Association of ambient air pollution with respiratory hospitalization in a government-designated "area of concern": the case of Windsor, Ontario.This study is part of a larger research program to examine the relationship between ambient Surrounding. For example, ambient temperature and humidity are atmospheric conditions that exist at the moment. See ambient lighting. air quality and health in Windsor, Ontario Windsor is the southernmost city in Canada and lies at the western end of the heavily populated Quebec City-Windsor Corridor. Windsor is located directly south of Detroit and is separated from that city by the Detroit River. The city has views of the Detroit skyline. , Canada. We assessed the association between air pollution and daily respiratory hospitalization hospitalization /hos·pi·tal·iza·tion/ (hos?pi-t'l-i-za´shun) 1. the placing of a patient in a hospital for treatment. 2. the term of confinement in a hospital. for different age and sex groups from 1995 to 2000. The pollutants pollutants see environmental pollution. included were 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. , 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. , 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; , ozone, 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. [less than or equal to] 10 [micro]m in diameter (P[M.sub.10]), coefficient of haze The coefficient of haze is a measurement of visibility interference in the atmosphere. (COH CoH City of Heroes (gaming) CoH Company of Heroes (game) COH City of Hope COH Court of Honor (Boy Scouts of America) COH Controlled Ovarian Hyperstimulation ), and total reduced sulfur (TRS See traffic engineering methods. TRS - term rewriting system ). We calculated relative risk (RR) estimates using both time-series and case-crossover methods after controlling for appropriate confounders (temperature, humidity humidity, moisture content of the atmosphere, a primary element of climate. Humidity measurements include absolute humidity, the mass of water vapor per unit volume of natural air; relative humidity (usually meant when the term humidity , and change in barometric ba·rom·e·ter n. 1. An instrument for measuring atmospheric pressure, used especially in weather forecasting. 2. Something that registers or responds to fluctuations; an indicator: pressure). The results of both analyses were consistent. We found associations between N[O.sub.2], S[O.sub.2], CO, COH, or P[M.sub.10] and daily hospital admission of respiratory diseases Noun 1. respiratory disease - a disease affecting the respiratory system respiratory disorder, respiratory illness adult respiratory distress syndrome, ARDS, wet lung, white lung - acute lung injury characterized by coughing and rales; inflammation of the especially among females. For females 0-14 years of age, there was 1-day delayed effect of N[O.sub.2] (RR = 1.19, case-crossover method), a current-day S[O.sub.2] (RR = 1.11, time series), and current-day and 1- and 2-day delayed effects for CO by case crossover Crossover The point on a stock chart when a security and an indicator intersect. Crossovers are used by technical analysts to aid in forecasting the future movements in the price of a stock. In most technical analysis models, a crossover is a signal to either buy or sell. (RR = 1.15, 1.19, 1.22, respectively). Time-series analysis Time-series analysis Assessment of relationships between two or among more variables over periods of time. showed that 1-day delayed effect of P[M.sub.10] on respiratory admissions of adult males (15-64 years of age), with an RR of 1.18. COH had significant effects on female respiratory hospitalization, especially for 2-day delayed effects on adult females, with RRs of 1.15 and 1.29 using time-series and case-crossover analysis, respectively. There were no significant associations between [O.sub.3] and TRS with respiratory admissions. These findings provide policy makers with current risks estimates of respiratory hospitalization as a result of poor ambient air quality in a government designated "area of concern." Key words: air pollution, area of concern, Ontario, respiratory disease, Windsor. 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 113:290-296 (2005). doi:10.1289/ehp.7300 available via http://dx.doi.org/[Online 14 December 2004] ********** Poor environmental quality has been an important public health issue for some time now. Research using large-scale data sets has shown a fairly consistent relationship between air pollutant pol·lut·ant n. Something that pollutes, especially a waste material that contaminates air, soil, or water. levels and respiratory diseases in a variety of communities in the industrialized in·dus·tri·al·ize v. in·dus·tri·al·ized, in·dus·tri·al·iz·ing, in·dus·tri·al·iz·es v.tr. 1. To develop industry in (a country or society, for example). 2. world (e.g., Atkinson et al. 1999; Dockery et al. 1993; Lin et al. 2002, 2004; Pope et al. 1995; Schwartz 1994). In Canada, several reports have been published linking air pollution to adverse population health in cities based on data that were collected in the 1980s and early 1990s (e.g., Burnett et al. 1994, 1999; Goldberg et al. 2001). Windsor, Ontario, with a population of 208,402, is one of the cities that has been identified as heavily polluted pol·lute tr.v. pol·lut·ed, pol·lut·ing, pol·lutes 1. To make unfit for or harmful to living things, especially by the addition of waste matter. See Synonyms at contaminate. 2. (Burnett et al. 1998). The city is one of the most industrialized cities in Canada This is a list of incorporated cities of Canada in alphabetical order categorized by province. More thorough lists of communities are available for each province. Significant cities , with major industries including three automobile assembly plants, an engine plant, a foundry, and a scrap metal recycling recycling, the process of recovering and reusing waste products—from household use, manufacturing, agriculture, and business—and thereby reducing their burden on the environment. plant. In addition, there is the outstanding problem of transboundary air and water pollution from the U.S. states A U.S. state is any one of the fifty subnational entities of the United States, although four states use the official title "commonwealth". The separate state governments and the federal government share sovereignty, in that an American is a citizen both of the federal entity and of Ohio, Illinois Ohio is a village in Bureau County, Illinois, United States. The population was 540 at the 2000 census. Geography Ohio is located at (41.556900, -89.460995)GR1. , and Michigan. The city is immediately downwind down·wind adv. In the direction in which the wind blows. down  wind of major steel mills with associated
