Exposure assessment of particulate matter for susceptible populations in Seattle. (Research).In this article we present results from a 2-year comprehensive exposure assessment study that examined the particulate matter particulate matter n. Abbr. PM Material suspended in the air in the form of minute solid particles or liquid droplets, especially when considered as an atmospheric pollutant. Noun 1. (PM) exposures and health effects in 108 individuals with and without chronic obstructive pulmonary disease chronic obstructive pulmonary disease n. Abbr. COPD A chronic lung disease, such as asthma or emphysema, in which breathing becomes slowed or forced. (COPD COPD chronic obstructive pulmonary disease. COPD abbr. chronic obstructive pulmonary disease Chronic obstructive pulmonary disease (COPD) ), coronary heart disease coronary heart disease: see coronary artery disease. coronary heart disease or ischemic heart disease Progressive reduction of blood supply to the heart muscle due to narrowing or blocking of a coronary artery (see atherosclerosis). (CHD CHD coronary heart disease. ChD abbr. Latin Chirurgiae Doctor (Doctor of Surgery) CHD, n.pr See disease, coronary heart. CHD canine hip dysplasia. ), and asthma. The average personal exposures to PM with aerodynamic diameters Drug particles for pulmonary delivery are typically characterized by aerodynamic diameter rather than geometric diameter. The velocity at which the drug settles is proportional to the aerodynamic diameter, da. < 2.5 [micro]m (P[M.sub.2.5]) were similar to the average outdoor P[M.sub.2.5] concentrations but significantly higher than the average indoor concentrations. Personal P[M.sub.2.5] exposures in our study groups were lower than those reported in other panel studies of susceptible populations. Indoor and outdoor P[M.sub.2.5], P[M.sub.10] (PM with aerodynamic diameters < 10 [micro]m), and the ratio of P[M.sub.2.5] to P[M.sub.10] were significantly higher during the heating season. The increase in outdoor P[M.sub.10] in winter was primarily due to an increase in the P[M.sub.2.5] fraction. A similar seasonal variation was found for personal P[M.sub.2.5]. The high-risk subjects in our study engaged in an equal amount of dust-generating activities compared with the healthy elderly subjects. The children in the study experienced the highest indoor P[M.sub.2.5] and P[M.sub.10] concentrations. Personal P[M.sub.2.5] exposures varied by study group, with elderly healthy and CHD subjects having the lowest exposures and asthmatic children having the highest exposures. Within study groups, the P[M.sub.2.5] exposure varied depending on residence because of different particle infiltration infiltration /in·fil·tra·tion/ (in?fil-tra´shun) 1. the pathological diffusion or accumulation in a tissue or cells of substances not normal to it or in amounts in excess of the normal. 2. infiltrate (2). efficiencies. Although we found a wide range of longitudinal lon·gi·tu·di·nal adj. Running in the direction of the long axis of the body or any of its parts. correlations between central-site and personal P[M.sub.2.5] measurements, the longitudinal r is closely related to the particle infiltration efficiency. P[M.sub.2.5] exposures among the COPD and CHD subjects can be predicted with relatively good power with a microenvironmental model composed of three microenvironments. The prediction power is the lowest for the asthmatic children. Key words: asthma, CHD, COPD, infiltration efficiency, longitudinal correlation, personal cloud, P[M.sub.2.5], wood smoke. Environ en·vi·ron tr.v. en·vi·roned, en·vi·ron·ing, en·vi·rons To encircle; surround. See Synonyms at surround. [Middle English envirounen, from Old French environner Health Perspect 111:909-918 (2003). doi:10.1289/ehp.6011 available via http://dx.doi.org/ [Online 4 February 2003] ********** Many epidemiologic studies epidemiologic study A study that compares 2 groups of people who are alike except for one factor, such as exposure to a chemical or the presence of a health effect; the investigators try to determine if any factor is associated with the health effect have reported associations between daily morbidity and mortality Morbidity and Mortality can refer to:
EPA abbr. eicosapentaenoic acid EPA, n.pr See acid, eicosapentaenoic. EPA, n. ) 2001]. Most of these studies have relied on central-site PM monitors for information on concentration of PM and other pollutants pollutants see environmental pollution. . Effects have been seen with all size ranges of PM, from total suspended sus·pend v. sus·pend·ed, sus·pend·ing, sus·pends v.tr. 1. To bar for a period from a privilege, office, or position, usually as a punishment: suspend a student from school. particulates [PM with aerodynamic diameters [less than or equal to] 10 [micro]m (P[M.sub.10]) or < 2.5 [micro]m (P[M.sub.2.5])] to ultrafine particles (aerodynamic diameters < 0.1 [micro]m). Several studies indicate that P[M.sub.2.5] may be more strongly associated with some adverse health end points than are the larger size fractions (Katsouyanni et al. 1997; Schwartz et al. 1996; Schwartz and Neas 2000; Woodruff et al. 1997), although other studies suggest that coarse particles are more closely associated with asthma (Lin et al. 2002; Zhang et al. 2002). Premature mortality is usually found in individuals with preexisting pre·ex·ist or pre-ex·ist v. pre·ex·ist·ed, pre·ex·ist·ing, pre·ex·ists v.tr. To exist before (something); precede: Dinosaurs preexisted humans. v.intr. cardiorespiratory car·di·o·res·pi·ra·to·ry adj. Of or relating to the heart and the respiratory system. Adj. 1. cardiorespiratory - of or pertaining to or affecting both the heart and the lungs and their functions; "cardiopulmonary disease (Goldberg et al. 2001; Samet et al. 2000; Schwartz 2000; Sunyer et al. 2000). Morbidity morbidity /mor·bid·i·ty/ (mor-bid´it-e) 1. a diseased condition or state. 2. the incidence or prevalence of a disease or of all diseases in a population. mor·bid·i·ty n. (measured as hospital admissions, lung function decrements, airway airway /air·way/ (-wa) 1. the passage by which air enters and leaves the lungs. 2. a device for securing unobstructed respiration. inflammation inflammation, reaction of the body to injury or to infectious, allergic, or chemical irritation. The symptoms are redness, swelling, heat, and pain resulting from dilation of the blood vessels in the affected part with loss of plasma and leucocytes (white blood , respiratory symptoms or medication use, or cardiac dysfunction dysfunction /dys·func·tion/ (dis-funk´shun) disturbance, impairment, or abnormality of functioning of an organ.dysfunc´tional erectile dysfunction impotence (2). ) is found in individuals with chronic obstructive pulmonary disease (COPD) or heart disease. Children with asthma appear to be more susceptible than adults to air pollution--induced aggravation Any circumstances surrounding the commission of a crime that increase its seriousness or add to its injurious consequences. Such circumstances are not essential elements of the crime but go above and beyond them. (Koenig 1999). Despite the wealth of data supporting associations between health outcomes and PM exposures, there are many gaps in our knowledge. One concern is whether the particle concentration measured at an outdoor monitoring site is, in fact, related to the exposure of people in the community. This concern has been the focus of several panel studies in susceptible subpopulations (Ebelt et al. 2000; Evans et al. 2000; Janssen et al. 2000; Rodes et al. 2001; Rojas-Bracho et al. 2000; Williams et al. 2000a, 2000b). More accurate assessment of exposure to PM, particularly among individuals shown to be susceptible to PM exposure in epidemiologic studies, is a crucial research need (e.g., Moolgavkar et al. 1997; National Research Council 2001; Reichhardt 1995; Styer et al. 1995). This Seattle panel study is one of four panel studies of high-risk subpopulations sponsored by the U.S. Environmental Protection Agency (EPA) that monitored PM and related air pollutants. In these panel studies, groups of subjects were monitored and followed for several seasons to characterize their exposure to PM. Our study included four susceptible study groups: elderly persons who a) were healthy, b) had COPD, or c) had coronary heart disease (CHD), and d) children with asthma. We collected personal, indoor, and outdoor samples for P[M.sub.10], P[M.sub.2.5], 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; , sulfur dioxide sulfur dioxide, chemical compound, SO2, a colorless gas with a pungent, suffocating odor. It is readily soluble in cold water, sparingly soluble in hot water, and soluble in alcohol, acetic acid, and sulfuric acid. , and nitrogen dioxide nitrogen dioxide n. A poisonous brown gas, NO2, often found in smog and automobile exhaust fumes and synthesized for use as a nitrating agent, a catalyst, and an oxidizing agent. Noun 1. during seasons with high and low wood smoke (1999-2001). In this article we focus on characterizing the PM exposure among these four study groups. Study Design Subjects and monitoring sites. We recruited elderly subjects through distribution of flyers throughout the community at such sites as clinics, senior centers, and retirement homes. Children with asthma were recruited from one large asthma and allergy allergy, hypersensitive reaction of the body tissues of certain individuals to certain substances that, in similar amounts and circumstances, are innocuous to other persons. Allergens, or allergy-causing substances, can be airborne substances (e.g. clinic. Our panel included 34 with COPD, 27 with CHD, 28 without any signs or symptoms of cardiorespiratory disease (healthy), all elderly, and 19 children with asthma. These subjects were volunteers and were not selected using probability-based sampling; therefore our results cannot be extrapolated to larger populations. All but one of the elderly subjects were more than 65 years of age; 85% were between 71 and 90 years of age. The children were between 6 and 13 years of age. About 55% of these subjects were reenrolled for monitoring in different seasons within a year. All COPD subjects had physician-diagnosed COPD and had a 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 the first second (FE[V.sub.1]) between 40% and 70% predicted value. All CHD subjects had a history of myocardial infarction myocardial infarction: see under infarction. , angina Angina Definition Angina is pain, "discomfort," or pressure localized in the chest that is caused by an insufficient supply of blood (ischemia) to the heart muscle. , or congestive heart failure congestive heart failure, inability of the heart to expel sufficient blood to keep pace with the metabolic demands of the body. In the healthy individual the heart can tolerate large increases of workload for a considerable length of time. . All asthmatic children had physician-diagnosed mild to moderate asthma and had intermittent intermittent /in·ter·mit·tent/ (-mit´ent) marked by alternating periods of activity and inactivity. in·ter·mit·tent adj. 1. Stopping and starting at intervals. 