Current state of the science: health effects and indoor environmental quality.Our understanding of the relationship between human health and the indoor environment continues to evolve. Previous research on health and indoor environments has tended to concentrate on discrete pollutant sources and exposures and on specific disease processes. Recently, efforts have been made to characterize more fully the complex interactions between the health of occupants and the interior spaces they inhabit. In this article we review recent advances in source characterization, exposure assessment, health effects associated with indoor exposures, and intervention research related to indoor environments. Advances in source characterization include a better understanding of how chemicals are transported and processed within spaces and the role that other factors such as lighting and building design may play in determining health. Efforts are under way to improve our ability to measure exposures, but this remains a challenge, particularly for biological agents. Researchers are also examining the effects of multiple exposures as well as the effects of exposures on vulnerable populations such as children and the elderly. In addition, a number of investigators are also studying the effects of modifying building design, materials, and operations on occupant health. Identification of research priorities should include input from building designers, operators, and the public health community. Key words: allergens, chemistry, exposure, fungi, humans, indoor air pollution, intervention, review. Environ Health Perspect 115:958-964 (2007). doi:10.1289/ehp.8987 available via http://dx.doi.org/ [Online 25 January 2007] ********** Our understanding of health effects related to the indoor environment has evolved over the past decade. In the past, discussions of indoor environmental quality (IEQ IEQ Indoor Environmental Quality (synonymous with IAQ) IEQ Initial Enrollment Questionnaire (US Medicare) IEQ Isotopic Equilibrator IEQ Input Event Queue ) focused on indoor air constituents (primarily particles, bioaerosols, and chemicals), and comfort factors (temperature, air flow, and humidity) (Samet et al. 1998). More recently, we have begun to look at the relationship between the built environment and humans as a complex interplay between building occupants (who they are and what they do) and an array of physical, chemical, biological, and design factors. This evolution in understanding has profound implications for the design and operation of buildings, how the buildings are used, and the prevention and management of health problems that occur in building occupants. Source Characterization Outdoor air pollution is a dynamic system in which the physical and chemical processes affecting the accumulation of pollutants in the atmosphere are constantly changing, largely driven by complex meteorology and photochemistry photochemistry, study of chemical processes that are accompanied by or catalyzed by the emission or absorption of visible light or ultraviolet radiation. A molecule in its ground (unexcited) state can absorb a quantum of light energy, or photon, and go to a . In contrast, the usual approach of modeling indoor air pollution considers only pollution source strength and dilution by air exchange, thus treating the indoor environment as a static box in which physical and chemical transformations of indoor air pollutants are absent or negligible. This misconception produces conservative estimates for primary indoor air pollutant concentrations and ignores the secondary pollutants. In-depth studies of indoor air have shown that the concentration of agents in indoor air is a function of outdoor concentration, indoor source strength, removal and deposition rate within the structure, indoor mixing, and chemical reaction. In the following sections, we use real-world examples to illustrate the dynamic nature of these processes and to discuss the implication of this dynamic environment in assessing exposures and health effects associated with indoor air pollution. Indoor production. The generation of pollutants within the indoor environment may come from primary and secondary sources. Primary sources include fuel combustion for cooking, heating, and lighting; tobacco smoking; bioeffluents from humans and animals; floor and wall coverings; synthetic paints, glues, polishes, and waxes; pesticides; and building products. Another source is the release of gases from solvents used indoors or from water that is used daily for showers, bathing, cooking, and from drinking fountains. Such sources are important for by-products (e.g., chloroform chloroform (klôr`əfôrm) or trichloromethane (trī'klôrōmĕth`ān), CHCl3 ) of chlorination-based water disinfection disinfection, n the process of destroying pathogenic organisms or rendering them inert. disinfection, full oral cavity, n a procedure used to reduce active periodontal disease, usually completed within a certain short time frame. and radon (McKone and Knezovich 1991; Xu and Weisel 2005). Because of the use of many types of synthetic materials in our daily lives, concentrations of many volatile organic compounds (VOCs) are consistently higher indoors than outdoors in residences and offices in developed countries. For some VOCs such as limonene lim·o·nene n. A liquid, C10H16, with a characteristic lemonlike fragrance, used as a solvent, wetting agent, and dispersing agent and in the manufacture of resins. , indoor levels up to 10 times those outdoors are common, even in locations with significant outdoor air pollution sources, such as petrochemical plants (Ott and Roberts 1998; Weisel et al. 2005). Secondary sources refer to indoor chemistry that transforms a set of indoor pollutants, emitted from primary sources or transported from outdoors, to a new set of indoor pollutants, as discussed below. Outdoor-to-indoor transport. Pollutants of outdoor origin, including those present in the outdoor air and those released from soil sources, can be transported indoors via building openings and cracks (Garbesi et al. 1999; Nazaroff 2004). Attempts have been made to estimate the fraction of measured indoor concentration contributed by outdoor air due to the outdoor-to-indoor transport process (Ott et al. 2000; Thatcher and Layton 1995). One such study, the Exposures of Adult Urban Populations in Europe Study (EXPOLIS), compared concentrations of ambient particulate matter [less than or equal to] 2.5 [micro]m ([PM.sub.2.5]), its 16 elemental constituents and black carbon, 30 VOCs, and carbon monoxide carbon monoxide, chemical compound, CO, a colorless, odorless, tasteless, extremely poisonous gas that is less dense than air under ordinary conditions. It is very slightly soluble in water and burns in air with a characteristic blue flame, producing carbon dioxide; (CO) among urban adult populations in seven European cities. The study examined exposures in workplaces, residential outdoor and indoor air, and separated workday and leisure time (Jantunen et al. 1998). EXPOLIS data from Helsinki, Finland, showed the infiltration factor (the proportion of outdoor PM found indoors) for [PM.sub.2.5] averaged 0.64 for residential structures, 0.47 for workplaces, and 0.35 for a subsample sub·sam·ple n. A sample drawn from a larger sample. tr.v. sub·sam·pled, sub·sam·pling, sub·sam·ples To take a subsample from (a larger sample). of office buildings constructed after 1990 (Hanninen et al. 2004b, 2005). In another study, the Relationship of Outdoor, Indoor, and Person Air (RIOPA), fractions of measured indoor concentration contributed by outdoor air for [PM.sub.2.5] and each of 24 VOCs including 10 aldehydes and ketones Ketones Poisonous acidic chemicals produced by the body when fat instead of glucose is burned for energy. Breakdown of fat occurs when not enough insulin is present to channel glucose into body cells. Mentioned in: Diabetic Ketoacidosis, Urinalysis were estimated for 310 residences located in three U.S. cities (Weisel et al. 2005). The median fractions of measured indoor concentration contributed by outdoor air for compounds with dominant indoor sources were less than 50%, for example, 13% for d-limonene (a common cleaning solvent), 20% for chloroform (a by-product of drinking water drinking water supply of water available to animals for drinking supplied via nipples, in troughs, dams, ponds and larger natural water sources; an insufficient supply leads to dehydration; it can be the source of infection, e.g. leptospirosis, salmonellosis, or of poisoning, e.g. disinfection), 31% for [alpha]-pinene and 20% for [beta]-pinene (ingredients of synthetic paints), and 19% for formaldehyde (released from building/furnishing materials). For the compounds with sole or dominant outdoor sources (e.g., methyl tert butyl butyl /bu·tyl/ (bu´t'l) a hydrocarbon radical, C4H9. bu·tyl n. A hydrocarbon radical, C4H9. butyl a hydrocarbon radical, C4H9. ether, carbon tetrachloride carbon tetrachloride (tĕ'trəklôr`īd) or tetrachloromethane (tĕ'trəklôr'əmĕth`ān), CCl4, colorless, poisonous, liquid organic compound that boils at 76. , and trichloroethylene trichloroethylene /tri·chlo·ro·eth·y·lene/ (-eth´i-len) a clear, mobile liquid used as an industrial solvent; formerly used as an inhalant anesthetic. tri·chlo·ro·eth·yl·ene n. ), the fractions were about 100%, as expected. The fractions for [PM.sub.2.5] had a median of 56%, 25th percentile of 46%, and 75th percentile of 93% across the RIOPA homes (Meng et al. 2005; Weisel et al. 2005). Significant interhome variability in fractions of measured indoor concentrations contributed by outdoor air has been observed for [PM.sub.2.5] and most of the VOCs in the RIOPA study. This finding has important implications for air pollution epidemiologic studies using concentrations measured at outdoor locations. Numerous exposure studies have shown poor correlations between personal exposure or residential indoor concentration and outdoor concentrations, indicating the observed associations between adverse health effects and PM concentrations measured at fixed outdoor sites do not necessarily represent the