coking operations in Detroit, Michigan “Detroit” redirects here. For other uses, see Detroit (disambiguation).Detroit (IPA: [dɪˈtʰɹɔɪt]) (French: Détroit, meaning strait , the wastewater treatment plant Wastewater treatment plant also called wastewater treatment works
sludge a suspension of solid or semisolid particles in a fluid. incineration incineration the act of burning to ashes. facilities, and a major power plant that until recently was coal fired. Consequently, Windsor and surrounding communities have been identified as an "area of concern" and in need of further health investigation (Health Canada Health Canada (French: Santé Canada) is the department of the government of Canada with responsibility for national public health. Health Canada's goal is to improve Canadian life by improving Canadian longevity, lifestyle and use of public healthcare. 2000). Furthermore, in line with Windsor's ranking as a city with a high level of pollution compared with other Canadian cities (Burnett et al. 1998), a recent community-health profile by Gilbertson and Brophy (200I) indicated mortality and morbidity rates morbidity rate n. The proportion of patients with a particular disease during a given year per given unit of population. morbidity rate Epidemiology The number of cases of a particular disease in a unit of population from various cancers, circulatory circulatory /cir·cu·la·to·ry/ (ser´ku-lah-tor?e) 1. pertaining to circulation, particularly that of the blood. 2. containing blood. cir·cu·la·to·ry n. 1. , and respiratory disorders Noun 1. respiratory disorder - a disease affecting the respiratory system respiratory disease, respiratory illness adult respiratory distress syndrome, ARDS, wet lung, white lung - acute lung injury characterized by coughing and rales; inflammation of the were higher in Windsor than in the rest of the province of Ontario. This work aroused a lot of public sentiments, and several calls were made for further investigation into the "alarming trends" of morbidity and mortality Morbidity and Mortality can refer to:
Disease that affects the heart and blood vessels. Mentioned in: Lipoproteins Test cardiovascular disease hospitalization (Fung et al. 2005). We reported, among other things, that short-term effects of sulfur dioxide were associated significantly with daily cardiac hospital admissions for people [greater than or equal to] 65 years of age. The main focus of this article is on respiratory diseases. We used the most recent hospitalization data available from 1995 through 2000 to quantify Quantify - A performance analysis tool from Pure Software. the association between ambient air pollution and respiratory hospitalization, with temperature, humidity, and change in barometric pressure as covariates. We are especially interested in investigating whether there is an age or sex difference in respiratory admissions. This research will provide policy makers as well as the public with estimates of current risks of respiratory hospitalization as a result of poor ambient air quality. Materials and Methods Data acquisition. The study population consisted of all people who were admitted into one of the four hospitals in Windsor with primary diagnoses of respiratory disease [International Classification of Diseases, 9th Revision (ICD-9) codes 460-519 (World Health Organization [WHO] 1975)] from 1 April 1995 through 31 December 2000 and were registered with the Ontario Health Insurance Plan The Ontario Health Insurance Plan (OHIP) is the government-run health plan for the Canadian province of Ontario. Every Ontario resident is entitled to free access to emergency and preventive medical care under OHIP. (OHIP OHIP Ontario Health Insurance Plan OHIP Office of Health Insurance Programs (New York State Department of Health) OHIP Occupational Health Internship Program (AOEC) OHIP Ownership Has Its Privileges ). Daily hospital admission records for OHIP patients were obtained from the Canadian Institute for Health Information The Canadian Institute for Health Information (CIHI) is an independent, not-for-profit organization in Canada, primarily funded by the provincial and federal governments of Canada. (CIHI CIHI Canadian Institute for Health Information CIHI Center for International Health Information ) Discharge Abstract Database (CIHI 2002). The data included date of respiratory admission, age, and sex. Our analysis focused on finding the association between air pollution and daily respiratory hospitalizations. It was not able to address events that happened after admission. The hourly air pollution data from the four fixed monitoring stations in Windsor were obtained from the Ontario Ministry of the Environment (MOE Moe continually exasperated at Larry and Curly for their mischievous pranks. [TV: “The Three Stooges” in Terrace, II, 366] See : Exasperation 2000). To capture the effects of exposure, the highest reading for each day was used for the analysis (see Chock et al. 2000). The pollutants were nitrogen dioxide, S[O.sub.2], carbon monoxide, ozone, inhalable particles [particulate matter [less than or equal to] 10 [micro]m in diameter (P[M.sup.10])], coefficient of haze (COH), and total reduced sulfur compounds (TRS). We included COH in our analysis following the recommendation by Goldberg et al. (2001). According to according to prep. 1. As stated or indicated by; on the authority of: according to historians. 2. In keeping with: according to instructions. 3. Goldberg et al. (2001), despite the infrequent in·fre·quent adj. 1. Not occurring regularly; occasional or rare: an infrequent guest. 2. use of the COH in time-series analyses, it is a reliable measure of the concentration of ambient carbon particles (generally from internal combustion combustion, rapid chemical reaction of two or more substances with a characteristic liberation of heat and light; it is commonly called burning. The burning of a fuel (e.g., wood, coal, oil, or natural gas) in air is a familiar example of combustion. ), with only limited contributions from other pollutants, such as sulfates, nitrates, or particle mass. Respirable respirable /res·pir·a·ble/ (re-spir´ah-b'l) 1. suitable for respiration. 