程度的氧化压力。生物体内的强氧化剂或体外因素（如环境污染物）引起的强氧化物与抗氧化防御系统之间的平衡能够用于评估环境压力对生物体产生影响的程度，尤其适合于评估不同种化学物质引起氧化损伤的程度。这些抗氧化防御系统及其对氧化压力的敏感性在环境毒物学研究中占有非常重要的地位，大量研究结果表明：过渡金属、多环芳烃、有机氯和有机磷农药、多氯联苯、二氧芑和其它异型物质都能够对生物体产生氧化压力。这些有毒物质能够引起各种有害影响，如对膜脂、DNA和蛋白产生损伤；改变抗氧化酶的活性等。总结了这种氧化压力的研究进展情况，并讨论了这些分子生物标志物在水生生物中的应用。     

木本植物对大气气态污染物吸收净化作用的研究

一、工作目的与意义 植物通过叶片上的气孔和枝条上的皮孔,可将大气污染物吸收入体内。在体内通过氧化还原过程进行中和而成无毒物质(即降解作用),或通过根系排出体外,或积累贮藏于某一器官内。植物对大气污染物的这种吸收、降解和积累、排出,实际起到了对大气污染的净化作用。一般情况下,植物吸收一定数量的大气污染物后,并不表现出异常的反应。而只是在超过其生理上的忍受限量后,才表现出可见的或不可见的症状。植物对大气污染物的这一生