exposure-response relationships (Adgate et al. 2004; Clayton et al. 1993). Although attempts have been made to differentiate PM of outdoor origin from PM of indoor origin, analyses have been complicated because the fraction of indoor species contributed by outdoor air depends not only on outdoor concentration but also on home-specific parameters including air exchange rate [AER; typically expressed as air exchanges per hour (ach)], indoor generation rate, removal rate, and house volume (Meng et al. 2005; Thomas et al. 1993; Wallace et al. 1991). Outdoor-to-indoor transport of very reactive chemical species has often been considered unimportant. An example is ground-level ozone ([O.sub.3])that is formed via photochemical reactions and has elevated concentration in polluted atmospheres during photochemical smog photochemical smog n. Air pollution produced by the action of sunlight on hydrocarbons, nitrogen oxides, and other pollutants. episodes. [O.sub.3], like PM, is regulated in the United States as a criteria pollutant. Because of its high reactivity, only a fraction of [O.sub.3] can penetrate a building envelope. This fraction had been considered insignificant to cause any exposure concerns until 1989 when Weschler et al. (1989) showed that indoor exposure to [O.sub.3] can easily surpass outdoor exposure. Under moderate AERs (~ 0.5 ach), indoor [O.sub.3] concentrations may be 20-30% of corresponding outdoor concentrations. Under high AERs (> 1 ach), indoor [O.sub.3] levels can be 50-70% of outdoor levels. In a study carried out in six homes located in suburban New Jersey, indoor [O.sub.3] concentrations were 22-66% of outdoor levels during afternoon hours (Zhang et al. 1994). In summer time, 50% of the schools measured in Mexico City had indoor [O.sub.3] levels > 113 ppb (Gold et al. 1996). It is reasonably conservative to state that indoor [O.sub.3] levels > 20 ppb are common when outdoor [O.sub.3] concentrations are elevated. [O.sub.3] concentration at 20 ppb may not be sufficient to cause health concerns due to direct [O.sub.3] exposure, but this [O.sub.3] level can be sufficient to drive a complex set of indoor chemical reactions. When [O.sub.3] generators (so-called air purifiers) are used at [O.sub.3] generation rates of tens to thousands of milligrams per hour, indoor [O.sub.3] concentrations can be in the parts per million parts per million mg/kg or ml/l; see ppm. levels in a room with typical volume and AER. Particle sources include both indoor home and residential sources, although recent research has shown that indoor (workplace and residential) contributions to total exposures may be underestimated compared with outdoor sources such as traffic (BeruBe et al. 2004; Koistinen et al. 2004). This appears to depend on the character of the particle; combustion-derived particles may be due more to outdoor sources, whereas other particles (for example, soil-derived particles) may be related to resuspension Noun 1. resuspension - a renewed suspension of insoluble particles after they have been precipitated suspension - a mixture in which fine particles are suspended in a fluid where they are supported by buoyancy of particles during a host of indoor activities (Ferro et al. 2004; Larson et al. 2004). Recent experiments have shown that a wide range of indoor activities can result in considerable generation of PM (Afshari et al. 2005). Models of indoor PM exposure have been developed to account for both indoor and outdoor sources, as well as mixing, transport, and removal (Georgopoulos et al. 2005; Nazaroff 2004). Indoor-to-outdoor transport. Ventilation is the primary factor affecting indoor-to-outdoor transport of indoor generated pollutants. Ventilation is necessary to reduce concentrations of pollutants generated indoors, but it is also necessary to reduce the time available for chemical reactions among indoor pollutants. One reason offered to support the conventional view of indoor chemistry being insignificant is that chemical reactions among indoor pollutants are too slow to complete with air exchange processes. Although this may be true when the AER is high, a variety of chemical reactions can take place at AERs typical of today's residences and offices. Since the late 1970s, the airtight design of buildings, driven mainly by energy conservation, has resulted in reduced AERs. Based on approximately 4,590 measurements of residential AERs conducted across the United States, Pandian et al. (1998) reported that the mean, median, and SDs of AERs were 0.55, 0.42, and 0.47 ach, respectively, for the northeastern region, and 0.71, 0.62, and 0.56 ach for the southeastern region of the United States. AERs of this magnitude are undesirable for removing air pollutants that originate indoors and are low enough for certain chemical reactions to occur. Indoor chemistry. Pollutants can be removed from indoor air through both physical and chemical processes. Physical processes that can result in pollutant removal (in addition to transport outdoors) include phase change, adsorption adsorption, adhesion of the molecules of liquids, gases, and dissolved substances to the surfaces of solids, as opposed to absorption, in which the molecules actually enter the absorbing medium (see adhesion and cohesion). or absorption, or dissolving in water or organic films. Recently there has been considerable research interest in removal of pollutants through chemical reactions. "Indoor chemistry" has been defined as reactions involving indoor pollutants, occurring either in the gas phase or on surfaces (Weschler et al. 2006). For a chemical reaction to influence the indoor environment, the rate of the reaction must be sufficient to compete with AERs. These chemical reaction processes represent sinks for the reactants (primary indoor pollutants) and sources of new reaction products (secondary indoor pollutants). The products may predominate in the air or on the surface. Removal does not necessarily occur in a simple linear fashion; for example, semivolatile organic compounds can undergo an initial removal followed by a secondary increase due to resuspension of the compounds adsorbed on particles (Lioy 2006). Both gas-phase reactions and surface reactions that can occur under typical indoor conditions have been identified. The most extensively studied gas-phase reactions are oxidation reactions involving [O.sub.3] and free radicals. [O.sub.3] drives most indoor oxidation chemistry because it can react at meaningful rates with nitric oxide nitric oxide or nitrogen monoxide, a colorless gas formed by the combustion of nitrogen and oxygen as given by the reaction: energy + N2 + O2 → 2NO; m.p. −163.6°C;; b.p. −151.8°C;. , nitrogen dioxide, and unsaturated organic compounds (e.g., terpenes terpenes (terˑ·pēnz), n.pl a large-sized group of unsaturated hydrocarbons with the empirical formula (C5H8)n. , terpenoids, sesquiterpenes, unsaturated fatty acids unsaturated fatty acids, n.pl the double- or triple-bonded fatty acids contained primarily in vegetable oils and fish, which remain liquid at room temperature; linked to a reduction in the risk of developing heart disease. ) to yield reactive intermediates, the hydroxyl radical (OH), the nitrate radical (N[O.sub.3]) and oxygenated organic compounds (Weschler and Shields 1996). Reactions of [O.sub.3] with N[O.sub.2], in the absence of sunlight, form the N[O.sub.3] radical that further reacts with VOCs, leading to the formation of indoor nitric acid nitric acid, chemical compound, HNO3, colorless, highly corrosive, poisonous liquid that gives off choking red or yellow fumes in moist air. It is miscible with water in all proportions. . The N[O.sub.3] radical can also react with N[O.sub.2] to form dinitrogen pentaoxide ([N.sub.2][O.sub.5]) that undergoes hydrolysis hydrolysis (hīdrŏl`ĭsĭs), chemical reaction of a compound with water, usually resulting in the formation of one or more new compounds. , another pathway of nitric acid formation (Weschler et al. 1992). When [O.sub.3] and N[O.sub.2] are present simultaneously, indoor N[O.sub.3] may be the dominant indoor oxidant oxidant /ox·i·dant/ (ok´si-dant) the electron acceptor in an oxidation-reduction (redox) reaction. ox·i·dant n. See oxidizer. that effectively reacts with nearly all indoor VOCs. The role of indoor N[O.sub.3] chemistry in transforming indoor air pollutants remains to be evaluated. Several terpenes, especially d-limonene and [alpha]-pinene, are present at substantially higher concentrations indoors compared those with outdoors. These terpenes react readily with [O.sub.3] under typical or realistic indoor conditions to initiate a series of complex chemical reactions, for example, at an [O.sub.3] concentration of 20 ppb, the rate constant for [O.sub.3] reaction with d-limonene and [alpha]-pinene is approximately 0.36 ach and approximately 0.15 ach (Fan et al. 2003). Products of these reactions are found in both the gas and particle phases. Gas-phase-stable products include aldehydes, carboxylic acids, potentially allergenic Allergenic A substance capable of causing an allergic reaction. Mentioned in: Echinococcosis peroxides and hydroperoxides (Fan et al. 2003). In one experiment where [O.sub.3] (~ 41 ppb) was mixed with a VOC (Vertical Online Community) See vertical portal. mixture comprising 23 commonly found VOCs, the resulting peak concentration of ultrafine and fine particles was approximately 100 [micro]g/[m.sup.3] (Fan et al. 2005). Although attempts have been made to chemically identify the resulting particles, the majority of the particle mass could not be explained by the compounds identified thus far (Fan et al. 2003). It will be even more challenging to identify the short-lived, highly reactive, thermally labile labile /la·bile/ (la´bil) 1. gliding; moving from point to point over the surface; unstable; fluctuating. 