2. small enough to be inhaled. res·pi·ra·ble adj. 1. Fit for breathing, as air. particles (PM [less than or equal to] 2.5 [micro]m in diameter) data were available only from 1998 through 2001 and were not included in our analysis. Daily weather data including maximum and minimum temperature, humidity, and change in maximum or minimum barometric pressure from the previous day were obtained from the Environment Canada Environment Canada (EC), legally incorporated as the Department of the Environment under the Department of the Environment Act ( R.S., 1985, c. E-10 ), is the department of the Government of Canada with responsibility for coordinating environmental policies and (2002). Statistical analysis. First, we linked together > 2,000 days of records from several databases comprising pollutants, temperature, humidity and pressure, and number of respiratory admissions. Data from CIHI were given to us in a ready-to-use format. Because we used the maximum of daily hourly pollutant values from four stations, there were not many missing values In statistics, missing values are a common occurrence. Several statistical methods have been developed to deal with this problem. Missing values mean that no data value is stored for the variable in the current observation. (< 1%). If missing values were sporadic sporadic /spo·rad·ic/ (spo-rad´ic) occurring singly; widely scattered; not epidemic or endemic. spo·rad·ic or spo·rad·i·cal adj. 1. Occurring at irregular intervals. 2. , we replaced the missing values by the mean of nearby points (3 days before and 3 days after). If missing values occurred for a series of days, we substituted the linear trend value for those points using other pollutants and covariates as predictors. In very few cases, if the highest hourly maximum was deemed extreme, it was replaced by the next highest value. To relate short-term effects of air pollution on the number of respiratory hospitalizations, we used two different statistical techniques: time-series and case crossover methods. Both procedures have been used extensively to analyze this type of data (Burnett et al. 1994; Goldberg et al. 2001; Lee and Schwartz 1999; Lin et al. 2002, 2004; Neas et al. 1999). Detailed formulas are available in the literature. Since 2002, significant developments in these methodologies have taken place. For time series, the usual smoothing method that has been used for producing residuals with no seasonality was locally weighted regression The introduction to this article provides insufficient context for those unfamiliar with the subject matter. Please help [ improve the introduction] to meet Wikipedia's layout standards. You can discuss the issue on the talk page. smoothers (LOESS loess (lĕs, lō`əs, Ger. lös), unstratified soil deposit of varying thickness, usually yellowish and composed of fine-grained angular mineral particles mixed with clay. ) within the generalized additive models In statistics, the generalized additive model (or GAM) is a statistical model developed by Trevor Hastie and Rob Tibshirani blending properties of multiple regression (a special case of general linear model) with additive models. (GAMs) (Hastie and Tibshirani 1990). It was later discovered (Dominici et al. 2002; Ramsay et al. 2003; Samet et al. 2003) that the default settings of the GAM function in the software package S-Plus (Insightful Corp. 2001) do not assure convergence of its iterative it·er·a·tive adj. 1. Characterized by or involving repetition, recurrence, reiteration, or repetitiousness. 2. Grammar Frequentative. Noun 1. estimation estimation In mathematics, use of a function or formula to derive a solution or make a prediction. Unlike approximation, it has precise connotations. In statistics, for example, it connotes the careful selection and testing of a function called an estimator. procedure and can provide biased estimates of regression coefficients Regression coefficient Term yielded by regression analysis that indicates the sensitivity of the dependent variable to a particular independent variable. See: Parameter. regression coefficient and standard errors, especially when the concurvity is high. Dominici et al. (2002) reanalyzed the National 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. , Mortality, and Air Pollution Study data with the default implementation and found that the estimates were biased upward (i.e., higher than they should be). Since then, either the default option was set to a smaller number, such as [10.sup.-8] (S-Plus has already done that in their new release), or another smoother called natural splines has been used in the general linear model function. For case-crossover analysis, Navidi modified his bidirectional The ability to move, transfer or transmit in both directions. design (Navidi 1998) and proposed the semisymmetric bidirectional design (Navidi and Weinhandl 2002). Fung et al. (2003) compared all these methods using simulations, and we used what was recommended in that report--natural splines (ns) in time series and bidirectional case crossover. For the time-series analysis in this article, daily concentrations of each pollutant and covariates were related to the natural logarithm Natural logarithm Logarithm to the base e (approximately 2.7183). of hospital admissions, y, by the model log E(y) = pollutant + ns(time, df) + DOW + ns(temperature, 4) + ns(humidity, 4) + ns(pressure, 4), where E(y) is the mean of y and DOW is the day-of-the-week effect, which takes on values 1-7. For each age and sex group, we first found the degrees of freedom (df) for ns(time) such that after fitting the smoothed time effect and DOW, we had a time series of residuals that is as close to white noise as possible, as determined by Bartlett's test Bartlett's test (Snedecor and Cochran, 1983) is used to test if k samples have equal variances. Equal variances across samples is called homoscedasticity or homogeneity of variances. (Priestly priest·ly adj. priest·li·er, priest·li·est 1. Of or relating to a priest or the priesthood. 2. Characteristic of or suitable for a priest. 