2. use of rescue medication (albuterol albuterol /al·bu·ter·ol/ (al-bu´ter-ol) a ß agonist used as the base or sulfate salt as a bronchodilator. al·bu·ter·ol n. ). All subjects were nonsmokers living with nonsmokers, and they usually spent more than 30 min a day outdoors. Most of the COPD and healthy subjects lived in either group homes or private residences. Most of the cardiac subjects lived in private homes or apartments. All but one of the children lived in private homes. Monitoring period. This study was conducted in 26 monitoring sessions, including 13 sessions in each monitoring year: Year 1 (October 1999-August 2000) and Year 2 (September 2000-May 2001) (Table 1). Each session consisted of 10 consecutive monitoring days; starting at 1600 hr ([+ or -] 2 hr) on Tuesdays and ending at 1600 hr ([+ or -] 2 hr) on Fridays. Up to nine subjects (mean [+ or -] SD, 6 [+ or -] 2) per session were monitored simultaneously. The average temperature, 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. , and wind speed were slightly higher in Year 1 (temperature = 9.9 [+ or -] 4.6[degrees]C; relative humidity = 79.3 [+ or -] 8.4%; wind speed = 5.5 [+ or -] 0.9 m/sec) than in Year 2 (temperature = 7.9 [+ or -] 4.2[degrees]F; relative humidity = 78.7 [+ or -] 10.6%; wind speed = 4.7 [+ or -] 1.9 m/sec), whereas the daily average hours of stagnation Stagnation A period of little or no growth in the economy. Economic growth of less than 2-3% is considered stagnation. Sometimes used to describe low trading volume or inactive trading in securities. Notes: A good example of stagnation was the U.S. economy in the 1970s. (wind speed < 1.8 m/sec) was higher in Year 2 (11.6 [+ or -] 6.2 hr) than in Year 1 (8.8 [+ or -] 6.2 hr). Personal monitoring. Personal P[M.sub.2.5] exposures were determined using the Harvard Personal Environmental Monitor for P[M.sub.2.5] (HPE (Home Premium Edition) See Windows Vista versions. [M.sub.2.5]; Harvard School of Public Health The Harvard School of Public Health is (colloquially, HSPH) is one of the professional graduate schools of Harvard University. Located in Longwood Area of the Boston, Massachusetts neighborhood of Mission Hill, next to Harvard Medical School and Cambridge, Massachusetts, , Boston, MA). The small HPE[M.sub.2.5] is a single-stage inertial in·er·tia n. 1. Physics The tendency of a body to resist acceleration; the tendency of a body at rest to remain at rest or of a body in straight line motion to stay in motion in a straight line unless acted on by an outside force. impactor with a 50% cut point of 2.4 [+ or -] 0.1 [micro]m (Sioutas et al. 1999). The HPE[M.sub.2.5] was connected to a personal pump (AFC (1) (Application Foundation Classes) A class library from Microsoft that provides an application framework and graphics, graphical user interface (GUI) and multimedia routines for Java programmers. 400S; BGI BGI Barclays Global Investors BGI Bainbridge Graduate Institute BGI Bureau Gravimétrique International BGI Borland Graphic Interface (File Name Extension) BGI Bridgetown, Barbados - Grantley Adams International , Inc., Waltham, MA) with a mass flow controller A mass flow controller (MFC) is a device used to measure and control the flow of gases. A mass flow controller is designed and calibrated to control a specific type of gas at a particular range of flow rates. operated at 4 L/min. Particles> 2.5 [micro]m in diameter were originally collected on a porous porous /por·ous/ (por´us) penetrated by pores and open spaces. po·rous adj. 1. Full of or having pores. 2. Admitting the passage of gas or liquid through pores. metal impaction plate coated with silicon oil immediately downstream of the inlet inlet /in·let/ (-let) a means or route of entrance. pelvic inlet the upper limit of the pelvic cavity. thoracic inlet the elliptical opening at the summit of the thorax. ; particles < 2.5 [micro]m bypassed the impaction plate and were collected on a 37-mm Teflon filter (polytetrafluoroethylene polytetrafluoroethylene a synthetic material commonly used as a nonstick lining in domestic cooking utensils (frypans); abbreviated PTFE; called also Teflon. Overheating produces toxic fumes that cause an acute hemorrhagic pneumonitis and death in small caged birds, which are with support ring, model 225-1709; SKC SKC Salish Kootenai College (Pablo, MT) SKC Sky Clear (Meteorology) SKC St Kevin's College (Melbourne, Victoria-Australia) SKC Chief Storekeeper , Inc., Eighty Four, PA). Because of an oil contamination problem, the entire porous metal plate was replaced with silicon vacuum grease Vacuum grease is a lubricant with low volatility and is used for applications in low pressure environments. Lubricants with higher volatility would evaporate, causing two problems:
Each subject carried an HPE[M.sub.2.5] in the breathing zone for 24 hr, except while sleeping, showering, or using the restroom. The monitor was attached to the shoulder strap of either a backpack or a fanny pack that contained the air pump. When the monitor was not worn, it was placed at an elevation elevation, vertical distance from a datum plane, usually mean sea level to a point above the earth. Often used synonymously with altitude, elevation is the height on the earth's surface and altitude, the height in space above the surface. of 3-5 feet (e.g., on a table) close to the subjects. Our field technicians visited the subjects daily to calibrate To adjust or bring into balance. Scanners, CRTs and similar peripherals may require periodic adjustment. Unlike digital devices, the electronic components within these analog devices may change from their original specification. See color calibration and tweak. the pumps with a digital piston flow meter flow meter Device that measures the velocity of a gas or liquid. It has applications in medicine as well as in chemical engineering, aeronautics, and meteorology. Examples include pitot tubes, venturi tubes, and rotameters (tapered graduated tubes with a float inside that is (Drycal, DC-Lite; SKC Inc.), and later with a rotameter (model 92-04; Cole-Parmer Instrument Co., Vernon Hills Vernon Hill II (born circa 1946) is the founder and former chairman, president, and chief executive officer of Commerce Bancorp and Commerce Bank of Cherry Hill Township, New Jersey. , IL), and to record on and off flow rates and change samplers. Fixed-site monitoring. The indoor and outdoor PM concentrations were measured with single-stage inertial Harvard Impactors (HI) (Air Diagnostics and Engineering, Inc., Naples, ME) and 37-mm Teflon filters for P[M.sub.10] and P[M.sub.2.5] (Marple et al. 1987). One H[I.sub.2.5]-H[I.sub.10] pair was located inside each home in the main activity room and connected to a Medo pump (model vp0935a; Medo USA, Inc., Hanover Park, IL). Concurrently, one H[I.sub.2.5]-H[I.sub.10] pair was located outside each home and connected to a Gast pump (model DOA-V191-AA; Gast Manufacturing, Inc., Benton Harbor Benton Harbor, city (1990 pop. 12,818), Berrien co., SW Mich., on Lake Michigan at the mouth of the St. Joseph River opposite St. Joseph; inc. 1869. A long-time fruit industry, tourist, and industrial center, noted for appliance manufacturing, the city declined in , MI). The on and off flow rates were calibrated cal·i·brate tr.v. cal·i·brat·ed, cal·i·brat·ing, cal·i·brates 1. To check, adjust, or determine by comparison with a standard (the graduations of a quantitative measuring instrument): and recorded daily with the flow meter and later with a Cole-Parmer rotameter (model 34-39). All HI sampling periods were for 24 hr at a flow rate of 10 L/min. H[I.sub.2.5], H[I.sub.10], and HPE[M.sub.2.5] were also collocated with the federal reference method monitor for P[M.sub.2.5] (FR[M.sub.2.5]) at the central Beacon Hill Bea·con Hill An area of Boston, Massachusetts, noted for its historic residences, brick sidewalks, and picturesque mews. Noun 1. Beacon Hill - a fashionable section of Boston; site of the Massachusetts capital building site, which is located in a semiresidential area (elevation, 300 feet) and is maintained by the Washington State Department of Ecology ecology, study of the relationships of organisms to their physical environment and to one another. The study of an individual organism or a single species is termed autecology; the study of groups of organisms is called synecology. . This site has been validated val·i·date tr.v. val·i·dat·ed, val·i·dat·ing, val·i·dates 1. To declare or make legally valid. 2. To mark with an indication of official sanction. 3. as representative of the regional air quality in urban Seattle (Goswami et al. 2002). Duplicate DUPLICATE. The double of anything. 2. It is usually applied to agreements, letters, receipts, and the like, when two originals are made of either of them. Each copy has the same effect. sets of central-site HPE[M.sub.2.5], H[I.sub.2.5], and H[I.sub.10] were running at the same schedule as those at home sites (1600 hr to 1600 hr) for estimating precision. One central-site H[I.sub.2.5]-HPE[M.sub.2.5] pair ran from midnight to midnight to coincide with the FR[M.sub.2.5] measurements. Filter analysis. All filter weights were measured in either duplicate or triplicate using a seven-place electronic ultramicrobalance (model UMT UMT University of Management and Technology (Lahore, Pakistan) UMT Unit Ministry Team UMT Universal Military Training UMT Union Marocaine du Travail (French: Union of Moroccan Workers) UMT Uranium Mill Tailings 2; Mettler Toledo Mettler-Toledo is a manufacturer of scales and analytical instruments. It is the combination of two companies: Mettler, based in Switzerland, and Toledo Scale, based in Columbus, Ohio, USA. , Greifensee, Switzerland). The filters were equilibrated for at least 24 hr before weighing. Both equilibration equilibration /equi·li·bra·tion/ (e-kwil?i-bra´shun) the achievement of a balance between opposing elements or forces. occlusal equilibration and weighing were performed inside a controlled environmental chamber with constant relative humidity (34.7 [+ or -] 2.5%) and temperature (22.4 [+ or -] 1.9[degrees]C) (Allen et al. 2001). Before weighing, the filters were passed between two polonium-210 strips (500 [micro]Ci) to eliminate any electrostatic charge Noun 1. electrostatic charge - the electric charge at rest on the surface of an insulated body (which establishes and adjacent electrostatic field) electric charge, charge - the quantity of unbalanced electricity in a body (either