2. chemically unstable. la·bile adj. 1. or highly oxidized oxidized having been modified by the process of oxidation. oxidized cellulose see absorbable cellulose. species that are formed in this complex reaction system. Unstable products of the ozone-terpene reactions include reactive intermediates and the hydroxyl radical. Hydroxyl radicals resulting from these indoor reactions can reach levels higher than typical nighttime outdoor concentrations, and thus react with other indoor VOCs with which ozone reacts too slowly to be of any practical significance (Weschler and Shields 1996). The formation of particles via [O.sub.3]-driven indoor chemistry has two implications. First, in an analysis of indoor particles measured in residences located in several United States cities, 25% of indoor [PM.sub.2.5] could not be explained with known sources (Wallace 1996). Indoor chemistry was not considered in the analysis, which might explain at least part of the unknown sources. Second, because [O.sub.3] and fine particles are co-generated outdoors during photochemical photochemical in laser treatment, the laser light is absorbed and converted into chemical energy. episodes, indoor particles resulting from indoor [O.sub.3]/VOC reactions can vary coincidently with the variations of outdoor summertime fine particles. This will certainly complicate the effort to separate PM of outdoor origin from PM of indoor origin. It should also be noted that source characterization may vary significantly, depending on the size of the particles (Koistinen et al. 2004). A second type of indoor chemistry involves surface reactions. Outdoor aerosol surfaces play an important role in atmospheric chemistry. The importance of surface reactions indoors is easily recognized, given that surface-to-volume ratios indoors are much larger than outdoors (roughly 3 vs. 0.01 [m.sup.2]/[m.sup.3]). Indeed, indoor surfaces may be ideal for substance sorption sorption /sorp·tion/ (sorp´shun) the process or state of being sorbed; absorption or adsorption. sorp·tion n. Adsorption or absorption. and for water condensation. Surface water film can react with indoor N[O.sub.2], a major product of natural gas combustion, to form nitrous acid nitrous acid /ni·trous ac·id/ (ni´trus) a weak acid, HNO2, existing only in aqueous solution. nitrous acid n. A weak inorganic acid existing only in solution or in the form of its salts. (HONO HONO Honolulu, Hawaii ) and nitric acid (HN[O.sub.3]). The resulting nitrous acid is released into the air as gas-phase HONO, whereas nitric acid remains on surfaces as an HN[O.sub.3]-[H.sub.2]O complex (Dubowski et al. 2004). The latter yields possible acidic, oxidizing, and nitrating surface films on interior walls. [O.sub.3] reacts with unsaturated VOCs contained in surface coatings at a faster rate than when it reacts with the same compounds in the gas phase (Reiss et al. 1995). Indoor surfaces, including building materials, wall cavities, ducts, skin, clothing, dust, and airborne particles are very diverse and are a determining factor of indoor surface chemistry. They affect HONO formation via surface-N[O.sub.2] chemistry (Wainman et al. 2001). Complex physical and chemical processes involving surfaces include sorption, redox redox (rē`dŏks): see oxidation and reduction. reactions, acidbase chemistry and hydrolysis (Nazaroff and Singer 2004). For example, diphthalate esters (plasticizers plasticizers mostly triaryl phosphates, such as tricresyl, triphenyl phosphates, which are poisonous. See also triorthocresyl phosphate. contained in polyvinyl chloride polyvinyl chloride (PVC), thermoplastic that is a polymer of vinyl chloride. Resins of polyvinyl chloride are hard, but with the addition of plasticizers a flexible, elastic plastic can be made. flooring materials) can undergo hydrolysis to form alcohols and monoesters. Aldehydes are emitted, at concentrations exceeding their odor thresholds, when [O.sub.3] interacts with carpets (Morrison and Nazaroff 2002). Building materials contain a large number of reactive constituents that can be released into the indoor air along with secondary products, including terpenoids, aliphatic aliphatic /al·i·phat·ic/ (al?i-fat´ik) pertaining to any member of one of the two major groups of organic compounds, those with a straight or branched chain structure. al·i·phat·ic adj. aldehydes, phthalates Phthalates, or phthalate esters, are a group of chemical compounds that are mainly used as plasticizers (substances added to plastics to increase their flexibility). They are chiefly used to turn polyvinyl chloride from a hard plastic into a flexible plastic. , phenol phenol (fē`nōl), C6H5OH, a colorless, crystalline solid that melts at about 41°C;, boils at 182°C;, and is soluble in ethanol and ether and somewhat soluble in water. , mono- and dicarboxylic acids, diisocyanates, and various photoinitiators. Photoinitiators, contained in ultraviolet curable cur·a·ble adj. Capable of being cured or healed. coatings, can undergo decomposition to generate free radicals, and some (e.g., benzaldehyde benzaldehyde (bĕnzăl`dəhīd) or benzenecarbonal (bĕn'zēnkär`bənəl), C6H5CHO, colorless liquid aldehyde with a characteristic almond odor. and cyclohexanone) are precursors of odorous products (Salthammer et al. 2002). In a study conducted in German houses constructed with wooden studs treated with pentachlorophenol pentachlorophenol a wood preservative with great capacity to enter the body by any route, including percutaneously; causes weight loss, low milk production and general debility. (PCP PCP abbr. 1. phencyclidine 2. primary care physician Pneumocystis carinii pneumonia (PCP) ), it was found that over time PCP had been transformed to tetrachloroanisole, a compound of highly undesirable odor (Gunschera et al. 2004). Indoor oxidation chemistry is largely driven by [O.sub.3] reactions with unsaturated VOCs and perhaps with N[O.sub.2] as well. Given that ozone levels have been rising in many areas, that indoor use of unsaturated VOCs (e.g., terpenes) has been on the rise, and that AERs have been decreasing, indoor oxidation chemistry has likely increased over the past several decades. Exposure Assessment Much remains to be learned about exposure assessment in indoor environments. Part of the challenge is to account for the relative contributions of both indoor and outdoor exposures. This has important implications, as indoor and outdoor exposures are often regulated very differently. Studies suggest that although indoor environmental measurements provide a better estimate of personal exposure than outdoor monitoring of VOCs, neither indoor nor outdoor environmental sampling (together or individually) is a good predictor of personal exposures (assessed by personal sampling and blood VOC concentrations) (Sexton et al. 2004, 2005). Exposure assessment for biological agents is even more challenging than for particulate and chemical exposures. New and more accurate identification methods to identify molds are under development. Currently, polymerase chain reaction polymerase chain reaction (pŏl`ĭmərās') (PCR), laboratory process in which a particular DNA segment from a mixture of DNA chains is rapidly replicated, producing a large, readily analyzed sample of a piece of DNA; the process is (PCR PCR polymerase chain reaction. PCR abbr. polymerase chain reaction Polymerase chain reaction (PCR) ) methods are used in which the target DNA DNA: see nucleic acid. DNA or deoxyribonucleic acid One of two types of nucleic acid (the other is RNA); a complex organic compound found in all living cells and many viruses. It is the chemical substance of genes. from building material is used as a template. In quantitative PCR (qPCR), quantitative data on the presence of viable and dead molds can be obtained--information that is not possible to obtain with the present culture methods (Cruz and Stetzenbach 2004; Meklin et al. 2004). These new methods are not yet fully developed and need to be evaluated (Keswani et al. 2005; McDevitt et al. 2004; Vesper et al. 2004). Even if fungal and mold species can be identified more accurately in the environment, there are as yet no reliable markers of human exposure or dose for these and other biological agents; some efforts are under way to assess exposure using chemical markers or immunologic markers (Schmechel 2006; Sebastian et al. 2005). Health Effects In this section we review recent findings on specific agents and mixtures of pollutants. Some of the most significant advances have been made in our understanding of the mechanism of inflammation, and its role in mediating the responses to a wide variety of environmental stressors. Particulate matter. Particulate air pollution has long been linked to both acute and chronic health effects, including asthma (e.g., mineral and organic dusts), cardiac disease (e.g, tobacco smoke and ambient air [PM.sub.2.5]), and other conditions (Pope et al. 1991; Viegi et al. 2004). Recent attention has focused on the ability of PM to potentiate po·ten·ti·ate v. 1. To make potent or powerful. 