1981). We then extended the model by incorporating the smoothed weather variables. Different combinations of smoothed weather variables (minimum or maximum temperature, humidity, and change in barometric pressure) were examined, and the combination that yielded the lowest Akaike Information Criterion Akaike's information criterion, developed by Hirotsugu Akaike under the name of "an information criterion" (AIC) in 1971 and proposed in Akaike (1974), is a measure of the goodness of fit of an estimated statistical model. It is grounded in the concept of entropy. (Akaike 1973) was chosen. Last, we added the air pollutant into the model. Regression models with current-day pollution value (lag 1), average of current day and yesterday (lag 2), and average of current and 2 previous days (lag 3) were examined. Relative risk (RR) was calculated as exp exp abbr. 1. exponent 2. exponential ([beta] x IQR IQR Interquartile Range (statistics) IQR Internet Quick Reference IQR Individual Qualification Record IQR Internal Quality Review ), where [beta] is the estimated regression coefficient for pollutant in the above log-linear model log-linear model a statistical model which models frequency counts in contingency tables by using an analysis of variance approach. and IQR is the interquartile range In descriptive statistics, the interquartile range (IQR), also called the midspread, middle fifty and middle of the #s, is a measure of statistical dispersion, being equal to the difference between the third and first quartiles. (75th 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 to 25th percentile) of the pollutant. This implies that the percentage change in the mean number of daily hospitalizations is (RR - 1) x 100% for an increase of IQR unit of pollutant. Ninety-five percent confidence intervals confidence interval, n a statistical device used to determine the range within which an acceptable datum would fall. Confidence intervals are usually expressed in percentages, typically 95% or 99%. (CIs) of the RRs were obtained under the assumption that the estimated regression coefficients were normally distributed. The case-crossover design of Maclure (1991) has recently been suggested as an alternative to time-series analysis. This design is essentially a case-control design in which cases serve as their own controls. Risk estimates are based on within subject comparisons of exposures at failure times with exposure at times both before and after failure, using matched case-control methods. This procedure is used to investigate whether a recent exposure has triggered the occurrence of a particular adverse health outcome and is particularly useful for estimating effects that are transient A malfunction that occurs at random intervals and lasts for a short duration such as a spike or surge in a power line or a memory cell that intermittently fails. See spike and power surge. transient - 1. or acute. Because each subject serves as its own control, the case-crossover approach controls for effects of stable subject specific covariates such as sex and race, and for potential time varying confounders such as seasonal effects or personal habits such as smoking. In this study, we used the bidirectional design (Navidi 1998), which can control for different patterns of time trends in exposures and outcomes and gives the least biased estimate compared with the pre- or post-unidirectional design (Fung et al. 2003). We selected an interval of 2 weeks between case and control periods to minimize autocorrelation Autocorrelation The correlation of a variable with itself over successive time intervals. Sometimes called serial correlation. between case and control exposures and to control for seasonal effects. Conditional logistic regression In statistics, logistic regression is a regression model for binomially distributed response/dependent variables. It is useful for modeling the probability of an event occurring as a function of other factors. analysis using the same covariates as time series were performed via the Cox proportional hazards model. Maximum likelihood estimates of the parameters were obtained by choosing the "exact" option in S-Plus. Details of this model can be found in Navidi (1998) or Fung et al. (2003). Results A total of 4,214 overall admissions due to respiratory diseases occurred in the study period. Table 1 gives the summary statistics of daily respiratory admissions for the three age groups (0-14, 15-64, [greater than or equal to] 65 years). Overall, there seem to be more male hospitalizations than female in the early years, but the opposite is true for later years. Summary statistics of weather variables and daily high concentrations of all the pollutants are also provided in Table 1. An analysis of the Windsor yearly air pollution data for the period 1990-2000 showed an overall decreasing trend in ambient air pollutants (N[O.sub.2], S[O.sub.2], CO, COH), likely due to regulatory measures implemented by the government in the preceding 10 years (MOE 2000). There was an increasing trend in [O.sub.3] and TRS, whereas P[M.sub.10] did not change much. Based on the air quality index, there were 165 days of poor air quality, 583 days of moderate air quality, and 1,352 days of good air quality during the entire study period. Table 2 gives the correlation coefficients Correlation Coefficient A measure that determines the degree to which two variable's movements are associated. The correlation coefficient is calculated as: for the air pollutants and weather variables. Most of the pollutants are positively 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, except S[O.sub.2] and [O.sub.3] (r = -0.02), and TRS and [O.sub.3] (r = -0.01). Maximum temperature and minimum humidity were highly correlated with [O.sub.3]. Tables 3 and 4 give the time-series and case-crossover RR estimates by age and sex groups. 95% CIs were also given for the current day (lag 1), lag 2, and lag 3 of the pollutants that were used in the analyses. The time-series analysis showed elevated effects of N[O.sub.2] on the respiratory admissions of females overall and the 0-14 and 15-64 age groups (Table 3). The results of the case-crossover analysis somewhat concurred with those of the time series. We found N[O.sub.2] lag 2 to be significantly associated with respiratory hospitalization of females 0-14 years age, with an RR of 1.19 (95% CI, 1.002-1.411) (Table 4). Although the effects of N[O.sub.2] on women in the 15-64 and [greater than or equal to] 65 age groups were all elevated, none of these were significant. There were no significant associations between N[O.sub.2] and male hospitalization in any of the age groups (Tables 3 and 4). Time-series results showed a significant current-day effect of S[O.sub.2] on the admission of females 0-14 years of age, with an RR of 1.11 (95% CI, 1.011-1.221). The case-crossover method also showed an RR of 1.12, and it is almost significant. Other than this, there