positive or negative) and on the filter. Each day, before the weighing sessions, the microbalance mi·cro·bal·ance n. A balance designed to weigh very small loads, up to 0.1 gram. Noun 1. microbalance - balance for weighing very small objects balance - a scale for weighing; depends on pull of gravity was calibrated internally and externally with four certified See certification. stainless steel stainless steel: see steel. stainless steel Any of a family of alloy steels usually containing 10–30% chromium. The presence of chromium, together with low carbon content, gives remarkable resistance to corrosion and heat. weights (20, 50, 100, and 200 mg) to further validate To prove something to be sound or logical. Also to certify conformance to a standard. Contrast with "verify," which means to prove something to be correct. For example, data entry validity checking determines whether the data make sense (numbers fall within a range, numeric data the internal calibration calibration /cal·i·bra·tion/ (kal?i-bra´shun) determination of the accuracy of an instrument, usually by measurement of its variation from a standard, to ascertain necessary correction factors. . Other information. At the beginning of each sampling session, technicians gathered information on the dwelling dwelling an abnormality of gait in a horse in which there is a momentary hesitation before the foot is placed on the ground. (apartment, home, etc.), proximity to a busy roadway, type of parking garage, and type of heating (forced air, radiator radiator, device used to heat an area surrounding it or to cool a fluid circulating within it. The familiar radiators of steam and hot water heating systems in buildings are misnamed, as they operate principally by convection, in which heat is transferred by air , fireplace fireplace Opening made in the base of a chimney to hold an open fire. The opening is framed, usually ornamentally, by a mantel (or mantelpiece). A medieval development that replaced the open central hearth for heating and cooking, the fireplace was sometimes large enough to , etc.). During the study, each subject kept a diary of time, activity, and location with a 15-min resolution. The diary provided sufficient room to specify minutes used for each activity if more than one activity was conducted within the 15-min interval. In addition, technicians recorded occurrence of events that would potentially affect PM concentrations at homes, including window opening, type of cooking, incense incense, perfume diffused by the burning of aromatic gums or spices. Incense was used in ancient Egypt, Greece, and Rome and is mentioned in the Old and the New Testaments. It is also found in the major religions of Asia. burning, and house cleaning, among others. These questionnaires were developed especially for the four panel studies sponsored by the U.S. EPA and were approved by its Office of Management and Budget The Office of Management and Budget (OMB), formerly the Bureau of the Budget, is an agency of the federal government that evaluates, formulates, and coordinates management procedures and program objectives within and among departments and agencies of the Executive Branch. . Data reduction. All data were examined for irregularity A defect, failure, or mistake in a legal proceeding or lawsuit; a departure from a prescribed rule or regulation. An irregularity is not an unlawful act, however, in certain instances, it is sufficiently serious to render a lawsuit invalid. and noncompliance noncompliance failure of the owner to follow instructions, particularly in administering medication as prescribed; a cause of a less than expected response to treatment. noncompliance with our standard operating procedures standard operating procedure Medtalk A technique, method or therapy performed 'by the book,' using a standard protocol meeting internally or externally defined criteria; a formal, written procedure that describes how specific lab operations are to be performed. . Samples were flagged and removed when the flow rates fell outside 10% of the designated flow rate. Most flagged samples, including 4.6% of HI samples and 9% of HPEM HPEM High Power Electromagnetics samples, were due to pump or battery failure, broken filters, or disconnected tubing. Results Quality control. The total number of field blanks was between 10% and 26% of the total sample size. The limit of detection (LOD Lod (lōd), city (1994 pop. 51,200), central Israel. It is also known as Lydda. Its manufactures include paper products, chemicals, oil products, electronic equipment, processed food, and cigarettes. ) was calculated as three times the standard deviation In statistics, the average amount a number varies from the average number in a series of numbers. (statistics) standard deviation - (SD) A measure of the range of values in a set of numbers. of the field blanks. The LOD for the 24-hr integrated HI was 1 [micro]g/[m.sup.3]; for the 24-hr integrated HPE[M.sub.2.5], the LOD was 6.2 [micro]g/[m.sup.3] for the first four sessions and 4.5 [micro]g/[m.sup.3] afterward af·ter·ward also af·ter·wards adv. At a later time; subsequently. Adv. 1. afterward - happening at a time subsequent to a reference time; "he apologized subsequently"; "he's going to the store but he'll be back here . This reduction was achieved by replacing the oiled porous impaction plate with vacuum grease to reduce contamination from silicon oil (Demokritou et al. 2001), and adding a drain disk downstream of the Teflon filter. This 4.5 [micro]g/[m.sup.3] LOD for HPE[M.sub.2.5] is similar to values (2.6-4.0 [micro]g/[m.sup.3]) reported by Sarnat et al. (2000). The total number of field duplicates ranged between 18% and 29% of total sample size. All duplicates were highly correlated cor·re·late v. cor·re·lat·ed, cor·re·lat·ing, cor·re·lates v.tr. 1. To put or bring into causal, complementary, parallel, or reciprocal relation. 2. with each other, with a Pearson's r of [greater than or equal to] 0.96. The mean difference between the duplicates was not significantly different from zero. The precision, calculated as the standard deviation of duplicate differences divided by the square root of 2, was 1.2 [micro]g/[m.sup.3] for HI and 2.2 [micro]g/[m.sup.3] for HPE[M.sub.2.5]. The accuracy of our P[M.sub.2.5] measurements was calculated by comparing them with the collocated FR[M.sub.2.5] measurements at the central site (Figure 1A). We also collocated H[I.sub.2.5] and HPE[M.sub.2.5] whenever possible: 77 pairs at the stationary Stationary can mean:
n. 1. Soft or melted animal fat, especially after rendering. 2. A thick oil or viscous substance, especially when used as a lubricant. 3. a. The oily substance present in raw wool; suint. impaction plate, the bias is negligible  This article or section is written like a personal reflection or and may require .Please [ improve this article] by rewriting this article or section in an . (0.4 [micro]g/[m.sup.3]; p = 0.08). All HI and HPEM measurements were corrected for average blank values. The HPE[M.sub.2.5] measurements with oiled impaction plates during the first four monitoring sessions (n = 269 out of 1,347 personal filters) were removed from the following analysis because of the oil contamination problem. [FIGURE 1 OMITTED] Summary statistics. Table 2 summarizes concentrations of P[M.sub.2.5] and P[M.sub.10] for the four study groups and four microenvironments. Because all measurements are skewed skewed curve of a usually unimodal distribution with one tail drawn out more than the other and the median will lie above or below the mean. skewed Epidemiology adjective Referring to an asymmetrical distribution of a population or of data to the right, geometric means (mathematics) geometric mean - The Nth root of the product of N numbers. If each number in a list of numbers was replaced with their geometric mean, then multiplying them all together would still give the same result. (GMs) and geometric standard deviations In probability theory and statistics, the geometric standard deviation describes how spread out are a set of numbers whose preferred average is the geometric mean. If the geometric mean of a set of numbers is denoted as μg (GSDs) are reported along with the arithmetic means (mathematics) arithmetic mean - The mean of a list of N numbers calculated by dividing their sum by N. The arithmetic mean is appropriate for sets of numbers that are added together or that form an arithmetic series. . Although for all study groups the mean personal exposures and indoor and outdoor concentrations of P[M.sub.2.5] were below the new National Ambient Air Quality Standard (NAAQS NAAQS National Ambient Air Quality Standards ) (U.S. EPA 2001) for the annual P[M.sub.2.5] average (15 [micro]g/[m.sup.3]), individual 10-day exposures exceeded the annual NAAQS for 12% of the elderly and 42% of the child subjects. The average indoor P[M.sub.2.5] levels were < 10 [micro]g/[m.sup.3], whereas average indoor P[M.sub.10] levels were between 10 and 20 [micro]g/[m.sup.3]. Personal P[M.sub.2.5] concentrations were similar to outdoor P[M.sub.2.5] concentrations (mean difference [+ or -] SD = 0.3 [+ or -] 8.3; p = 0.29, paired t-test) but significantly higher than indoor concentrations (p < 0.0001). Indoor P[M.sub.2.5] concentrations were significantly lower than those outdoors (p < 0.0001). The difference between P[M.sub.10] and P[M.sub.2.5] measurements (coarse particles, P[M.sub.2.5-10]) was approximately 5 [micro]g/[m.sup.3] for both indoor and outdoor environments for all study groups, except inside asthmatic children's residences, where the mean P[M.sub.2.5-10] was double (10.2 [micro]g/[m.sup.3]). P[M.sub.2.5] was on average 61% of the P[M.sub.10] mass both indoors and outdoors in Year 1. In Year 2, when more homes were located in wood-smoke-affected neighborhoods (Larson et al. 1989), the mean home outdoor and indoor P[M.sub.2.5]:P[M.sub.10] ratios were significantly higher (p < 0.001), whereas the central-site P[M.sub.2.5]:P[M.sub.10] ratio remained the same across years (Table 3). Both the indoor and outdoor P[M.sub.2.5]:P[M.sub.10] ratios were significantly higher (p < 0.001) during the heating season (October through February), when wood smoke was dominant (Maykut et al. 2001), with home outdoor P[M.sub.2.5] accounting for 70% of the outdoor P[M.sub.10] mass. Figure 2A shows P[M.sub.2.5] measurements obtained from same subjects and locations in both the heating and nonheating seasons. A significant seasonal effect was detected for all locations (p < 0.0001, paired t-test), with the outdoor locations showing the most prominent seasonal effect. Higher variability in P[M.sub.2.5] measurements was observed at fixed locations (indoor, outdoor, and the central site) during the heating season than during the nonheating season. In