2. To enhance or increase the effect of a drug. 3. To promote or strengthen a biochemical or physiological action or effect. the effects of common allergens, promoting IgE production (Karol 2002). Fine particles have been shown to decrease the forced expiratory volume forced expiratory volume n. Abbr. FEV The maximum volume of air that can be expired from the lungs in a specific time interval when starting from maximum inspiration. in 1 sec (FE[V.sub.1]) in asthmatic schoolchildren schoolchildren school npl → écoliers mpl; (at secondary school) → collégiens mpl; lycéens mpl schoolchildren school (Delfino et al. 2004). Although particles have been shown to increase cardiovascular mortality, the specific mechanisms by which this occurs have yet to be clarified. Recent investigations have focused on possible effects on heart rate variability Heart rate variability (HRV) is a measure of variations in the heart rate. It is usually calculated by analysing the time series of beat-to-beat intervals from ECG or arterial pressure tracings. (Magari et al. 2002; Pope et al. 1999). PM, especially products of combustion, has also been linked to the development of cancer, although the exact relationship is still under active investigation (Vineis and Husgafvel-Pursiainen 2005). Most studies of PM have focused on ambient (outdoor) exposures and their relationship to hospital admissions and mortality. The contribution and significance of indoor particulate matter, which may differ substantially in composition from outdoor particulates, have yet to be fully explored (Bell et al. 2004; Morris 2001). Few studies have described the attributable risk attributable risk Epidemiology Any factor which ↑ the risk of suffering a particular condition. See Relative risk, Risk factor. Cf Nonattributable risk Statistics The rate of a disorder in exposed subjects that is attributable to the exposure derived from of adverse health effects from indoor sources of particles, but some are attempting to quantify the relative contributions of indoor and outdoor particulate matter (and other toxins) in greater detail, to aid risk and exposure models (Weisel et al. 2005). Chemicals. Chemicals of interest in the built environment include volatile and semivolatile organic compounds, pesticides, and some chemicals produced during combustion (carbon monoxide, nitrogen oxides). Initially, interest in chemicals in indoor environments focused primarily on irritant and toxic properties of individual chemicals such as volatile organic compounds (VOCs) and combustion products. Concerns were also raised about the potential for chronic health effects (primarily cancer) related to exposures to organic compounds. There is interest also in the health effects from plastics and plasticizers. Chemical constituents of plastics have been found in household dust, and studies suggest these plasticizers may be related to allergic diseases in children (Bornehag et al. 2004b, 2005; Oie et al. 1997). Chemical processing inside structures also contributes to adverse health effects from indoor chemicals (Weschler 2004). The relationship between irritation, stress, and perceived health effects of VOC exposures has gained increased attention. In one recent study, controlled exposures to VOCs, with and without ozone, did not significantly affect health effects compared with performance of a stress-inducing task (Fiedler et al. 2005). The relationship of VOCs to asthma, particularly in children, remains controversial. A population-based case-control study case-control study, n an investigation employing an epidemiologic approach in which previously existing incidents of a medical condition are used in lieu of gathering new information from a randomized population. of asthmatic and nonasthmatic children (ages 6 months to 3 years) in Australia found that the adjusted odds ratios for asthma increased with increasing concentrations of VOCs (particularly benzene, toluene toluene (tōl`y  ēn') or methylbenzene (mĕth'əlbĕn`zēn), C7H8 ,
ethylbenzene Ethylbenzene is an organic chemical compound which is an aromatic hydrocarbon. Its major use is in the petrochemical industry as an intermediate compound for the production of styrene, which in turn is used for making polystyrene, a commonly used plastic material. , and xylene xylene (zī`lēn) or dimethylbenzene (dī'mĕthəlbĕn`zēn), C6H4(CH3)2 ) (Rumchev et al. 2004). By contrast, a study in
the United Kingdom found that VOC exposure (except formaldehyde) was not
associated with an increased risk of wheezing Wheezing DefinitionWheezing is a high-pitched whistling sound associated with labored breathing. Description Wheezing occurs when a child or adult tries to breathe deeply through air passages that are narrowed or filled with mucus as a illness, whereas dampness was significantly associated with wheezing illness (Venn et al. 2003). Several factors could account for inconsistencies between observational and interventional studies of home exposures to VOCs and asthma risk, including confounding, small effect levels, or chronicity of exposure (Dales and Raizenne 2004). Polybrominated diphenyl ethers Polybrominated diphenyl ethers or PBDE, are a flame retardant sub-family of the brominated flame retardant group. They have been used in a wide array of household products, including fabrics, furniture, and electronics. commonly used in flame retardants in consumer products can concentrate in house dust, and thus are potentially available for ingestion ingestion /in·ges·tion/ (-chun) the taking of food, drugs, etc., into the body by mouth. in·ges·tion n. 1. The act of taking food and drink into the body by the mouth. 2. by occupants (Gevao et al. 2006). Similar results have been obtained for a variety of chemicals used in consumer products, indicating the importance of examining not only building components but also furnishings and contents of the indoor environment as sources of exposure (Marklund et al. 2003). Biological agents. Animal antigens. Allergy to indoor agents can cause frequent and severe health problems, especially in children. Animal allergens are found commonly indoors, even where animals are not present. For example, assessment of cat, dog, and mite allergens in settled dust in schools and day-care centers in Oslo, Norway, revealed most samples contained detectable amounts of cat and dog allergens. Allergens were detected in mattress and floor dust in daycare centers and in curtain and floor dust in schools. The levels of cat and dog allergens in school floor dust were associated with the number of pupils with animals at home. By contrast, < 1% of the samples had measurable levels of mite allergen allergen /al·ler·gen/ (al´er-jen) an antigenic substance capable of producing immediate hypersensitivity (allergy).allergen´ic pollen allergen Der p 1. Endotoxin Endotoxin A biologically active substance produced by bacteria and consisting of lipopolysaccharide, a complex macromolecule containing a polysaccharide covalently linked to a unique lipid structure, termed lipid A. levels were also assessed. Levels of endotoxin tended to be higher in dust from floors (1.4 ng/[m.sup.2]) compared with that from mattresses (0.9 ng/[m.sup.2]). Mattresses in daycare centers are reservoirs of cat and dog allergens and should be cleaned frequently (Instanes et al. 2005). In most communities, avoiding cats in the home would not decrease the prevalence of sensitization sensitization /sen·si·ti·za·tion/ (sen?si-ti-za´shun) 1. administration of an antigen to induce a primary immune response. 2. exposure to allergen that results in the development of hypersensitivity. to cats because cat allergen is distributed in schools, other public buildings, and homes without a cat. Evidence that children or adults who make a modified T-helper 2 response (IgG and IgG4 antibody without IgE) are not at increased risk of asthma supports the role of IgE in asthma (Erwin et al. 2005). Biological hazards associated with damp indoor environments. There is a large and growing literature on the health effects of biological agents typically found in damp indoor environments (Bornehag et al. 2001, 2004a). An Institute of Medicine (IOM IOM See: Index and Option Market ) committee concluded there was sufficient evidence of association of damp indoor spaces with various upper and lower respiratory tract Noun 1. lower respiratory tract - the bronchi and lungs lung - either of two saclike respiratory organs in the chest of vertebrates; serves to remove carbon dioxide and provide oxygen to the blood symptoms in adults and children. Molds and other specific biological agents were associated with a number of conditions including hypersensitivity pneumonitis Hypersensitivity Pneumonitis Definition Hypersensitivity pneumonitis refers to an inflammation of the lungs caused by repeated breathing in of a foreign substance, such an organic dust, a fungus, or a mold. in susceptible persons. The committee noted that in many cases and for many conditions, evidence is still insufficient to conclude that such an association exists (IOM Committee on Damp Indoor Spaces and Health 2004). The clinical effects of human exposure to mold spores were studied in sensitive subjects who had previously experienced potentially building-related symptoms at work. A highly controlled dose of fungal material was aerosolized Adj. 1. aerosolized - in the form of ultramicroscopic solid or liquid particles dispersed or suspended in air or gas aerosolised gaseous - existing as or having characteristics of a gas; "steam is water is the gaseous state" directly from wet building materials. In a double-blinded study, eight sensitive school employees were exposed to Penicillium chrysogenum or Trichoderma harzianum spores for 6 min on 3 separate days. A statistically significant rise in symptoms from mucous membranes Mucous membranes The inner tissue that covers or lines body cavities or canals open to the outside, such as nose and mouth. These membranes secrete mucus and absorb water and salts. Mentioned in: Leprosy, Pulmonary Fibrosis, Topical Anesthesia was assessed. This short-term exposure to high concentrations of two different molds induced no more reactions than exposure to placebo. Long-term experimental exposure studies on larger number of subjects would be needed to rule out an effect of mold exposure (Meyer et al. 2005). One area in which the IOM panel felt evidence was insufficient to conclude whether an association or causal relationship concerned molds and a number of systemic conditions alleged to be related to mycotoxins (Fischer and Dott 2003). Molds can produce toxic metabolites Metabolites Substances produced by metabolism or by a metabolic process. Mentioned in: Interactions known as mycotoxins. Over 400 mycotoxins have been described, most produced by species occurring on food. Many of the molds found indoors are similar to those on food and thus are also considered potential mycotoxin mycotoxin Toxin produced by a fungus. Numerous and varied, mycotoxins can cause hallucinations, skin inflammation, liver damage, hemorrhages, miscarriage, convulsions, neurological disturbances, and/or death in livestock and humans. producers. It is important to note that mycotoxin production depends both on the growth conditions and the substrate, and therefore only a limited number of species are known to produce toxic compounds when grown on building or in house materials (Nielsen et al. 2002). The most well-known species is Stachybotrys chartarum but there has been considerable controversy regarding the toxic potential of