were no significant association between S[O.sub.2] and hospitalization for respiratory diseases in females and males using both methods of analysis. However, the effects of S[O.sub.2] on female respiratory admissions were consistently elevated in all age groups. Although the time-series analysis showed elevated effects of CO on respiratory hospitalization of females, only CO lag 2 was significantly associated with the hospitalization of females 0-14 years of age (RR = 1.07; 95% CI, 1.001-1.139). The case-crossover results showed that CO had both immediate and delayed effects on respiratory admissions for females 0-14 years of age, with RRs of 1.15 (95% CI, 1.006-1.307), 1.19 (95% CI, 1.020-1.379), and 1.22 (95% CI, 1.022-1.459) for lags 1, 2, and 3, respectively. The effects of CO on the respiratory admissions of females in the 15-64 and [greater than or equal to] 65 age groups were elevated, but none were significant. There were no significant associations between CO and respiratory admissions in any of the male age groups. We also found no significant association between 03 and respiratory admissions on either females or males, although the effects were elevated mostly among the young and elderly age groups in the case-crossover analysis. The time-series results showed that P[M.sub.10] lag 2 is significantly associated with respiratory hospitalization for males 15-64 years of age, with an RR of 1.18 (95% CI, 1.036-1.332). In the case-crossover analysis, the effects of P[M.sub.10] on respiratory admissions were mostly elevated, but not significant, in all the groups except for males 0-14 years of age. COH (lag 3) was significantly associated with the admission of all females (RR = 1.07; 95% CI, 1.004-1.135) and for females 15-64 years of age (RR = 1.15; 95% CI, 1.020-1.296) in the time-series analysis. When all the age groups were combined, the case-crossover analysis also showed that COH had an immediate effect on the admission of women for respiratory disease, with an RR of 1.09 (95% CI, 1.037-1.176). COH lags 2 and 3 were also significantly associated with respiratory admissions for females 15454 years of age, with RRs of 1.20 (95% CI, 1.003-1.426) and 1.29 (95% CI, 1.051-1.582) respectively. None of the effects of COH on the hospitalization of females 0-14 and [greater than or equal to] 65 years of age for respiratory disease was significant. Furthermore, none of the male groups showed a significant association between COH and respiratory admissions. Using both methods, we found no significant associations between TRS and respiratory admissions for any group, but the case-crossover results suggested there might be a delayed effect of TRS on the younger age groups. Taken together, both the time-series and case-crossover analyses show that young (0-14 years) and adult (15-64 years) females were more likely to be admitted for air-pollution-induced respiratory diseases than were males. Discussion Although ambient pollution levels (N[O.sub.2], S[O.sub.2], CO, COH) in Windsor "area of concern" decreased during the study period, we still see existing levels of some pollutants that had significant effects on respiratory hospitalization. Consistent with Lin et al. (2002), we saw some differences in results between time-series and case-crossover analyses. CIs on RR estimates from the bidirectional case-crossover analysis were slightly wider than those from time series, implying lower statistical power for the bidirectional case-crossover design, as documented previously (Bateson and Schwartz 1999; Fung et al. 2003). Because of the sex dimension we introduced into our analysis, together with differences in analytical approaches, control variables, populations studied, exposure variable averaging times, and cut points, comparison of our findings with other studies is not entirely straightforward (e.g., Burnett et al. 1997). Despite the fact that no comparable RRs can be given, our findings are consistent with those of existing studies qualitatively. Although N[O.sub.2] has been known to increase susceptibility susceptibility the state of being susceptible. Refers usually to infectious disease but may be to physical factors such as wetting or to psychological factors such as harassment. to respiratory infections Noun 1. respiratory infection - any infection of the respiratory tract respiratory tract infection infection - the pathological state resulting from the invasion of the body by pathogenic microorganisms (Speizer et al. 1980), results of different studies that examined the link between N[O.sub.2] and respiratory outcomes continued to vary. For instance, Atkinson et al. (1999), working in London, reported no significant associations between N[O.sub.2] and respiratory admissions overall or within any of three age groups (0-14, 15-64, and [greater than or equal to] 65 years). As part of the Air Pollution and Health: A European Approach (APHEA APHEA Australasian and Pacific Hansard Editors Association ) project, Spix et al. (1998) reported no significant association between N[O.sub.2] and respiratory admissions for the 15-64 and [greater than or equal to] 65 year age groups. In Paris, France (Dab et al. 1996), and in Birmingham, England (Wordley et al. 1997), a lack of associations between N[O.sub.2] and hospital admissions for respiratory diseases was observed. On the other hand, Wong et al. (1999) reported significant associations between N[O.sub.2] and respiratory admissions for 0-4, 5-64 and [greater than or equal to] 65 year age groups in Hong Kong Hong Kong (hŏng kŏng), Mandarin Xianggang, special administrative region of China, formerly a British crown colony (2005 est. pop. 6,899,000), land area 422 sq mi (1,092 sq km), adjacent to Guangdong prov. . Similarly, in London, England, Ponce de Leon Ponce de Le·ón , Juan 1460-1521. Spanish explorer who sailed with Columbus on his second voyage (1493-1494) and discovered Florida (1513) while looking for the legendary Fountain of Youth. Noun 1. et al. (1996) found a significant association between summer exposure to N[O.sub.2] lag 2 and respiratory admissions for children 0-14 years of age. In the present analysis, we found a significant association between N[O.sub.2] lag 2 and respiratory admissions for females 0-14 years of age, but not for any of the other female or male groups. The effect of S[O.sub.2] on respiratory hospitalization varies considerably, especially at low levels of exposure. For example, Spix et al. (1998), Sunyer et al. (2003), and