contrast, the variability in personal P[M.sub.2.5] measurements was similar during both seasons. P[M.sub.10] concentrations also elevated during the heating season (p < 0.01) for all locations (Figure 2B). For outdoor particles, the increase in P[M.sub.10] during the heating season was accompanied by a significant increase in the coarse fraction (p < 0.0001). For indoor particles, the increase in P[M.sub.10] was entirely due to the increase in the fine fraction because the P[M.sub.2.5-10] levels were identical in both seasons (p = 0.25). [FIGURE 2 OMITTED] Relationships among measurements. Figure 3A shows the cumulative probability plots of P[M.sub.2.5] measurements at four microenvironments with indoor P[M.sub.2.5] consistently lower than personal and outdoor P[M.sub.2.5]. The personal median is about the same as that of the outdoor or central-site measurements. For P[M.sub.10], the home indoor and outdoor measurements are very similar above the 50th percentile percentile, n the number in a frequency distribution below which a certain percentage of fees will fall. E.g., the ninetieth percentile is the number that divides the distribution of fees into the lower 90% and the upper 10%, or that fee level (Figure 3B). Above the 90th percentile, indoor P[M.sub.10] often exceeded outdoor P[M.sub.10]. The highest correlation for the P[M.sub.2.5] measurements was between the home outdoor and central-site measurements (r = 0.84) (Table 4). Personal P[M.sub.2.5] correlated best with indoor P[M.sub.2.5] (r = 0.65) and less so with outdoor and central-site P[M.sub.2.5]. Indoor PM correlated with both outdoor and central-site PM, with higher correlations found for P[M.sub.2.5] than for P[M.sub.10]. Outdoor P[M.sub.10] and P[M.sub.2.5] showed comparable correlations between sites (0.82 vs. 0.84) because the majority of the P[M.sub.10] consists of P[M.sub.2.5]. All P[M.sub.2.5] measurements are highly correlated with the collocated P[M.sub.10] measurements, again indicating a predominant pre·dom·i·nant adj. 1. Having greatest ascendancy, importance, influence, authority, or force. See Synonyms at dominant. 2. portion of P[M.sub.2.5] in P[M.sub.10]. [FIGURE 3 OMITTED] The longitudinal (Pearson's) correlation between personal P[M.sub.2.5] exposures and central-site measurements for each subject, calculated over the 10 consecutive 24-hr monitoring days and for at least six valid pairs of measurements, ranged between -0.57 and 0.98 (Figure 4A), with a median of 0.34. One issue in presenting such longitudinal correlations is the limited number of observations per subject and thus an overly broad distribution compared with the true distribution, particularly at the low end. The shrunk shrunk v. A past tense and a past participle of shrink. shrunk Verb a past tense and past participle of shrink shrunk, shrunken shrink correlation estimates (Lumley T, Liu L-JS. Unpublished data), by modifying slightly the upper end and significantly the lower end of the crude correlations by an appropriate amount (Figure 4B), give a more representative underlying distribution. The shrunk r estimates ranged between 0.10 and 0.82, with a median of 0.43. The correlation between the crude and shrunk correlations is 0.98. There were no significant differences among study groups in either the crude or shrunk longitudinal r (p = 0.43). [FIGURE 4 OMITTED] We used analysis of variance (ANOVA anova see analysis of variance. ANOVA Analysis of variance, see there ) to examine factors that may affect the crude longitudinal r, including age, sex, activity pattern (e.g., time spent outdoors), home type, and the estimated particle infiltration efficiency ([F.sub.inf]) (Allen R, Larson T, Wallace L, Liu L-JS. Unpublished data). [F.sub.inf], a unitless quantity defined as the equilibrium fraction of ambient PM that penetrates indoors and remains suspended (Wilson et al. 2000), is one of the most important parameters for estimating personal exposure to ambient PM. It is a function of air exchange rate (a), particle penetration (p), and particle decay Particle decay is the spontaneous process of one elementary particle transforming into other elementary particles. During this process, an elementary particle becomes a different particle with less mass and a W boson. The W boson then transforms into other particles. rate (k): [1] [F.sub.inf] = pa/a + k. We estimated [F.sub.inf] using the recursive See recursion. recursive - recursion model (Switzer and Ott 2001) with continuous nephelometer nephelometer /neph·e·lom·e·ter/ (nef?il-om´it-er) an instrument for measuring the concentration of substances in suspension by means of light scattering by the suspended particles. neph·e·lometer n. measurements taken concurrently with HI measurements (Allen R, Larson T, Wallace L, Liu L-JS. Unpublished data). The [F.sub.inf] estimates, available for 55 home sites, ranged between 0.07 and 1.00, with a mean [+ or -] SD of 0.57 [+ or -] 0.23 and a median of 0.64 (Allen R, Larson T, Wallace L, Liu L-JS. Unpublished data). [F.sub.inf] is the only important predictor for the longitudinal r (r= 0.30; n = 33; p = 0.09). Time--activity pattern. Table 5 shows the average percentage of the 24-hr day spent in different microenvironments as reported in subjects' time--activity diaries. On average, asthmatic subjects spent 66% of the time at home indoors and 21% indoors away from home (mostly at school). Elderly subjects spent between 83% and 88% of the time inside their homes and between 6% and 8% of the time indoors away from home. As expected, asthmatic children spent more time outdoors (4.7 [+ or -] 3.5%) compared with all elderly subjects (0.9-1.7%; p < 0.0001, F-test). We analyzed an·a·lyze tr.v. an·a·lyzed, an·a·lyz·ing, an·a·lyz·es 1. To examine methodically by separating into parts and studying their interrelations. 2. Chemistry To make a chemical analysis of. 3. time--activity patterns by age, sex, and health condition (Table 6). For elderly adults, the healthy group was used as the baseline for comparison. ANOVA analysis shows that percentage of time spent indoors at home was significantly affected by health condition and age among elderly subjects. The COPD group spent an average of 5% more time inside their homes than did the healthy group. For every 1-year increase in age, the time spent indoors also increased by 0.7%. For asthmatic children, the age effect is significant but negative. The COPD group spent an average of 0.7% less time outdoors than did the healthy elderly cohort cohort /co·hort/ (ko´hort) 1. in epidemiology, a group of individuals sharing a common characteristic and observed over time in the group. 2. , and every 1-year increase in age decreased the time spent outdoors by 0.06%. For time spent outdoors by asthmatic children, the significant predictor was session (a surrogate surrogate n. 1) a person acting on behalf of another or a substitute, including a woman who gives birth to a baby of a mother who is unable to carry the child. 2) a judge in some states (notably New York) responsible only for probates, estates, and adoptions. for time of year), not age. We also examined minutes spent conducting various potential PM-generating activities versus health conditions, age, and sex, while controlling for the session effect (Tables 5 and 6). Indoor activities included cooking, dusting, vacuuming, sweeping, tidying up, and washing windows. Outdoor activities included exercise, yard work, painting, and so on, and in-transit included walking, riding a car, and so forth. The only activity that differed by elderly group was the time spent in transit, with the COPD group spending an average of 11 [+ or -] 2 min less than other elderly groups in transit, after controlling for the session effect (p < 0.05). Among the elderly groups, time spent on indoor and outdoor activities was significantly different by sex and age but not by study group. Elderly female subjects spent 18 [+ or -] 5 min more per day conducting indoor activities than did male subjects (p < 0.001). The older they were, the fewer indoor activities they conducted (-1.5 [+ or -] 0.4 min/year; p < 0.001). Minutes spent doing outdoor activities were significantly affected by sex in the opposite direction, with female elderly subjects spending 6 [+ or -] 3 min fewer being active outdoors (p < 0.05). Effects of health condition, age, and sex on personal P[M.sub.2.5]. Personal P[M.sub.2.5] exposures ([C.sub.p]) were examined for all study groups while controlling for home outdoor P[M.sub.2.5] concentration ([C.sub.0]), home type (H), session (S), and the group x H interaction effects. We used the following fixed-effect model: [2] [C.sub.p] = [mu] + group + [C.sub.0] + S + H + group x H + [epsilon], where [mu] is the overall mean and [epsilon] is the error term. The session effect accounts for any systematic differences between sessions, such as changes in neighborhood or subject cluster that could not be accounted for by [C.sub.0]. Age was not included in this analysis because the age range in children was far more limited (6-13 years) than that in adults. The healthy elderly group and private homes were used as the references in the model. Results show that personal P[M.sub.2.5] exposures differed significantly by group, with that of the asthmatic group 5.6 [micro]g/[m.sup.3] greater, and the COPD group 3.5 [micro]g/[m.sup.3] greater, than the healthy elderly group (Table 7). There are significant interactions between home type and group. The COPD subjects living in group homes or private apartments had lower P[M.sub.2.5] exposure than did other COPD subjects living in private homes, whereas the reverse was true for the CHD subjects. The interaction effects canceled each other such that the home effect is not significant. This model also estimated that an average of 39% of outdoor P[M.sub.2.5] contributed to personal P[M.sub.2.5]. Among the elderly subjects, age is an important factor affecting personal exposure. For elderly subjects, personal P[M.sub.2.5] exposure was significantly reduced by 0.23 [micro]g/[m.sup.3] for each year of age increase (Table 7). Age is not a significant predictor for personal PM exposure among asthmatic children, most likely because of the small age range among subjects. Microenvironmental modeling and personal cloud. We used a microenvironmental model (Ozkaynak et al. 1996) with three microenvironments to predict personal exposures to P[M.sub.2.5]. The three microenvironments are indoor (including home, work, and other places), outdoor near home, and outdoor away from home. The model predicts personal exposures ([C.sub.p]) by summing up time-weighted exposures from each microenvironment microenvironment /mi·cro·en·vi·ron·ment/ (-en-vi´ron-ment) the environment at the microscopic or cellular level. : [3] [C.sub.p] = ([C.sub.i] x [F.sub.i]) + ([C.sub.0] x [F.sub.0]) + ([C.sub.00] x [F.sub.00]), where [C.sub.i], [C.sub.0], and [C.sub.00] are P[M.sub.2.5] concentrations measured indoors at home, outdoors at home, and at the central site, respectively. [F.sub.i], [F.sub.0], and [F.sub.00] are fractions of the 24-hr day spent indoors at all locations, outdoors near home, and outdoors away from home, respectively. This model does not include personal cloud (or, equivalently, the error term), whereas in the earlier model (Equation 2) the error term appears explicitly. Technically, the C values in Equation 3 should be averaged only during the time the person is in that microenvironment, but in fact only 24-hr averages were available for all three C values. This is not much of a problem for the last two terms because of slow-changing outdoor C values and very small F values. However, it may be problematic if [F.sub.i] includes a fair amount of time at school or work, where the concentration is unknown, which may introduce an additional source of error. This model predicts exposures of the elderly groups relatively well (Table 8). When the model predictions were regressed against measured personal exposures, this microenvironmental model predicts between 45% and 62% of the variability in measured elderly P[M.sub.2.5] exposures. The percentage of variation explained was the highest for elderly CHD and COPD groups, due to the limited microenvironments encountered and personal activities. The lowest prediction power was observed for the children's asthmatic group ([R.sup.2] = 0.09), due in part to the fact that the home indoor P[M.sub.2.5] measurements were used as a surrogate for the P[M.sub.2.5] levels away from home. Some of the unexplained unexplained Adjective strange or unclear because the reason for it is not known Adj. 1. unexplained - not explained; "accomplished by some unexplained process" variability is likely due to the so-called "personal cloud." We define the personal cloud as the difference between the predicted and measured personal PM exposures. The personal cloud is a combined result of particles generated from personal activities (e.g., cooking or dusting) and exposures to local sources (e.g., next to traffic exhaust on the street) that are not captured by the stationary indoor and outdoor monitors. When using the intercepts of the regression regression, in psychology: see defense mechanism. regression In statistics, a process for determining a line or curve that best represents the general trend of a data set. models as estimates for the personal clouds, asthmatic children had the highest personal cloud (9.6 [micro]g/[m.sup.3]), and elderly groups had similar low personal clouds (1.1, 2.2, and 2.4 [micro]g/[m.sup.3] for CHD, COPD, and healthy elderly groups, respectively). However, when using the difference between the measured and the modeled personal exposures, the personal cloud is much lower for asthmatic children (3.9 [micro]g/[m.sup.3]) and comparable for elderly (1.7, 2.3, and 1.3 for CHD, COPD, and the healthy elderly groups, respectively). The personal cloud, estimated using the difference between the predicted and measured values, differed significantly by group. For elderly subjects, the most important factors contributing to the personal cloud are the time (in minutes) spent outside running errands, cooking indoors, and in the yard outdoors (Table 9). For the asthmatic group, the most important factors are the time (in minutes) spent at school in class/library and in the bus or shuttle (Table 9). Waiting on the roadside for buses/cars is only marginally significant. The personal cloud was also negatively correlated with the longitudinal r (r = -0.11, p < 0.01) and was affected by the type of residence. Subjects living in group homes or private apartments had 1.1 [micro]g/[m.sup.3] or 1.5 [micro]g/[m.sup.3] lower personal cloud, respectively, than did those living in private homes. This could be due to the fact that more active subjects lived in private homes. As expected, the particle infiltration efficiency does not affect the personal cloud (p = 0.75). Discussion The average personal P[M.sub.2.5] exposures among sensitive subpopulations in Seattle were similar to the mean outdoor P[M.sub.2.5] concentration but significantly higher than that indoors. Our elderly subjects' personal P[M.sub.2.5] exposure (GM = 7.7-8.8 [micro]g/[m.sup.3]) was lower than those observed among elderly subjects in previous studies living in nonsmoking non·smok·ing adj. 1. Not engaging in the smoking of tobacco: nonsmoking passengers. 2. Designated or reserved for nonsmokers: the nonsmoking section of a restaurant. homes (Ebelt et al. 2000; Evans et al. 2000; Janssen et al. 2000; Williams et al. 2000a, 2000b). This is most likely due to the low ambient P[M.sub.2.5] in Seattle. The GM of 17 elderly COPD subjects in Vancouver, British Columbia British Columbia, province (2001 pop. 3,907,738), 366,255 sq mi (948,600 sq km), including 6,976 sq mi (18,068 sq km) of water surface, W Canada. Geography , was 10.8 [micro]g/[m.sup.3] (Ebelt et al. 2000); the median of 18 elderly COPD subjects in Boston, Massachusetts “Boston” redirects here. For other uses, see Boston (disambiguation). Boston is the capital and most populous city of Massachusetts.[3] The largest city in New England, Boston is considered the unofficial economic and cultural center of the entire New , was 15.5-18.5 [micro]g/[m.sup.3] (Rojas-Bracho et al. 2000); the median of 15 healthy senior citizens in Baltimore, Maryland "Baltimore" redirects here. For the surrounding county, see Baltimore County, Maryland. For other uses, see Baltimore (disambiguation). Baltimore is an independent city located in the state of Maryland in the United States. , was between 14.5 and 23.1 [micro]g/[m.sup.3] (Sarnat et al. 2000); the GM of 21 elderly subjects (6 healthy, 4 COPD, 11 CHD) in Baltimore was 12.4 [micro]g/[m.sup.3] (Williams et al. 2000a, 2000b); the GM was 11.4 [micro]g/[m.sup.3] for five healthy elderly subjects during winter 1999 and 10.8 [micro]g/[m.sup.3] for 16 elderly subjects during spring 1999 in Fresno, California “Fresno” redirects here. For other uses, see Fresno (disambiguation). Fresno is the sixth-largest city in California and the county seat of Fresno County, with an official Census Bureau estimated population of 481,035 as of July 1, 2006. (Evans et al. 2000); the median was 15.3 [micro]g/[m.sup.3] for 37 CHD subjects in Amsterdam and 10.0 [micro]g/[m.sup.3] for 47 CHD in Helsinki (Janssen et al. 2000). The personal P[M.sub.2.5] exposure in the asthmatic children in our study, who lived in nonsmoking households in Seattle (arithmetic mean, 13.3 [micro]g/[m.sup.3]), was also lower than those found elsewhere. The arithmetic mean was 24.4 [micro]g/[m.sup.3] for nine children in nonsmoking households and 37.0 [micro]g/[m.sup.3] for four children in smoking households in Wageningen, The Netherlands (Janssen et al. 1999). In Seattle, both P[M.sub.2.5] and P[M.sub.10] levels were significantly elevated during the heating season at all locations, including indoors, outdoors, and around subjects (P[M.sub.2.5] only) (Figure 2). The seasonal variation was more prominent in outdoor PM levels than in indoor or personal PM measurements. Previous studies also found seasonal variation in outdoor P[M.sub.2.5] and P[M.sub.10] levels: Northeastern U.S. cities have higher P[M.sub.2.5] and P[M.sub.10] levels in the summer because of the enhanced photochemical photochemical in laser treatment, the laser light is absorbed and converted into chemical energy. production of sulfate sulfate, chemical compound containing the sulfate (SO4) radical. Sulfates are salts or esters of sulfuric acid, H2SO4, formed by replacing one or both of the hydrogens with a metal (e.g., sodium) or a radical (e.g., ammonium or ethyl). and other secondary pollutants (Rojas-Bracho et al. 2000; Sarnat et al. 2000; Wilson and Suh 1997), and western U.S. cities have higher P[M.sub.2.5] and P[M.sub.10] levels in the winter because of wood burning and lack of photochemical reaction photochemical reaction Chemical reaction initiated by absorption of energy in the form of visible (light), ultraviolet, or infrared radiation. Primary photochemical processes occur as an immediate result, and secondary processes may follow. enhancement in the summer (Larson et al. 1989; Rodes et al. 2001). However, Rojas-Bracho et al. (2000) and Rodes et al. (2001) did not find significant seasonal changes in either personal or indoor P[M.sub.2.5] and P[M.sub.10] levels. We found that although [F.sub.inf] varied by season in private home, it did not vary significantly in group homes or private apartments (Allen R, Larson T, Wallace L, Liu L-JS. Unpublished data). This fact, coupled with the higher outdoor PM in winter, results in higher indoor and personal PM levels in winter. The mean P[M.sub.2.5]:P[M.sub.10] ratios indoors, outdoors, and at the central site were significantly higher during the heating season (October through February). The mean indoor P[M.sub.2.5]:P[M.sub.10] ratio during the heating season (0.60) was similar to that reported by Rodes et al. (2001) in Fresno indoors between January and February 1999 (0.61), whereas the P[M.sub.2.5]:P[M.sub.10] ratio in the nonheating season (0.55) was similar to that in Fresno (0.51) between April and May 1999. The home outdoor P[M.sub.2.5]:P[M.sub.10] ratio during the heating season (0.70) again was similar to that reported in Fresno (0.73, January through February 1999), whereas the home outdoor nonheating P[M.sub.2.5]:P[M.sub.10] ratio (0.57) was much higher than that in Fresno (0.36). The much lower ratio in Fresno is partially due to the more distinct nonheating season and partially to the introduction of coarse dusts from the adjacent San Joaquin Valley Noun 1. San Joaquin Valley - a vast valley in central California known for its rich farmland Calif., California, Golden State, CA - a state in the western United States on the Pacific; the 3rd largest state; known for earthquakes during the drier spring. The higher outdoor P[M.sub.2.5] proportion during the heating seasons in Fresno and Seattle is similar to that in Baltimore during the summer (0.73). A number of studies have examined the relationship between personal exposures and central-site measurements. Results from the Particle Total Exposure Assessment Methodology (PTEAM PTEAM Particle Total Exposure Assessment Methodology ) study (Clayton et al. 1993; Ozkaynak et al. 1996) indicated that correlations of personal exposures with fixed-site outdoor concentrations were low for P[M.sub.10] (ranging between 0.37 in the daytime Daytime may refer to:
and 0.54 at night). The relationship could be improved considerably when longitudinal regressions were performed for each subject (Janssen et al. 1997, 1998, 2000). Outdoor sulfur sulfur or sulphur (sŭl`fər), nonmetallic chemical element; symbol S; at. no. 16; at. wt. 32.06; m.p. 112.8°C; (rhombic), 119.0°C; (monoclinic), about 120°C; (amorphous); b.p. 444.674°C;; sp. gr. at 20°C;, 2. or sulfate, which is predominantly pre·dom·i·nant adj. 1. Having greatest ascendancy, importance, influence, authority, or force. See Synonyms at dominant. 2. in fine particles Fine particles are an air pollutant mainly produced by cars running on diesel. Other sources are the combustion of fossil fuels in power plants and various industrial processes. and of outdoor origin, was highly correlated with personal sulfur or sulfate exposures (Brauer et al. 1999; Ebelt et al. 2000; Ozkaynak et al. 1996; Stieb et al. 1998; Suh et al. 1992; Wallace 1996). For susceptible subjects in Seattle, the cross-sectional Pearson's correlation between personal and central P[M.sub.2.5] was 0.29 over all individual days (p < 0.0001; Spearman's r = 0.37; n = 974). The median longitudinal r between personal P[M.sub.2.5] exposure and central-site measurements was 0.34 (median shrunk r = 0.43) and does not vary much across groups. Our longitudinal correlations are in agreement with the large correlation range found in other panel studies (see, e.g., summary table 5 in Ebelt et al. 2000). More recent elderly panel studies showed the median correlation ranging between 0 in Nashville, Tennessee “Nashville” redirects here. For other uses, see Nashville (disambiguation). Nashville is the capital and the second most populous city of the U.S. state of Tennessee, after Memphis. (Bahadori et al. In press), and 0.80 in Fresno (spring; Rodes et al. 2001). Because the sample size and sampling duration vary by study, it should be interesting to compare the longitudinal shrunk estimates across all studies. The high correlations among outdoor sites for P[M.sub.2.5] and P[M.sub.10] in Seattle are consistent with our earlier findings in Seattle. Goswami et al. (2002) found that although the P[M.sub.2.5] concentration varied by elevation and the distance from major thoroughfares to the home sites, outdoor P[M.sub.2.5] measurements were highly correlated, with a median Pearson's r of 0.89 for 135 pairs of concurrent outdoor home sites. Significant differences in the fraction of time spent inside, outside homes, and in transit were observed among the study groups in this study (Tables 5 and 6). The COPD and CHD study groups spent more time at home (86-88%) than did the healthy elderly group (83%), whose time at home was similar to the 81% for elderly persons (> 64 years of age) in the general population reported in the National Human Activity Pattern Survey (NHAPS) (Klepeis et al. 1996). The asthmatic children in our study spent an average of 66% of the time at home, slightly lower than the 70% reported for children between 5 and 11 years of age in NHAPS (Tsang and Klepeis 1996). The longitudinal correlations are a function of the particle [F.sub.inf]. The personal PM exposure consists of the ambient originated PM, indoor originated PM, and the personal cloud (Wilson et al. 2000). Therefore, the longitudinal r for the personal exposure and the central-site measurements (i.e., ambient originated PM) is a function of the sum of the variances of the indoor and personal (or nonambient) originated PM ([[sigma].sup.2.sub.[epsilon]]), the variance of the ambient generated PM ([[sigma].sup.2.sub.x]), and the attenuation Loss of signal power in a transmission. Attenuation The reduction in level of a transmitted quantity as a function of a parameter, usually distance. It is applied mainly to acoustic or electromagnetic waves and is expressed as the ratio of power densities. from ambient PM to personal exposure ([alpha]), which is the sum of the fraction of time spent outdoors (y) and the fraction of time spent indoors (1 - y) times [F.sub.inf] [i.e., [alpha] = y + (1 - y) x [F.sub.inf]]. Note that [alpha] can be approximated by [F.sub.inf] because most people spend very little time outdoors and therefore y is negligible. Based on the definition of correlation, the longitudinal r can be written as [4] Longitudinal r = 1/[square root of 1 + R/[[alpha].sup.2]] where R = [[sigma].sup.2.sub.[epsilon]]/[[sigma].sup.2.sub.x]/. Simulated longitudinal correlation plots for longitudinal r and [F.sub.inf] based on different R values are shown as curves in Figure 5. Our measurements show that most longitudinal correlations fall between R = 0.05 and 1 (black circles), indicating that for most individuals, the variance of the nonambient-originated PM, [[sigma].sup.2.sub.[epsilon]], is generally smaller than the variance in ambient originated PM, [[sigma].sup.2.sub.x]] A much smaller group of data points falls beyond the line R = 3, (blue circles), which has smaller longitudinal r values (< 0.4) even when [alpha] = 1. For this group of individuals, the variance in nonambient-originated PM is greater than the variance of ambient-originated PM such that the longitudinal r is small (and most likely insignificant) regardless of [alpha]. These results show exactly why ambient PM concentrations were significantly associated with corresponding personal exposures for only about one-half to two-thirds of the monitored populations in past panel studies (Ebelt et al. 2000; Sarnat et al. 2000). [FIGURE 5 OMITTED] The three-microenvironmental model (Table 8) predicts personal exposures relatively well for the elderly subjects. Levels of the personal cloud in our elderly groups are lower than those reported in other elderly groups: 3.7 [micro]g/[m.sup.3] (12-hr average) in 18 COPD patients in Boston (Rojas-Bracho et al. 2000; Wallace 2000), 3.1 [micro]g/[m.sup.3] for COPD subjects in Baltimore (Rodes et al. 2001), and 3.4 [micro]g/[m.sup.3] (24-hr average) for elderly subjects in Fresno (Rodes et al. 2001). The elderly subjects' personal cloud in this study was much lower than the 27 [micro]g/[m.sup.3] reported for 18 healthy subjects in Azusa, California Azusa is a city in Los Angeles County, California, United States. The population was 44,712 at the 2000 census. Though often assumed to be a compaction of the phrase "everything from A to Z in the USA (Wallace 2000), or 6 [micro]g/[m.sup.3] for 10 COPD patients in Nashville (Bahadori et al. In press). The personal cloud for the asthmatic children in our study, 3.9 [micro]g/[m.sup.3], is also smaller than the 11 [micro]g/[m.sup.3] reported for 13 children in Amsterdam (Janssen et al. 1997). Our regression results showed that the personal cloud in the elderly groups can be attributed to running errands outdoors, cooking, and activities conducted in the yard, whereas the personal cloud among the asthmatic children can be attributed to time spent away from home (e.g., inside the school and riding the bus or shuttle). It is possible that the P[M.sub.2.5] concentration differs between the children's homes children's home n → centro de acogida para niños children's home n → foyer m d'accueil (pour enfants) children's home n and other indoor environments (Rea et al. 2001), where children spent about 21% of their time during the day, usually at school, in transit, and in extracurricular activities. Therefore, using home indoor measurements to represent P[M.sub.2.5] concentrations in these "away-from-home" environments resulted in an artificially larger personal cloud for children. The microenvironmental model (Equation 3) also does not include the personal cloud, so we are left with an ambiguity Ambiguity Delphic oracle ultimate authority in ancient Greece; often speaks in ambiguous terms. [Gk. Hist.: Leach, 305] Iseult’s vow pledge to husband has double meaning. [Arth. about what exactly accounts for the difference in observed versus expected exposure values that are on the order of 1-2.5 [micro]g/[m.sup.3] for the elderly groups. Only 39% of the outdoor PM contributed to personal P[M.sub.2.5] exposure, as estimated by the fixed-effect model (Equation 2) (Table 7); this indicates that personal P[M.sub.2.5] exposure is mostly attributed to nonambient sources, resulting in a low prediction power when using the outdoor or central-site measurements to predict personal exposures. However, a three-microenvironmental model that includes indoor home, outdoor home, and other outdoor environments resulted in relatively good prediction power ([R.sup.2] = 0.5-0.55) for the elderly groups. Therefore, given the time--activity pattern and microenvironmental concentrations, the elderly susceptible subjects' P[M.sub.2.5] exposures are relatively predictable. Conclusions The average personal P[M.sub.2.5] exposures that we found among sensitive subpopulations in Seattle were similar to the average outdoor P[M.sub.2.5] concentrations but significantly higher than average indoor concentrations. The elderly subjects' personal P[M.sub.2.5] exposures were lower than those reported for other elderly subjects in other cities. The personal P[M.sub.2.5] exposure in the asthmatic children in this study, who lived in nonsmoking households, was also lower than those found elsewhere. P[M.sub.2.5] and P[M.sub.10] concentrations, as well as the ratio of P[M.sub.2.5] to P[M.sub.10] concentration, vary seasonally; higher concentrations were found indoors and outdoors during the heating season. A similar seasonal variation was also found for personal P[M.sub.2.5] exposures. Personal P[M.sub.2.5] exposures varied by study group, with elderly healthy and CHD subjects having similar exposures, elderly COPD subjects experiencing slightly higher exposures, and asthmatic children having the highest exposures. The P[M.sub.2.5] exposure varied within the study groups, depending on the type of residences, most likely due to the differences in particle infiltration rates among residences. In addition, we found that the high-risk subjects engaged in an equal amount of dust-generating activities as did the healthy elderly subjects. The elderly COPD and CHD subjects had higher indoor P[M.sub.2.5] concentrations than did the elderly healthy subjects. The child subjects experienced the highest indoor P[M.sub.2.5] and P[M.sub.10] concentrations. Although a wide range of longitudinal correlations between central-site and personal P[M.sub.2.5] measurements was found, our results show that the longitudinal r is closely related to the particle infiltration efficiency of each residence. The P[M.sub.2.5] exposures among the COPD and CHD subjects can be predicted with a relatively good prediction power using a microenvironmental model with three microenvironments. The prediction power is the lowest for the asthmatic children in our study, whose in-school exposure was not accounted for in this microenvironmental model.
Table 1. Number of subjects by study
group and session in the Seattle panel.