S. chartarum Stachybotrys atra, S. alternans, S. chartarum a fungus that grows on stored feed and produces trichothecene mycotoxins. Poisoning is characterized by diarrhea, necrotic ulcers in the mouth, mucosal petechiation and agranulocytosis. See also satratoxins. . Care is essential when dealing with fungal problems caused by Stachybotrys or related fungi. Although the species S. chartarum is well known, there about 17 other different species of Stachybotrys and the related Memnoniella (Jarvis 2003; Jong and David 1976). Research on the chemistry of Stachybotrys toxins is progressing to identify the chemical properties of species occurring in indoor environments. An excellent review of the toxins of S. chartarum describes a variety of secondary metabolites including trichothecenes, triprenylated phenols phenols (fēˑ·n  lz),n. , and a new class of diterpenoids called "atranones" produced by the fungus (Jarvis 2003). Two chemotypes were found in Stachybotrys. The very toxic macrocyclic trichothecenes were detected in one-third of the isolates; less toxic, simple trichothecenes and a new class of atranones were found in the remaining two-thirds of the isolates. Atranones also possess significant biological activity (Miller J.D., personal communication). Species of Chaetomium and Aspergillus Aspergillus Any fungus of the genus Aspergillus of the Fungi Imperfecti (form-class Deuteromycetes). Species for which the sexual phase is known are placed in the order Eurotiales. A. niger causes black mold on some foods; A. niger, A. flavus, and A. vesicolor are also potential toxin producers. The clinical effects of mycotoxins have been alleged to include respiratory, neurologic, immunologic, dermatologic, gastrointestinal, and irritant effects, among others (Kuhn and Ghannoum 2003; Laumbach and Kipen 2005). Despite the absence of validated markers of exposure, efforts have been made to understand the relationship between mold exposures and chronic nonallergic health effects. There have also been trials of empiric therapies for treating mold-exposed individuals, including patients treated with cholestyramine cholestyramine /cho·le·sty·ra·mine/ (ko?le-sti´rah-men) see cholestyramine resin, under resin. cho·le·styr·a·mine n. (Shoemaker and House 2005). There remains a lack of consensus regarding the systemic effects of mold exposures (Terr 2004). One of the limiting factors in this research is reliable, validated markers of exposure to either molds or the putative mycotoxins. In addition to intact molds and fungi, (1[right arrow]3)-[beta]-D-glucans are nonallergenic structural cell wall components of most fungi that have been suspected of playing a causal role in the development of respiratory symptoms associated with indoor fungal exposure. Current epidemiologic data do not permit conclusions to be drawn regarding the presence (or absence) of such an association between exposure and specific adverse health effects or which specific immunologic mechanisms underlie the presumed health effects (Douwes 2005). Other biological hazards associated with indoor environments include bacteria, viruses, and other organisms. Although the association of Legionella Legionella /Le·gion·el·la/ (le?jah-nel´ah) a genus of gram-negative, aerobic, rod-shaped bacteria (family Legionellaceae), normal inhabitants of lakes, streams, and moist soil; they have often been isolated from cooling-tower water, with building water systems is well known, humidification Humidification The process of increasing the water-vapor content (humidity) of a gas. This process and its reverse operation, dehumidification, are important steps in air conditioning for human comfort and in many industrial operations. systems carry risks for development of a variety of organisms capable of causing acute inflammatory responses as well as infection (Koschel et al. 2005). In addition, the design and operation of heating, ventilation, and air conditioning systems (HVACs) may have significant impact on the distribution of and subsequent exposures to aerosolized infectious agents (Li et al. 2005a, 2005b). Interactions and multiple exposures. Investigators have begun to measure multiple pollutants present within the same environment, including particles, combustion products, photochemical smog products, and allergens (Breysse et al. 2005; Hanninen et al. 2004a). This is partly because health effects are often related to multiple exposures and because many experimental interventions affect more than one exposure and agent. Important interactions also occur between exposures to pollutants and other hazards such as infectious agents. Exposures to [O.sub.3] and N[O.sub.2] have been shown to increase airway epithelial cell cytokine Cytokine Any of a group of soluble proteins that are released by a cell to send messages which are delivered to the same cell (autocrine), an adjacent cell (paracrine), or a distant cell (endocrine). production (Spannhake et al. 2002). Studies have also demonstrated interactions between particles and other contaminants such as [O.sub.3] that can potentiate the health effects of the two concomitant exposures (D'Amato et al. 2005; Harkema and Wagner 2005; Mar et al. 2005; Molhave et al. 2005). These findings suggest the possibility of additional benefits to interventions that reduce cumulative exposures to several pollutants compared with interventions focusing on only one exposure. Building Design and Health There is growing interest in examining the interaction of building design and health (Cummins and Jackson 2001). Physical and design characteristics of built structures (lighting, heating, ergonomics, noise, design) may create additional exposures that might contribute to health and comfort. Some of these factors may also play a role in chronic health effects. For example, evidence indicates that suppression of melatonin melatonin: see pineal gland. melatonin Hormone secreted by the pineal gland of most vertebrates. It appears to be important in regulating sleeping cycles; more is produced at night, and test subjects injected with it become sleepy. by nocturnal artificial lighting may play a role in breast and colon cancer colon cancer, cancer of any part of the colon (often called the large intestine). Colon cancer is the second most common cancer diagnosed in the United States. development (Pauley 2004; Stevens 2005). Research in office buildings, which has tended to focus on health and productivity, is now moving beyond indoor air to issues such as office design and acoustics (De Croon croon v. crooned, croon·ing, croons v.intr. 1. To hum or sing softly. 2. To sing popular songs in a soft, sentimental manner. 3. Scots To roar or bellow. et al. 2005). There is a growing literature on school design and injury prevention, with more recent research on physical activity, obesity, and the implications of school design for the development of chronic diseases in later life (Sallis and Glanz 2006), but there is limited literature on student achievement (Sexton et al. 2000). Finally, studies of residential building design have examined a range of health outcomes related to building design, notably injury, but also mental health and other outcomes (Bonnefoy et al. 2003; Weich et al. 2002). Intervention Studies intervention studies, n.pl the epidemiologic investigations designed to test a hypothesized cause and effect relation by modifying the supposed causal factor(s) in the study population. A number of investigators are now examining the effectiveness of environmental modification and education in reducing asthma severity. Examples include the use of air filters (Francis et al. 2003; Kilburn et al. 2003), pest management (McConnell et al. 2003), and education coupled with environmental modification (Krieger et al. 2002; Morgan et al. 2004; Tobias et al. 2004). Most of the interventions focus on control of more than one exposure, and have a relatively short duration. Another study showed that use of ultra-violet germicidal germicidal /ger·mi·ci·dal/ (jer?mi-si´d'l) antimicrobial (1). germicidal destructive to pathogenic microorganisms. irradiation within the HVAC (Heating Ventilation Air Conditioning) In the home or small office with a handful of computers, HVAC is more for human comfort than the machines. In large datacenters, a humidity-free room with a steady, cool temperature is essential for the trouble-free system could reduce irritation symptoms in office workers (Menzies et al. 2003). This study was a crossover design in which subjects were blinded as to whether the intervention was in effect, and it used both symptom reporting and objective measures as outcomes. Although it did not examine all potential limitations and side effects Side effects Effects of a proposed project on other parts of the firm. of the intervention, it provides a useful example of the kinds of studies that may be needed to evaluate intervention strategies. Conclusion It is increasingly apparent that indoor environments are unique and contain significant exposures that can affect the health of occupants. The exposures are the result of complex interactions between the structure, building systems, furnishings, the outdoor environment, and the building occupants and their activities. As people spend more time indoors, the opportunities increase for significant health effects resulting from these exposures. So too does the need for research into the circumstances that make exposures more likely and the effectiveness of interventions to reduce the exposures. Interventions may involve difficult tradeoffs such as increased ventilation versus the need for energy efficiency. In addition, more research is needed on the interactions of multiple exposures, and the risks to certain populations (such as children, the elderly, or socioeconomically disadvantaged populations). Identification of research priorities should include input from building designers, operators, and the public health community. Research on interventions should examine a range of outcomes and potential tradeoffs and confounders, and does not necessarily need to await the identification of specific causal agents. Research is also