Wordley et al. (1997) reported no consistent association between S[O.sub.2] and respiratory admissions. However, studies in Milan, Italy (Vigotti et al. 1996), in Paris, France (Dab et al. 1996), and in London, England (Walters et al. 1994), found S[O.sub.2] levels influenced hospital admissions for all respiratory diseases. Atkinson et al. (1999) reported a strong association between S[O.sub.2] and respiratory admissions among 0- to 14-year-olds. Wong et al. (1999) observed significant short-term effects between S[O.sub.2] and respiratory admissions in the [greater than or equal to] 65 age group but not among younger age groups. Furthermore, Ponce de Leon et al. (1996) found a positive association between S[O.sub.2] lag 1 (in cool season) with respiratory admissions for adults 15-64 years of age; there was no significant association in either the 0-14 or [greater than or equal to] 65 age groups. Bates Bates , Katherine Lee 1859-1929. American educator and writer best known for her poem "America the Beautiful," written in 1893 and revised in 1904 and 1911. and Sizto (1987) found an association between S[O.sub.2] (2-day lag) and respiratory admissions in southern Ontario. Consistent with these findings, the time-series analysis in this study showed a significant association between S[O.sub.2] (lag 1) and respiratory admissions for females 0-14 years of age. However, the significance of S[O.sub.2] in all other age groups may be minimal because ambient concentrations of S[O.sub.2] in Ontario have decreased by more than 86% over recent decades (MOE 2000). Nonetheless, there is a need for continuous attention because of the number of people exposed and the existence of high-risk groups high-risk group Epidemiology A group of people in the community with a higher-than-expected risk for developing a particular disease, which may be defined on a measurable parameter–eg, an inherited genetic defect, physical attribute, lifestyle, habit, . According to Burnett et al. (1999), because there is a strong correlation between CO and other pollutants regularly used in air pollution studies, it is usually difficult to examine the effects of CO independent of all other pollutants. It is therefore not surprising that the literature on the effects of CO on respiratory illness Noun 1. respiratory illness - a disease affecting the respiratory system respiratory disease, respiratory disorder adult respiratory distress syndrome, ARDS, wet lung, white lung - acute lung injury characterized by coughing and rales; inflammation of the has also been mixed at best. For instance, Atkinson et al. (1999) found no association between CO and respiratory admissions either overall or by age group. However, in Korea, Cho et al. (2000) after controlling for seasonal and temperature effects, found an association between CO and hospital admissions for respiratory disease with RRs ranging from 1.21 to 3.55, depending on whether the area is rural or urban. In this study, we found that females 0-14 years of age were more likely to be admitted as a result of their exposure to CO in both the time-series and case-crossover models, although only CO lag 2 was significant in the former case. Although the effects of CO on respiratory admissions of women [greater than or equal to] 65 years of age were elevated for all lags, they were not statistically significant. It is important to note that significant reduction in CO had been achieved in the preceding 10 years in Windsor (mean = 1.0 ppm (Pages Per Minute) The measurement of printer speed. See gppm. PPM - Portable Pixmap in 1991 to 0.3 in 2000) because of more stringent regulatory effort in air quality (MOE 2000). There are contrasting reports on the effect of [O.sub.3] on respiratory admissions. For instance, studies in The Netherlands (Schouten et al. 1996), in London (Atkinson et al. 1999) and in Paris (Dab et al. 1996) found no significant associations between [O.sub.3] and respiratory hospitalization. However, Burnett et al. (1997) reported an association between [O.sub.3] and respiratory admissions in several Canadian cities, using data from 1981 through 1991. In Hong Kong, Wong et al. (1999) reported that [O.sub.3] had a significant effect on respiratory admissions with an RR of 1.022. Ponce de Leon et al. (1996) found an association between [O.sub.3] and daily respiratory admissions for the 15-64 and [greater than or equal to] 65 age groups but not for the 0-14 age group. Spix et al. (1998) observed a consistent association between [O.sub.3] and respiratory admissions in five European cities, and the effects were stronger in the [greater than or equal to] 65 age group. In our analysis, we found elevated risk in the 0-14 and [greater than or equal to] 65 age groups; however, none of these RRs was statistically significant. Several studies have reported positive and significant effects of P[M.sub.10] on respiratory admissions. In Toronto, Canada (Burnett et al. 1999), and in Hong Kong (Wong et al. 1999), P[M.sub.10] has been found to be associated with respiratory admissions. A study by Schwartz (1996) in Spokane, Washington Spokane (pronounced [spoʊ̯ˈkæn]) is a city located in Eastern Washington. The seat of Spokane County, Spokane is the metropolitan center of the Inland Northwest, the second largest city in Washington state, and (USA), found P[M.sub.10] to be significantly associated with respiratory hospitalization of women [greater than or equal to] 65 years of age. The association between P[M.sub.10] and respiratory admission was demonstrated further by Atkinson et al. (1999), who found significant effects in all age groups (0-14, 15-64, and [greater than or equal to] 65), although the effect was strongest in the 0-14 age group. In the present study, P[M.sub.10] (lag 2) was significantly associated with respiratory admission of males 15-64 years of age. The elevated effects of P[M.sub.10] found in this study for all female age groups and for adult and elderly males are in line with the notion that P[M.sub.10] influences inflammatory mechanisms in respiratory organs (Hitzfeld et al. 1997). Compared with other pollutants, the effect of COH on respiratory admissions has not been frequently examined (Goldberg et al. 2001). However, one study found that COH was the strongest predictor of hospitalizations for respiratory diseases among particle-related pollutants examined in both single- and multiple-pollutant regression models (Burnett et al. 1997). Consistent with this later report, we found COH to be significantly related to female respiratory hospitalization, and more so among adult females. Overall, our results show that there were more elevated effects with female respiratory hospitalization in relation to ambient air pollution compared with males. The reasons for these differences are unclear. However, several authors have suggested possible explanations for existing sex differences observed in respiratory health. According to Redline red·line v. red·lined, red·lin·ing, red·lines v.intr. 1. To refuse home mortgages or home insurance to areas or neighborhoods deemed poor financial risks. 