Study group
Year Starting date Session Asthmatics CHD COPD Healthy Total
1999 October 26 1 -- 0 5 3 8
November 8 2 -- 0 5 4 9
November 29 3 -- 0 5 3 8
2000 January 10 4 -- 0 3 6 9
February 7 5 -- 1 2 3 6
February 21 6 -- 0 3 3 6
March 6 7 -- 1 3 3 7
March 27 8 -- 0 4 4 8
April 10 9 -- 0 3 2 5
May 1 10 -- 0 5 3 8
May 15 11 -- 0 4 0 4
July 10 12 -- 1 4 2 7
July 31 13 -- 1 1 2 4
September 25 1 -- 2 4 -- 6
October 16 2 -- 3 5 -- 8
November 6 3 -- 6 -- -- 6
November 27 4 2 4 -- -- 6
December 25 5 4 1 -- -- 5
2001 January 8 6 5 1 -- -- 6
January 22 7 3 3 -- -- 6
February 5 8 2 3 -- -- 5
February 26 9 4 4 -- -- 8
March 29 10 5 3 -- -- 8
April 16 11 3 2 -- -- 5
April 30 12 4 1 -- -- 5
May 14 13 1 3 -- -- 4
Total 33 40 56 38 167
About 50% of the subjects were monitored twice.
Table 2. Summary of PM concentrations ([micro]g/[m.sup.3])
between October 1999 and May 2001 by study group.
No.
Location Pollutant Group (a) Mean [+ or -] SD
Personal P[M.sub.2.5] COPD 307 10.5 [+ or -] 7.2
Healthy 183 9.3 [+ or -] 8.4
Asthmatic 263 13.3 [+ or -] 8.2
CHD 325 10.8 [+ or -] 8.4
Indoor P[M.sub.2.5] COPD 443 8.5 [+ or -] 5.1
Healthy 193 7.4 [+ or -] 4.8
Asthmatic 276 9.2 [+ or -] 6.0
CHD 329 9.5 [+ or -] 6.8
P[M.sub.10] COPD 437 14.1 [+ or -] 6.6
Healthy 206 12.6 [+ or -] 7.8
Asthmatic 274 19.4 [+ or -] 11.1
CHD 324 16.2 [+ or -] 11.3
Outdoor P[M.sub.2.5] COPD 437 9.2 [+ or -] 5.1
Healthy 194 9.0 [+ or -] 4.6
Asthmatic 272 11.3 [+ or -] 6.4
CHD 323 12.6 [+ or -] 7.9
P[M.sub.10] COPD 435 14.3 [+ or -] 6.8
Healthy 200 14.5 [+ or -] 7.0
Asthmatic 269 16.4 [+ or -] 7.4
CHD 324 18.0 [+ or -] 9.0
Central P[M.sub.2.5] 222 10.1 [+ or -] 5.7
site P[M.sub.10] 221 17.3 [+ or -] 9.1
Location Pollutant Group GM GSD Min Max
Personal P[M.sub.2.5] COPD 8.6 1.9 0.8 45.6
Healthy 7.7 1.8 0.8 96.2
Asthmatic 11.1 1.9 1.0 49.4
CHD 8.8 1.9 1.4 66.6
Indoor P[M.sub.2.5] COPD 7.3 1.7 1.0 49.9
Healthy 6.1 1.9 0.4 38.0
Asthmatic 7.9 1.7 2.2 36.3
CHD 8.0 1.8 1.6 65.3
P[M.sub.10] COPD 12.7 1.6 2.5 40.1
Healthy 10.6 1.9 0.6 62.2
Asthmatic 16.8 1.7 2.2 107.7
CHD 13.6 1.8 0.6 110.6
Outdoor P[M.sub.2.5] COPD 8.0 1.7 -0.2 28.9
Healthy 7.9 1.7 0.7 24.5
Asthmatic 9.8 1.7 2.8 40.4
CHD 10.6 1.8 1.3 41.5
P[M.sub.10] COPD 12.8 1.6 2.9 41.4
Healthy 13.0 1.6 2.9 54.9
Asthmatic 14.7 1.6 1.2 47.3
CHD 16.1 1.6 3.3 54.3
Central P[M.sub.2.5] 8.6 1.8 1.0 29.5
site P[M.sub.10] 14.9 1.8 0.4 49.9
Abbreviations: GM, geometric mean; GSD, geometric
SD; Max, maximum; Min, minimum.
(a) Number of daily samples.
Table 3. Ratio of P[M.sub.2.5] to P[M.sup.10],
stratified by year or heating season.
Location No. Max
Group (a) (b) Mean [+ or -] SD Min (c)
Year 1 Indoor 561 0.59 [+ or -] 0.13 0.22 0.98
(October 1999- Outdoor 553 0.63 [+ or -] 0.12 0.08 1.05
August 2000) Central 103 0.59 [+ or -] 0.12 0.27 0.84
Year 2 Indoor 644 0.56 [+ or -] 0.19 0.09 1.39
(September Outdoor 628 0.67 [+ or -] 0.16 -0.01 1.23
2000-May 2001) Central 113 0.60 [+ or -] 0.16 0.07 0.98
Heating season Indoor 708 0.60 [+ or -] 0.17 0.09 1.17
(October-February) Outdoor 690 0.70 [+ or -] 0.13 0.08 1.10
Central 119 0.66 [+ or -] 0.12 0.20 0.98
Nonheating season Indoor 497 0.55 [+ or -] 0.15 0.18 1.39
(March-September) Outdoor 491 0.57 [+ or -] 0.13 -0.01 1.23
Central 97 0.50 [+ or -] 0.11 0.07 0.73
Combined Indoor 1,205 0.58 [+ or -] 0.16 0.09 1.39
Outdoor 1,181 0.65 [+ or -] 0.14 -0.01 1.23
Central 216 0.59 [+ or -] 0.14 0.07 0.98
Abbreviations: Max, maximum; Min, minimum.
(a) Indoor, outdoor, and central-site ratios significantly different
during heating/nonheating seasons (p < 0.001); indoor (p = 0.002) and
outdoor (p < 0.001) differ by year, but central site does not (p =
0.55).
(b) Number of daily samples.
(c) Some maximum ratios are > 1 due to the
measurement error at low PM concentrations.
Table 4. Spearman correlations (number of daily samples)
between personal, indoor, outdoor, and centralsite monitors
for P[M.sub.2.5] and P[M.sub.10].
Personal Indoor Outdoor
P[M.sub.2.5] P[M.sub.2.5] P[M.sub.2.5]
Personal P[M.sub.2.5] 1
(1,078)
Indoor P[M.sub.2.5] 0.65 1
(996) (1,500)
Outdoor P[M.sub.2.5] 0.41 0.58 1
(1,009) (1,425) (1,497)
Central P[M.sub.2.5] 0.37 0.51 0.84
(974) (1,293) (1,297)
Indoor P[M.sub.10] 0.56 0.83 0.42
(1,007) (1,454) (1,439)
Outdoor P[M.sub.10] 0.41 0.57 0.91
(998) (1,422) (1,440)
Central P[M.sub.10] 0.37 0.50 0.76
(965) (1,288) (1,289)
Central Indoor
P[M.sub.2.5] P[M.sub.10]
Personal P[M.sub.2.5]
Indoor P[M.sub.2.5]
Outdoor P[M.sub.2.5]
Central P[M.sub.2.5] 1
(1,408)
Indoor P[M.sub.10] 0.38 1
(1,303) (1,514)
Outdoor P[M.sub.10] 0.81 0.41
(1,289) (1,441)
Central P[M.sub.10] 0.90 0.41
(1,368) (1,297)
Outdoor Central
P[M.sub.10] P[M.sub.10]
Personal P[M.sub.2.5]
Indoor P[M.sub.2.5]
Outdoor P[M.sub.2.5]
Central P[M.sub.2.5]
Indoor P[M.sub.10]
Outdoor P[M.sub.10] 1
(1,491)
Central P[M.sub.10] 0.82 1
(1,283) (1,398)
All p-values are < 0.0001.
Table 5. Percentage of time spent in microenvironments by study group.
Percentage of time spent
in each microenvironment
Group Microenvironment Mean [+ or -] SD Min Max
Asthmatics Home 66.4 [+ or -] 5.7 55.5 80.0
(n = 33) (a) Yard 1.7 [+ or -] 2.6 0.0 8.2
In transit 4.4 [+ or -] 1.7 1.3 8.2
Work 1.1 [+ or -] 3.5 0.0 16.5
Outdoors 4.7 [+ or -] 3.5 0.1 17.5
Indoors away from home 21.0 [+ or -] 6.4 4.5 33.2
Cooking, self 0.1 [+ or -] 0.1 0.0 0.5
Cooking, others 0.7 [+ or -] 0.5 0.0 1.9
CHD Home 85.5 [+ or -] 7.8 65.0 96.5
(n = 38) Yard 1.0 [+ or -] 1.4 0.0 6.0
In transit 3.6 [+ or -] 2.3 0.1 9.2
Work 0.3 [+ or -] 1.7 0.0 10.6
Outdoors 0.9 [+ or -] 1.2 0.0 4.8
Indoors away from home 6.9 [+ or -] 5.1 0.1 20.9
Cooking, self 1.7 [+ or -] 1.6 0.0 5.8
Cooking, others 0.2 [+ or -] 0.3 0.0 1.5
COPD Home 87.6 [+ or -] 6.9 71.4 100.0
(n = 56) Yard 0.8 [+ or -] 1.0 0.0 4.3
In transit 3.2 [+ or -] 1.9 0.0 7.3
Work 0.1 [+ or -] 0.6 0.0 3.1
Outdoors 1.0 [+ or -] 1.9 0.0 11.6
Indoors away from home 6.1 [+ or -] 4.6 0.0 21.3
Cooking, self 1.0 [+ or -] 1.3 0.0 5.6
Cooking, others 0.2 [+ or -] 0.6 0.0 2.7
Healthy Home 82.7 [+ or -] 8.3 66.8 99.2
(n = 39) Yard 1.2 [+ or -] 1.6 0.0 6.7
In transit 4.0 [+ or -] 2.5 0.5 9.3
Work 1.0 [+ or -] 2.8 0.0 12.4
Outdoors 1.7 [+ or -] 1.8 0.0 7.9
Indoors away from home 8.0 [+ or -] 5.3 0.1 19.4
Cooking, self 1.0 [+ or -] 1.0 0.0 4.4
Cooking, others 0.3 [+ or -] 0.6 0.0 2.7
Abbreviations: Max, maximum; Min, minimum.