needed on better measures of dose, particularly for biological agents. REFERENCES Adgate JL, Church TR, Ryan AD, Ramachandran G, Fredrickson AL, Stock TH, et al. 2004. Outdoor, indoor, and personal exposure to VOCs in children. Environ Health Perspect 112:1386-1392. Afshari A, Matson U, Ekberg LE. 2005. Characterization of indoor sources of fine and ultrafine particles: a study conducted in a full-scale chamber. Indoor Air 15:141-150. Bell ML, Samet JM, Dominici F. 2004. Time-series studies of particulate matter. Annu Rev Public Health 25:247-280. BeruBe KA, Sexton KJ, Jones TP, Moreno T, Anderson S, Richards RJ. 2004. The spatial and temporal variations in [PM.sub.10] mass from six UK homes. Sci Total Environ 324:41-53. Bonnefoy XR, Braubach M, Moissonnier B, Monolbaev K, Robbel N. 2003. Housing and health in Europe: preliminary results of a pan-European study. Am J Public Health 93:1559-1563. Bornehag CG, Blomquist G, Gyntelberg F, Jarvholm B, Malmberg P, Nordvall L, et al. 2001. Dampness in buildings and health. Nordic interdisciplinary review of the scientific evidence on associations between exposure to "dampness" in buildings and health effects (NORDDAMP). Indoor Air 11:72-86. Bornehag CG, Lundgren B, Weschler CJ, Sigsgaard T, Hagerhed-Engman L, Sundell J. 2005. Phthalates in indoor dust and their association with building characteristics. Environ Health Perspect 113:1399-1404. Bornehag CG, Sundell J, Bonini S, Custovic A, Malmberg P, Skerfving S, et al. 2004a. Dampness in buildings as a risk factor for health effects, EUROEXPO: a multidisciplinary review of the literature (1998-2000) on dampness and mite exposure in buildings and health effects. Indoor Air 14:243-257. Bornehag CG, Sundell J, Weschler CJ, Sigsgaard T, Lundgren B, Hasselgren M, et al. 2004b. The association between asthma and allergic symptoms in children and phthalates in house dust: a nested case-control study A nested case-control study is a type of study design where new case controls are applied into cohorts which were defined before the study begins. Compared with case-control study, nested case-control study can reduce 'recall bias' and temporal ambiguity, and compared with . Environ Health Perspect 112:1393-1397. Breysse PN, Buckley TJ, Williams D, Beck CM, Jo SJ, Merriman B, et al. 2005. Indoor exposures to air pollutants and allergens in the homes of asthmatic children in innercity Baltimore. Environ Res 98:167-176. Clayton CA, Perritt RL, Pellizzari ED, Thomas KW, Whitmore RW, Wallace LA, et al. 1993. Particle Total Exposure Assessment Methodology (PTEAM PTEAM Particle Total Exposure Assessment Methodology ) study: distributions of aerosol and elemental concentrations in personal, indoor, and outdoor air samples in a southern California community. J Expo Anal Environ Epidemiol 3:227-250. Cruz P, Stetzenbach LD. 2004. Specific detection of fungi associated with SBS See Small Business Server. when using quantitative polymerase chain reaction Quantitative polymerase chain reaction (qPCR) is a modification of the polymerase chain reaction used to rapidly measure the quantity of DNA, complementary DNA or ribonucleic acid present in a sample. . Adv Appl Microbiol 55:437-449. Cummins SK, Jackson RJ. 2001. The built environment and children's health Children's Health Definition Children's health encompasses the physical, mental, emotional, and social well-being of children from infancy through adolescence. . Pediatr Clin North Am 48:1241-1252, x. Dales R, Raizenne M. 2004. Residential exposure to volatile organic compounds and asthma. J Asthma 41:259-270. D'Amato G, Liccardi G, D'Amato M, Holgate S. 2005. Environmental risk factors and allergic bronchial asthma bronchial asthma n. A condition of the lungs characterized by widespread narrowing of the airways due to spasm of the smooth muscle, edema of the mucosa, and the presence of mucus in the lumen of the bronchi and bronchioles. . Clin Exp Allergy 35:1113-1124. De Croon EM, Sluiter JK, Kuijer PP, Frings-Dresen MH. 2005. The effect of office concepts on worker health and performance: a systematic review of the literature. Ergonomics 48:119-134. Delfino RJ, Quintana PJ, Floro J, Gastanaga VM, Samimi BS, Kleinman MT, et al. 2004. Association of FEV FEV forced expiratory volume. FEV abbr. forced expiratory volume FEV forced expiratory volume. 1 in asthmatic children with personal and microenvironmental exposure to airborne particulate matter. Environ Health Perspect 112:932-941. Douwes J. 2005. (1[right arrow]3)-[beta]-D-Glucans and respiratory health: a review of the scientific evidence. Indoor Air 15:160-169. Dubowski Y, Sumner AL, Menke EJ. 2004. Interactions of gaseous nitric acid with surfaces of environmental interest. Phys Chem Chem Physics 6:3879-3888. Erwin EA, Custis N, Ronmark E, Wickens K, Sporik R, Woodfolk JA, Platts-Mills TA. 2005. Asthma and indoor air: contrasts in the dose response to cat and dust-mite. Indoor Air 15(suppl 10):33-39. Fan Z, Lioy P, Weschler C, Fiedler N, Kipen H, Zhang J. 2003. Ozone-initiated reactions with mixtures of volatile organic compounds under simulated indoor conditions. Environ Sci Technol 37:1811-1821. Fan Z, Weschler CJ, Han I, Zhang J. 2005. Co-formation of hydroperoxides and ultra-fine particles during the reactions of ozone with a complex VOC mixture under simulated indoor conditions. Atmos Environ 39:5171-5182. Ferro AR, Kopperud RJ, Hildemann LM. 2004. Source strengths for indoor human activities that resuspend Verb 1. resuspend - put back into suspension; "resuspend particles" chemical science, chemistry - the science of matter; the branch of the natural sciences dealing with the composition of substances and their properties and reactions particulate matter. Environ Sci Technol 38:1759-1764. Fiedler N, Laumbach R, Kelly-McNeil K, Lioy P, Fan ZH, Zhang J, et al. 2005. Health effects of a mixture of indoor air volatile organics, their ozone oxidation products, and stress. Environ Health Perspect 113:1542-1548. Fischer G, Dott W. 2003. Relevance of airborne fungi and their secondary metabolites for environmental, occupational and indoor hygiene. Arch Microbiol 179:75-82. Francis H, Fletcher G, Anthony C, Pickering C, Oldham L, Hadley E, et al. 2003. Clinical effects of air filters in homes of asthmatic adults sensitized sensitized /sen·si·tized/ (sen´si-tizd) rendered sensitive. sensitized rendered sensitive. sensitized cells see sensitization (2). and exposed to pet allergens. Clin Exp Allergy 33:101-105. Garbesi K, Robinson AL, Sextro RG, Nazaroff WW. 1999. Radon entry into houses: the importance of scale-dependent permeability. Health Phys 77:183-191. Georgopoulos PG, Wang SW, Vyas VM, Sun Q, Burke J, Vedantham R, et al. 2005. A source-to-dose assessment of population exposures to fine PM and ozone in Philadelphia, PA, during a summer 1999 episode. J Expo Anal Environ Epidemiol 15:439-457. Gevao B, Al-Bahloul M, Al-Ghadban AN, Al-Omair A, Ali L, Zafar J, et al. 2006. House dust as a source of human exposure to polybrominated diphenyl ethers in Kuwait. Chemosphere chemosphere: see atmosphere. (4):603-608. Gold DR, Allen G, Damokosh A, Serrano P, Hayes C, Castillejos M. 1996. Comparison of outdoor and classroom ozone exposures for school children in Mexico City. J Air Waste Manag Assoc 46:335-342. Gunschera J, Fuhrmann F, Salthammer T, Schulze A, Uhde E. 2004. Formation and emission of chloroanisoles as indoor pollutants. Environ Sci Pollut Res Int 11:147-151. Hanninen OO, Alm S, Katsouyanni K, Kunzli N, Maroni M, Nieuwenhuijsen MJ, et al. 2004a. The EXPOLIS study: implications for exposure research and environmental policy in Europe. J Expo Anal Environ Epidemiol 14:440-456. Hanninen OO, Lebret E, Ilacqua V, Katsouyanni K, Kunzli N, Sram RJ, et al. 2004b. Infiltration of ambient [PM.sub.2.5] and levels of indoor generated non-ETS [PM.sub.2.5] in residences of four European cities. Atmos Environ 38:6411-6423. Hanninen OO, Palonen J, Tuomisto JT, Yli-Tuomi T, Seppanen O, Jantunen MJ. 2005. Reduction potential of urban [PM.sub.2.5] mortality risk using modern ventilation systems in buildings. Indoor Air 15:246-256. Harkema JR, Wagner JG. 2005. Epithelial and inflammatory responses in the airways of laboratory rats coexposed to ozone and biogenic substances: enhancement of toxicantinduced airway injury. Exp Toxicol Pathol 57(suppl 1):129-141. Instanes C, Hetland G, Berntsen S, Lovik M, Nafstad P. 2005. Allergens and endotoxin in settled dust from day-care centers and schools in Oslo, Norway. Indoor Air 15:356-362. IOM (Institute of Medicine) Committee on Damp Indoor Spaces and Health. 2004. Damp Indoor Spaces and Health. Washington, DC:National Academies Press. Jantunen MJ, Hanninen O, Katsouyanni K, Knoppel H, Kuenzli N, Lebret E, et al. 1998. Air pollution exposure in European cities: The "EXPOLIS" study. J Expo Anal Environ Epidemiol 8:495-518. Jarvis BB. 2003. Stachybotrys chartarum: a fungus for our time. Phytochemistry phytochemistry, n the scientific study and classification of the chemical constituents of plants. 64:53-60. Jong SC, David EE. 1976. Contribution to the knowledge of Stachybotrysand Memnoniellain culture. Mycotaxon 3:409-485. Karol MH. 2002. Respiratory allergy: what are the uncertainties? Toxicology 181-182:305-310. Keswani J, Kashon ML, Chen BT. 2005. Evaluation of interference to conventional and real-time PCR for detection and quantification of fungi in dust. J Environ Monit 7:311-318. Kilburn S, Lasserson TJ, McKean M. 2003. Pet allergen control measures for allergic asthma allergic asthma Clinical immunology A condition characterized by bronchoconstriction and SOB Clinical Wheezing, dyspnea—especially exhaling, chest tightness Exacerbated by Abrupt changes in temperature or humidity, allergies, URIs, exercise, stress, cigarette in children and adults. The Cochrane Database Sys Rev 1:CD002989. Koistinen KJ, Edwards RD, Mathys P, Ruuskanen J, Kunzli N, Jantunen MJ. 2004. Sources of fine particulate matter in personal exposures and residential indoor, residential outdoor and workplace microenvironments in the Helsinki phase of the EXPOLIS study. Scand J Work Environ Health 30(suppl 2):36-46. Koschel D, Stark W, Karmann F, Sennekamp J, Muller-Wening D. 2005. Extrinsic allergic alveolitis extrinsic allergic alveolitis n. Pneumoconiosis resulting from hypersensitivity to inhaled organic dust. caused by misting fountains. Respir Med 99:943-947. Krieger JK, Takaro TK, Allen C, Song L, Weaver M, Chai S, et al. 2002. The Seattle-King County healthy homes project: implementation of a comprehensive approach to improving indoor environmental quality for low-income children with asthma. Environ Health Perspect 110(suppl 2):311-322. Kuhn DM, Ghannoum MA. 2003. Indoor mold, toxigenic toxigenic /tox·i·gen·ic/ (tok?si-jen´ik) 1. producing or elaborating toxins. 