2. and Gold (1994), sex differences in respiratory diseases relate to differences in hormonal status, potentially influencing airway airway /air·way/ (-wa) 1. the passage by which air enters and leaves the lungs. 2. a device for securing unobstructed respiration. inflammation and smooth muscle and vascular functions. Differences may also be related to differences in the rates of lung growth and decline, and the relative changes in airway and parenchymal pa·ren·chy·ma n. 1. Anatomy The tissue characteristic of an organ, as distinguished from associated connective or supporting tissues. 2. size, in females and males. For instance, the deposition of pollution particles in the lung has been shown to vary by sex, with greater lung deposition fractions of 1-pm particles in females compared with males (Kim and Hu 1998; Kohlhaufl et al. 1999), leading to a more female susceptibility to respiratory diseases. Additionally, despite significant social progress, industrial and domestic jobs continue to be different for men and women. In particular, women as a group are poorer than men and may experience different psychosocial psychosocial /psy·cho·so·cial/ (si?ko-so´shul) pertaining to or involving both psychic and social aspects. psy·cho·so·cial adj. Involving aspects of both social and psychological behavior. stresses. Also, women usually perform the bulk of child care, cooking, dusting, and vacuum cleaning. It is therefore possible that women experience greater exposures to viral infections viral infection, n an infection by a pathogenic virus. A virus acts on the cell nucleus, taking over the genetic material within the nucleus and replicating itself. , nitrogen oxides Noun 1. nitrogen oxide - any of several oxides of nitrogen formed by the action of nitric acid on oxidizable materials; present in car exhausts pollutant - waste matter that contaminates the water or air or soil , household irritants, and aeroallergens (Redline and Gold, 1994). Moreover, some studies have shown that women are more sensitive than men to the effect of smoking, with the effects of smoking on lung function greater in women than in men (e.g., Chen et al. 1999; Prescott et al. 1997; Xu et al. 1994). The increased probability of female hospitalization for respiratory disease probably reflects the increase in smoking among women, relative to men, in the last half-century (Canadian Council for Tobacco Control The Canadian Council for Tobacco Control (CCTC) is a registered Canadian charity. It formerly existed as the Canadian Council on Smoking and Health (CCSH). It was founded in 1974 by several non-governmental organizations "concerned with the tobacco epidemic". 2002). Sex differences in respiratory morbidity, may also reflect differences in the management of morbidity. For instance, Goodman Goodman was a polite term of address, used where Mister (Mr.) would be used today. Compare Goodwife. Goodman refers to:
(character) underscore - _, ASCII 95. the need for more work to aid in our understanding of the bases for a female susceptibility to respiratory diseases. Limitations of this study are the same as in studies of this kind. They include the adequacy of covariate control and the impact of measurement error in the exposure and outcome variables. However, for most of the risk factors such as the presence of chronic conditions and cigarette smoking, there is no reason to believe that the individual risk factors are correlated with the daily changes in air pollution; hence, they are not likely to be confounders in this study. Furthermore, the limitations of using fixed monitors to represent the entire population in environmental exposure studies have been frequently discussed (Goldberg et al. 2001). Hence, these results must be interpreted with caution. Nevertheless, the findings still have implications for public health policy. Conclusion This study has found associations between ambient air pollution (N[O.sub.2], S[O.sub.2], CO, COH, and P[M.sub.10]) and daily hospital admission of respiratory diseases especially among females in the Windsor "area of concern." The findings are generally consistent with other studies. Even though the risks of respiratory disease due to ambient air pollution in the general population may seem low, it is reasonable to assume that the risks are much higher among susceptible groups, and our findings here support this hypothesis especially for females in the 0-14 age group. Hence, we recommend that in addressing the intense public concern about the health impacts of environmental quality in this "area of concern" must not only involve stricter guidelines guidelines, n.pl a set of standards, criteria, or specifications to be used or followed in the performance of certain tasks. (which will be beneficial) but also include environmental risk communication, aimed at improving public perception of risk due to poor air quality. In addition, the events of 11 September 2001 brought renewed concerns about the effects of air pollution in the Windsor area. There have been increasing delays resulting in long lines In communications, circuits that are capable of handling transmissions over long distances. of trucks at the border crossing points. The idling trucks are spewing toxic pollutants from their archaic exhaust systems Noun 1. exhaust system - system consisting of the parts of an engine through which burned gases or steam are discharged exhaust automobile engine - the engine that propels an automobile into the air. With Windsor located on the downwind side of Detroit, which is a major source of industrial pollutants, the combined effect of these factors is that the improvements that have been suggested here may no longer be possible to attain. We recommend that more frequent studies examining the link between ambient air quality and health effects be conducted to monitor any changes that may be taking place.