(a) Number of subjects in sessions.
Table 6. Associations between proportion of time spent indoors
or outdoors (in fraction) and subject characteristics and session.
Time spent
(fraction) Parameter Estimate SE
Indoors
Elderly adults Intercept 0.270 0.069
([R.sup.2] = Female -0.007 0.011
0.51, p< 0.001) Age (per year increase) 0.007 0.001
Health status
Healthy
CHD 0.040 0.025
COPD 0.049 0.012
Session
Asthmatic children Intercept 0.812 0.052
([R.sup.2] = 0.47, Female -0.011 0.024
p = 0.14) Age (per year increase) -0.012 0.005
Session
Outdoors
Elderly adults Intercept 0.0674 0.0193
([R.sup.2] = Female -0.0015 0.0030
0.23, p = 0.43) Age (per year increase) -0.0006 0.0002
Health status
Healthy
CHD -0.0001 0.0070
COPD -0.0072 0.0034
Session
Asthmatic Intercept 0.0100 0.0290
children Female -0.0130 0.0134
([R.sup.2] = Age (per year increase) 0.0030 0.0029
0.57, p = 0.03) Session
Confidence limit
Time spent
(fraction) Parameter Lower Upper p-Value
Indoors
Elderly adults Intercept 0.135 0.405 0.00
([R.sup.2] = Female -0.028 0.014 0.52
0.51, p< 0.001) Age (per year increase) 0.005 0.009 0.00
Health status
Healthy Reference
CHD -0.010 0.089 0.11
COPD 0.025 0.073 0.00
Session 0.45
Asthmatic children Intercept 0.709 0.914 0.00
([R.sup.2] = 0.47, Female -0.058 0.037 0.66
p = 0.14) Age (per year increase) -0.022 -0.001 0.03
Session 0.37
Outdoors
Elderly adults Intercept 0.0295 0.1052 0.00
([R.sup.2] = Female -0.0074 0.0043 0.61
0.23, p = 0.43) Age (per year increase) -0.0010 -0.0001 0.01
Health status
Healthy Reference
CHD -0.0139 0.0137 0.99
COPD -0.0139 -0.0006 0.03
Session 0.77
Asthmatic Intercept -0.0469 0.0669 0.73
children Female -0.0393 0.0133 0.33
([R.sup.2] = Age (per year increase) -0.0027 0.0087 0.30
0.57, p = 0.03) Session 0.02
Table 7. Association between personal and indoor P[M.sup.2.5]
measurements and study group, controlling for session, home
type, and outdoor P[M.sup.2.5] concentration.
Confidence limit
Parameter Estimate SE Lower Upper
All groups
Intercept 5.72 1.73 2.34 9.11
Health status
Asthma 5.57 1.57 2.49 8.64
CHD -1.02 1.55 -4.05 2.01
COPD 3.46 1.11 1.29 5.63
Outdoor P[M.sup.2.5] 0.39 0.04 0.31 0.47
Home
Session
Health x home
Elderly adults
Intercept 22.87 3.91 15.21 30.53
Health status
CHD 0.43 1.48 -2.48 3.33
COPD 3.84 1.04 1.80 5.87
Age (per year increase) -0.23 0.05 -0.32 -0.14
Outdoor P[M.sup.2.5] 0.39 0.04 0.31 0.48
Home
Session -0.71 1.77 -4.17 2.75
Health x home
Model
Parameter p-Value [R.sup.2] p-Value
All groups
Intercept <0.001 0.23 < 0.0001
Health status
Asthma <0.001
CHD 0.51
COPD <0.001
Outdoor P[M.sup.2.5] <0.0001
Home 0.14
Session <0.0001
Health x home <0.0001
Elderly adults
Intercept <0.0001 0.27 < 0.0001
Health status
CHD 0.77
COPD <0.001
Age (per year increase) <0.0001
Outdoor P[M.sup.2.5] <0.0001
Home 0.75
Session <0.0001
Health x home <0.0001
Table 8. Regression analysis results for measured compared with
microenvironmental model-predicted P[M.sup.2.5] personal exposures
([[??].sub.p]).
Estimates [[??]
.sub.p]
Group Variable [beta] SE p-Value [R.sup.2] mean
Asthmatic Intercept 9.57 1.01 < 0.0001 0.09 13.6
children [[??].sub.p] 0.41 0.09 < 0.0001
Elderly
adults
CHD Intercept 1.07 0.57 0.06 0.62 11
[[??].sub.p] 1.07 0.05 < 0.0001
COPD Intercept 2.24 0.57 < 0.0001 0.55 10.6
[[??].sub.p] 1.01 0.06 < 0.0001
Healthy Intercept 2.38 0.63 < 0.001 0.45 8.4
[[??].sub.p] 0.85 0.08 < 0.0001
Cp = intercept + ([beta] x [[??].sub.p]).
Table 9. Activities (in minutes) affecting the
P[M.sup.2.5] personal cloud ([micro]g/[m.sup.3]).
Wald 95%
confidence limit
Parameter Estimate SE Lower Upper p-Value
Elderly adults
(model [R.sup.2] =
0.06, p = 0.16)
Intercept 0.70 0.49 -0.26 1.66 0.152
Health status
CHD 0.27 0.52 -0.74 1.28 0.596
COPD 1.23 0.52 0.22 2.24 0.017
Outdoor errands 0.02 0.01 0.01 0.03 0.002
Cooking, indoors 0.01 0.01 0.00 0.02 0.024
In yard, outdoors 0.04 0.02 0.00 0.07 0.043
Asthmatic children
(model [R.sup.2] =
0.19, p = 0.06)
Intercept 1.27 1.81 -2.27 4.81 0.482
At school indoors 0.01 0.01 0.00 0.03 0.006
In bus or shuttle 0.05 0.02 0.01 0.09 0.008
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The relationships between personal PM exposures for elderly populations and indoor and outdoor concentrations for three retirement center scenarios. J Expo Anal Environ Epidemiol 11:103-115. Rojas-Bracho L, Suh HH, Koutrakis P. 2000. Relationship among personal, indoor, and outdoor fine and coarse particle concentrations for individuals with COPD. J Expo Anal Environ Epidemiol 10:294-306. Samet JM, Dominici F, Curriero FC, Coursac I, Zeger SL. 2000. Fine particulate air pollution and mortality in 20 U.S. cities, 1987-1994. N Engl J Med 343:1742-1749. Sarnat JA, Koutrakis P, Suh HH. 2000. Assessing the relationship between personal particulate and gaseous exposures of senior citizens living in Baltimore, MD. J Air Waste Manag Assoc 50:1184-1198. Schwartz J. 2000. Daily deaths are associated with combustion combustion, rapid chemical reaction of two or more substances with a characteristic liberation of heat and light; it is commonly called burning. 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Estimating separately personal exposure to ambient and nonambient particulate matter for epidemiology and risk assessment: why and how. J Air Waste Manag Assoc 50:1167-1183. Woodruff T, Grillo J, Schoendorf K. 1997. The relationship between selected causes of postneonatal infant mortality (hardware) infant mortality - It is common lore among hackers (and in the electronics industry at large) that the chances of sudden hardware failure drop off exponentially with a machine's time since first use (that is, until the relatively distant time at which enough mechanical and particulate air pollution in the United States United States, officially United States of America, republic (2005 est. pop. 295,734,000), 3,539,227 sq mi (9,166,598 sq km), North America. The United States is the world's third largest country in population and the fourth largest country in area. . Environ Health Perspect 105:608-612. Zhang J, Hu W, Wei F, Wu G, Korn L, Chapman R. 2002. Children's respiratory morbidity prevalence in relation to air pollution in four Chinese cities. Environ Health Perspect 110:961-967. L.-J. Sally Liu, (1) Michael Box, (1) David Kalman, (1) Joel Kaufman, (1) Jane Koenig, (1) Tim Larson, (2) Thomas Lumley, (3) Lianne Sheppard, (1,3) and Lance Wallace (4) (1) Department of Environmental and Occupational Health Sciences, (2) Department of Environmental and Civil Engineering, and (3) Department of Biostatistics biostatistics /bio·sta·tis·tics/ (-stah-tis´tiks) biometry. bi·o·sta·tis·tics n. The science of statistics applied to the analysis of biological or medical data. , University of Washington, Seattle, Washington  This page is protected from moves until disputes have been resolved on the .The reason for its protection is listed on the protection policy page. , USA; (4) U.S. Environmental Protection Agency, Reston, Virginia Reston is an internationally known planned community whose goal was to revolutionize post-World War II concepts of land use and residential/corporate development in American suburbia. , USA Address correspondence to L.-J. Sally Liu, Dept. of Environmental and Occupational Health Sciences, University of Washington, Box 354695, Seattle, WA 98195 USA. Telephone: (206) 543-2005. Fax: (206) 543-8123. E-mail: sliu@u.washington.edu We thank L. Tuttle, T. Gould, J. Sullivan, C. Trenga, J.C. Slaughter slaughter 1. the killing of animals for the preparation of meat for human consumption. Many methods are used. See also emergency slaughter, captive bolt pistol, carbon dioxide anesthesia, jewish slaughter, muslim slaughter, pithing, puntilla, shechita, sikh slaughter. 2. , and the field/laboratory technicians who worked on this project. We owe a great deal to our study subjects. This work was funded by the U.S. EPA (CR82717701), the Northwest Center for Particulate Air Pollution and Health (U.S. EPA grant CR827355), and 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. grant P30 ES07033. This report has been subjected to U.S. EPA review and approved for publication. Mention of trade names or commercial products does not constitute an endorsement or recommendation for use. The authors declare they have no conflict of interest. Received 20 September 2002; accepted 3 February 2003. |
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