2. derived from or containing toxins. tox·i·gen·ic adj. Producing a poison; toxicogenic. fungi, and Stachybotrys chartarum: infectious disease Infectious disease A pathological condition spread among biological species. Infectious diseases, although varied in their effects, are always associated with viruses, bacteria, fungi, protozoa, multicellular parasites and aberrant proteins known as prions. perspective. Clin Microbiol Rev 16:144-172. Larson T, Gould T, Simpson C, Liu LJ, Claiborn C, Lewtas J. 2004. Source apportionment The process by which legislative seats are distributed among units entitled to representation; determination of the number of representatives that a state, county, or other subdivision may send to a legislative body. The U.S. of indoor, outdoor, and personal [PM.sub.2.5] in Seattle, Washington, using positive matrix factorization fac·tor·ize tr.v. fac·tor·ized, fac·tor·iz·ing, fac·tor·iz·es Mathematics To factor. fac . J Air Waste Manag Assoc 54:1175-1187. Laumbach RJ, Kipen HM. 2005. Bioaerosols and sick building syndrome sick building syndrome n. An illness affecting workers in office buildings, characterized by skin irritations, headache, and respiratory problems, and thought to be caused by indoor pollutants, microorganisms, or inadequate ventilation. : particles, inflammation, and allergy. Curr Opin Allergy Clin Immunol 5:135-139. Li Y, Duan S, Yu IT, Wong TW. 2005a. Multi-zone modeling of probable SARS virus transmission by airflow between flats in Block E, Amoy Gardens. Indoor Air 15:96-111. Li Y, Huang X, Yu IT, Wong TW, Qian H. 2005b. Role of air distribution in SARS transmission during the largest nosocomial nosocomial /noso·co·mi·al/ (nos?o-ko´me-il) pertaining to or originating in a hospital. nos·o·co·mi·al adj. 1. Of or relating to a hospital. 2. outbreak in Hong Kong. Indoor Air 15:83-95. Lioy PJ. 2006. Employing dynamical and chemical processes for contaminant contaminant /con·tam·i·nant/ (kon-tam´in-int) something that causes contamination. contaminant something that causes contamination. mixtures outdoors to the indoor environment: The implications for total human exposure analysis and prevention. J Expo Sci Environ Epidemiol 16(3):207-224. Magari SR, Schwartz J, Williams PL, Hauser R, Smith TJ, Christiani DC. 2002. The association between personal measurements of environmental exposure to particulates and heart rate variability. Epidemiology 13:305-310. Mar TF, Koenig JQ, Jansen K, Sullivan J, Kaufman J, Trenga CA, et al. 2005. Fine particulate air pollution and cardio-respiratory effects in the elderly. Epidemiology 16:681-687. Marklund A, Andersson B, Haglund P. 2003. Screening of organophosphorus compounds and their distribution in various indoor environments. Chemosphere 53:1137-1146. McConnell R, Jones C, Milam J, Gonzalez P, Berhane K, Clement L, et al. 2003. Cockroach cockroach or roach, name applied to approximately 3,500 species of flat-bodied, oval insects forming the order Blattodea. Cockroaches have long antennae, long legs adapted to running, and a flat extension of the upper body wall that conceals the counts and house dust allergen concentrations after professional cockroach control and cleaning. Ann Allergy Asthma Immunol 91:546-552. McDevitt JJ, Lees PS, Merz WG, Schwab KJ. 2004. Development of a method to detect and quantify Aspergillus fumigatus Aspergillus fumigatus Microbiology The fungal species that is the most common cause of human aspergillosis, which may infect the lungs, invade blood vessels, or disseminate to various organs. See Aspergillosis. conidia co·nid·i·a n. Plural of conidium. by quantitative PCR for environmental air samples. Mycopathologia 158:325-335. McKone TE, Knezovich JP. 1991. The transfer of trichloroethylene (TCE TCE trichloroethylene. TCE Environment A volatile chlorinated hydrocarbon that boils at 88ºC and is highly soluble–1000 ppm in water, with various industrial uses Toxicity Peripheral neuropathy, carcinogenic. ) from a shower to indoor air: experimental measurements and their implications. J Air Waste Manage Assoc 41:832-837. Meklin T, Haugland RA, Reponen T, Varma M, Lummus Z, Bernstein D, et al. 2004. Quantitative PCR analysis of house dust can reveal abnormal mold conditions. J Environ Monit 6:615-620. Meng QY, Turpin BJ, Korn L, Weisel CP, Morandi M, Colome S, et al. 2005. Influence of ambient (outdoor) sources on residential indoor and personal [PM.sub.2.5] concentrations: analyses of RIOPA data. J Expo Anal Environ Epidemiol 15:17-28. Menzies D, Popa J, Hanley JA, Rand T, Milton DK. 2003. Effect of ultraviolet germicidal lights installed in office ventilation systems on workers' health and well-being: double-blind multiple crossover trial. Lancet 362:1785-1791. Meyer HW, Jensen KA, Nielsen KF, Kildeso J, Norn S, Permin H, et al. 2005. Double blind placebo controlled exposure to molds: exposure system and clinical results. Indoor Air 15(suppl 10):73-80. Molhave L, Kjaergaard SK, Sigsgaard T, Lebowitz M. 2005. Interaction between ozone and airborne particulate matter in office air. Indoor Air 15:383-392. Morgan WJ, Crain EF, Gruchalla RS, O'connor GT, Kattan M, Evans R III, et al. 2004. Results of a home-based environmental intervention among urban children with asthma. N Engl J Med 351:1068-1080. Morris RD. 2001. Airborne particulates and hospital admissions for cardiovascular disease Cardiovascular disease Disease that affects the heart and blood vessels. Mentioned in: Lipoproteins Test cardiovascular disease : a quantitative review of the evidence. Environ Health Perspect 109(suppl 4):495-500. Morrison GC, Nazaroff WW. 2002. Ozone interactions with carpet: secondary emissions of aldehydes. Environ Sci Technol 36:2185-2192. Nazaroff WW. 2004. Indoor particle dynamics. Indoor Air 14(suppl 7):175-183. Nazaroff WW, Singer BC. 2004. Inhalation of hazardous air pollutants from environmental tobacco smoke environmental tobacco smoke (ETS/passive smoke), n the gaseous by-product of burning tobacco products, including but not limited to commercially manufactured cigarettes and cigars; contains toxic elements harmful to the health of adults and children in US residences. J Expo Anal Environ Epidemiol 14(suppl 1):S71-S77. Nielsen KF, Huttunen K, Hyvarinen A, Andersen B, Jarvis BB, Hirvonen MR. 2002. Metabolite metabolite, organic compound that is a starting material in, an intermediate in, or an end product of metabolism. Starting materials are substances, usually small and of simple structure, absorbed by the organism as food. profiles of Stachybotrys isolates from water-damaged buildings and their induction of inflammatory mediators and cytotoxicity in macrophages Macrophages White blood cells whose job is to destroy invading microorganisms. Listeria monocytogenes avoids being killed and can multiply within the macrophage. . Mycopathologia 154:201-205. Oie L, Hersoug LG, Madsen JO. 1997. Residential exposure to plasticizers and its possible role in the pathogenesis of asthma. Environ Health Perspect 105:972-978. Ott W, Wallace L, Mage D. 2000. Predicting particulate (PM10) personal exposure distributions using a random component superposition su·per·po·si·tion n. 1. The act of superposing or the state of being superposed: "Yet another technique in the forensic specialist's repertoire is photo superposition" statistical model. J Air Waste Manag Assoc 50:1390-1406. Ott WR, Roberts JW. 1998. Everyday exposure to toxic pollutants. Sci Am 278:86-91. Pandian MD, Behar JV, Ott WR, Wallace LA, Wilson AL, Colome SD, et al. 1998. Correcting errors in the nationwide data base of residential air exchange rates. J Expo Anal Environ Epidemiol 8:577-586. Pauley SM. 2004. Lighting for the human circadian circadian /cir·ca·di·an/ (ser-ka´de-an) denoting a 24-hour period; see under rhythm. cir·ca·di·an adj. Relating to biological variations or rhythms with a cycle of about 24 hours. clock: recent research indicates that lighting has become a public health issue. Med Hypotheses 63:588-596. Pope CA III, Verrier RL, Lovett EG, Larson AC, Raizenne ME, Kanner RE, et al. 1999. Heart rate variability associated with particulate air pollution. Am Heart J 138:890-899. Pope C, Dockery D, Spengler J, Raizenne M. 1991. Respiratory health and [PM.sub.10] pollution: a daily times series analysis. Am Rev Respir Dis 144:668-674. Reiss R, Ryan PB, Tibbetts SJ, Koutrakis P. 1995. Measurement of organic acids, aldehydes, and ketones in residential environments and their relation to ozone. J Air Waste Manag Assoc 45:811-822. Rumchev K, Spickett J, Bulsara M, Phillips M, Stick S. 2004. Association of domestic exposure to volatile organic compounds with asthma in young children. Thorax thorax, body division found in certain animals. In humans and other mammals it lies between the neck and abdomen and is also called the chest. The skeletal frame of the thorax is formed by the sternum (breastbone) and ribs in front and the dorsal vertebrae in back. 59:746-751. Sallis JF, Glanz K. 2006. The role of built environments in physical activity, eating, and obesity in childhood. Future Child 16:89-108. Salthammer T, Bednarek A, Fuhrmann F, Funaki R, Tanabe S-I. 2002. Formation of organic indoor air pollutants by UV-curing chemistry. J Photochem Photobiology photobiology /pho·to·bi·ol·o·gy/ (-bi-ol´ah-je) the branch of biology dealing with the effect of light on organisms.photobiolog´icphotobiolog´ical pho·to·bi·ol·o·gy n. A Chemistry 152:1-9. Samet JM, Spengler JD, Mitchell CS. 1998. Indoor air pollution. In: Environmental and Occupational Medicine (Rom WN, ed). Philadelphia:Lippincott-Raven, 1523-1537. Schmechel D, Simpson JP, Beezhold D, Lewis DM. 2006. The development of species-specific immunodiagnostics for Stachybotrys chartarum: the role of cross-reactivity. J Immunol Methods 309:150-159. Sebastian A, Szponar B, Larsson L. 2005, Characterization of the microbial microbial pertaining to or emanating from a microbe. microbial digestion the breakdown of organic material, especially feedstuffs, by microbial organisms. community in indoor environments by chemical marker analysis: an update and critical evaluation. Indoor Air 15(suppl 9):20-26. Sexton K, Adgate JL, Church TR, Ashley DL, Needham LL, Ramachandran G, et al. 2005. Children's exposure to volatile organic compounds as determined by longitudinal measurements in blood. Environ Health Perspect 113:342-349. Sexton K, Adgate JL, Ramachandran G, Pratt GC, Mongin SJ, Stock TH, et al. 2004. Comparison of personal, indoor, and outdoor exposures to hazardous air pollutants in three urban communities. Environ Sci Technol 38:423-430. Sexton K, Greaves greaves cracklings, an edible raw fat from the meat trade. The skimmings from the preparation of this fat are also called greaves. They represent a low grade of meat meal. IA, Church TR, Adgate JL, Ramachandran G, Tweedie RL, et al. 2000. A school-based strategy to assess children's environmental exposures and related health effects in economically disadvantaged urban neighborhoods. J Expo Anal Environ Epidemiol 10:682-694. Shoemaker RC, House DE. 2005. A time-series study of sick building syndrome: chronic, biotoxin-associated illness from exposure to water-damaged buildings. Neurotoxicol Teratol 27:29-46. Spannhake EW, Reddy SP, Jacoby DB, Yu XY, Saatian B, Tian Tian or T'ien (Chinese; “Heaven”) In indigenous Chinese religion, the supreme power reigning over humans and lesser gods. The term refers to a deity, to impersonal nature, or to both. J. 2002. Synergism synergism /syn·er·gism/ (sin´er-jizm) synergy. syn·er·gism n. Synergy. synergism between rhinovirus rhinovirus Any of a group of picornaviruses capable of causing common colds in humans. The virus is thought to be transmitted to the upper respiratory tract by airborne droplets. infection and oxidant pollutant exposure enhances airway epithelial cell cytokine production. Environ Health Perspect 110:665-670. Stevens RG. 2005. Circadian disruption and breast cancer: from melatonin to clock genes. Epidemiology 16:254-258. Terr AI. 2004. Are indoor molds causing a new disease? J Allergy Clin Immunol 113:221-226. Thatcher TL, Layton DW. 1995. Deposition, resuspension, and penetration of particles within a residence. Atmos Environ 29:1487-1497. Thomas KW, Pellizzari ED, Clayton CA, Whitaker DA, Shores RC, Spengler J, et al. 1993. Particle Total Exposure Assessment Methodology (PTEAM) 1990 study: method performance and data quality for personal, indoor, and outdoor monitoring. J Expo Anal Environ Epidemiol 3:203-226. Tobias KR, Ferriani VP, Chapman MD, Arruda LK. 2004. Exposure to indoor allergens in homes of patients with asthma and/or rhinitis Rhinitis Definition Rhinitis is inflammation of the mucous lining of the nose. Description Rhinitis is a nonspecific term that covers infections, allergies, and other disorders whose common feature is the location of their symptoms. in southeast Brazil: effect of mattress and pillow covers on mite allergen levels. Int Arch Allergy Immunol 133:365-370. Venn AJ, Cooper M, Antoniak M, Laughlin C, Britton J, Lewis SA. 2003. Effects of volatile organic compounds, damp, and other environmental exposures in the home on wheezing illness in children. Thorax 58:955-960. Vesper SJ, Varma M, Wymer LJ, Dearborn DG, Sobolewski J, Haugland RA. 2004. Quantitative polymerase chain reaction analysis of fungi in dust from homes of infants who developed idiopathic pulmonary hemorrhaging. J Occup Environ Med 46:596-601. Viegi G, Simoni M, Scognamiglio A, Baldacci S, Pistelli F, Carrozzi L, et al. 2004. Indoor air pollution and airway disease. Int J Tuberc Lung Dis 8:1401-1415. Vineis P, Husgafvel-Pursiainen K. 2005. Air pollution and cancer: biomarker studies in human populations. Carcinogenesis car·ci·no·gen·e·sis n. The production of cancer. carcinogenesis production of cancer. biological carcinogenesis viruses and some parasites are capable of initiating neoplasia. 26:1846-1855. Wainman T, Weschler CJ, Lioy PJ, Zhang J. 2001. Effects of surface type and relative humidity relative humidity n. The ratio of the amount of water vapor in the air at a specific temperature to the maximum amount that the air could hold at that temperature, expressed as a percentage. on the production and concentration of nitrous acid in a model indoor environment. Environ Sci Technol 35:2201-2206. Wallace L. 1996. Indooor particles: a review. J Air Waste Manag Assoc 46:98-126. Wallace L, Nelson W, Ziegenfus R, Pellizzari E, Michael L, Whitmore R, et al. 1991. The Los Angeles TEAM Study: personal exposures, indoor-outdoor air concentrations, and breath concentrations of 25 volatile organic compounds. J Expo Anal Environ Epidemiol 1:157-192. Weich S, Blanchard M, Prince M, Burton E, Erens B, Sproston K. 2002. Mental health and the built environment: cross-sectional survey of individual and contextual risk factors for depression. Br J Psychiatry 180:428-433. Weisel CP, Zhang J, Turpin BJ, Morandi MT, Colome S, Stock TH, et al. 2005. Relationship of Indoor, Outdoor and Personal Air (RIOPA) Study: study design, methods and quality assurance/control results. J Expo Anal Environ Epidemiol 15:123-137. Weschler CJ. 2004. Chemical reactions among indoor pollutants: what we've learned in the new millennium. Indoor Air 14(suppl 7):184-194. Weschler CJ, Brauer M, Koutrakis P. 1992. Indoor ozone and nitrogen dioxide: a potential pathway to the generation of nitrate radicals, dinitrogen pentaoxide, and nitric acid indoors. Environ Sci Technol 26:179-184. Weschler CJ, Shields HC. 1996. Production of the hydroxyl radical in indoor air. Environ Sci Technol 30:3250-3258. Weschler CJ, Shields HC, Naik DV. 1989. Indoor ozone exposures. JAPCA JAPCA Journal of the Air Pollution Control Association 39:1562-1568. Weschler CJ, Wells JR, Poppendieck D, Hubbard H, Pearce TA. 2006. Workgroup report: indoor chemistry and health. Environ Health Perspect 114:442-446. Xu X, Weisel CP. 2005. Human respiratory uptake of chloroform and haloketones during showering. J Expo Anal Environ Epidemiol 15:6-16. Zhang J, Wilson WE, Lioy PJ. 1994. Sources of organic acids in indoor air: a field study. J Expo Anal Environ Epidemiol 4:25-47. Clifford S. Mitchell, (1) Junfeng (Jim) Zhang, (2) Torben Sigsgaard, (3) Matti Jantunen, (4) Paul J. Lioy, (5) Robert Samson, (6) and Meryl H. Karol (7) (1) Department of Environmental Health Sciences, Johns Hopkins Bloomberg School of Public Health The Johns Hopkins Bloomberg School of Public Health is part of Johns Hopkins University in Baltimore, Maryland, U.S. It was the first institution of its kind in the world. Founded in 1916 by William H. Welch and John D. , Baltimore, Maryland, USA; (2) Department of Environmental and Occupational Health, School of Public Health, University of Medicine and Denistry of New Jersey, Piscataway, New Jersey, USA; (3) Department of Environmental and Occupational Medicine, University of Aarhus History It was founded in 1928 as Universitetsundervisningen i Jylland ("University Teaching in Jutland") in classrooms rented from the Technical College and a teaching corps consisting of one professor of philosophy and four Readers of Danish, English, German and , Aarhus, Denmark; (4) Department of Environmental Health, National Public Health Institute of Finland National Public Health Institute of Finland (NPHI, in Finnish: Kansanterveyslaitos (KTL)) has a duty to promote health and prevent disease. NPHI researches public health and monitors diseases. NPHI also acquires the vaccines paid by the government. , Kuopio, Finland; (5) Department of Environmental and Community Medicine, Robert Wood Johnson Medical School Robert Wood Johnson Medical School (often abbreviated RWJMS) is one of eight schools that comprise the University of Medicine and Dentistry of New Jersey (UMDNJ). RWJMS operates three campuses in New Jersey, in Piscataway, New Brunswick and Camden. , University of Medicine and Denistry of New Jersey, Piscataway, New Jersey, USA; (6) Department of Services and Applied Research, Centraalbureau voor Schimmelcultures The Centraalbureau voor Schimmelcultures, or CBS, is part of the Royal Netherlands Academy of Arts and Sciences. Translated into English, the name means "Central Bureau of Fungal Cultures". The Center is located in the Netherlands. , Utrecht, the Netherlands; (7) Department of Environmental and Occupational Health, School of Public Health, University of Pittsburgh, Pittsburgh, Pennsylvania, USA This article is part of the mini-monograph "Developing Policies to Improve Indoor Environmental Quality." Address correspondence to C.S. Mitchell, Maryland Department of Health and Mental Hygiene, 201 West Preston Street, Room 327, Baltimore, MD 21201 USA. Telephone: (410) 767-7438. Fax: (410) 333-5995. E-mail: cmitchell@dhmh.state.md.us C.S.M. is supported in part by National Institute of Environmental Health Sciences The National Institute of Environmental Health Sciences (NIEHS) is one of 27 Institutes and Centers of the National Institutes of Health (NIH),which is a component of the Department of Health and Human Services (DHHS). The Director of the NIEHS is Dr. David A. Schwartz. (NIEHS NIEHS National Institute of Environmental Health Sciences (NIH, DHHS) ) grant 5P30 ES003819 and National Institute of Occupational and Health Safety grant T42 CCT CCT Circuit CCT Commission Canadienne du Tourisme (Canadian Tourism Commission) CCT Correlated Color Temperature CCT Common Customs Tariff (EU) CCT Certificate of Completion of Training 310419. P.J.L. is supported by NIEHS Center grant P30 ES05022. The authors declare they have no competing financial interests. Received 9 January 2006; accepted 11 July 2006. |
|
||||||||||||||||
Printer friendly
Cite/link
Email
Feedback
Reader Opinion