Table 1. Summary statistics of the daily high concentrations
of air pollutants and respiratory admissions, 1 April 1995
through 31 December 2000.
Variable (unit) Mean [+ or -] SD Minimum
0-14 years
Female (n = 626) 0.33 [+ or -] 0.60 0
Male (n = 976) 0.52 [+ or -] 0.79 0
15-64 years
Female (n = 573) 0.30 [+ or -] 0.56 0
Male (n = 310) 0.16 [+ or -] 0.41 0
[greater than or equal to] 65 years
Female (n = 938) 0.50 [+ or -] 0.75 0
Male (n = 791) 0.42 [+ or -] 0.66 0
Total (n = 4,214) 2.23 [+ or -] 1.76 0
S[O.sub.2] (ppb) 27.5 [+ or -] 16.5 0
N[O.sub.2] (ppb) 38.9 [+ or -] 12.3 0
[O.sub.3] (ppb) 39.3 [+ or -] 21.4 1
CO (Ppm) 1.3 [+ or -] 1.0 0
TRS (ppb) 8.1 [+ or -] 10.6 0
P[M.sub.10] ([micro]g/[m.sup.3]) 50.6 [+ or -] 35.5 9
COH 0.6 [+ or -] 0.4 0
Maximum temperature ([degrees]C) 14.2 [+ or -] 11.2 -15.8
Minimum temperature ([degrees]C) 5.3 [+ or -] 9.8 -21.4
Maximum humidity 86.1 [+ or -] 9.2 50.0
Minimum humidity 53.4 [+ or -] 15.0 17.0
Maxp 0.00 [+ or -] 0.54 -2.36
Minp 0.00 [+ or -] 0.70 -3.42
Variable (unit) Maximum (AAQC (a))
0-14 years
Female (n = 626) 4
Male (n = 976) 6
15-64 years
Female (n = 573) 4
Male (n = 310) 3
[greater than or equal to] 65 years
Female (n = 938) 5
Male (n = 791) 5
Total (n = 4,214) 14
S[O.sub.2] (ppb) 129 (100/24 hr)
N[O.sub.2] (ppb) 117 (100/24 hr)
[O.sub.3] (ppb) 129 (80/hr)
CO (Ppm) 11.82 (3/hr)
TRS (ppb) 132 (27/hr)
P[M.sub.10] ([micro]g/[m.sup.3]) 349 (30/24 hr)
COH 3.6 (1.0/24 hr)
Maximum temperature ([degrees]C) 35.7
Minimum temperature ([degrees]C) 25.6
Maximum humidity 100.0
Minimum humidity 98.0
Maxp 2.06
Minp 3.12
Abbreviations: Maxp, change in maximum barometric pressure from
the previous day; Minp, change in minimum barometric pressure
from the previous day.
(a) Ambient air quality criteria (MOE 2000).
Table 2. Correlation coefficients between air pollutants and
weather variables.
N[O.sub.2] S[O.sub.2] CO [O.sub.3]
P[M.sub.10]
N[O.sub.2] 1.00
S[O.sub.2] 0.22 1.00
CO 0.38 0.16 1.00
[O.sub.3] 0.26 -0.02 0.10 1.00
COH 0.49 0.14 0.31 0.23
P[M.sub.10] 0.33 0.22 0.21 0.33
TRS 0.06 0.13 0.11 -0.01
Mint -0.22 -0.12 -0.06 -0.45
Minh 0.06 -0.06 0.02 0.67
Maxt 0.15 -0.01 0.08 0.74
Maxh -0.09 -0.08 0.03 -0.20
Maxp -0.06 -0.03 -0.08 -0.04
Minp -0.03 -0.01 -0.04 -0.04
COH P[M.sub.10] TRS Mint
P[M.sub.10]
N[O.sub.2]
S[O.sub.2]
CO
[O.sub.3]
COH 1.00
P[M.sub.10] 0.39
TRS 0.15 0.05 1.00
Mint -0.16 -0.26 -0.10 1.00
Minh 0.21 0.25 0.08 -0.19
Maxt 0.28 0.34 0.06 0.95
Maxh 0.03 -0.09 0.09 -0.02
Maxp -0.05 -0.14 -0.02 -0.13
Minp -0.05 -0.13 0.04 -0.13
Minh Maxt Maxh Maxp Minp
P[M.sub.10]
N[O.sub.2]
S[O.sub.2]
CO
[O.sub.3]
COH
P[M.sub.10]
TRS
Mint
Minh 1.00
Maxt -0.34 1.00
Maxh 0.63 -0.07 1.00
Maxp -0.18 -0.14 -0.23 1.00
Minp -0.18 -0.15 -0.27 0.67 1.00
Abbreviations: Maxh, maximum humidity; Maxp, change in maximum
barometric pressure from the previous day; Maxt, maximum temperature;
Minh, minimum humidity; Minp, change in minimum barometric pressure
from the previous day; Mint, minimum temperature.
Table 3. RRs (95% Cls) for single-pollutant models using time-series
method for an increase in IQR. (a)
All age groups
Pollutants (IOR) Female Male
N[O.sub.2] (16 ppb)
Lag 1 1.035 (0.971-1.104) 0.944 (0.886-1.006)
Lag 2 1.027 (0.967-1.094) 0.958 (0.900-1.021)
Lag 3 1.036 (0.970-1.107) 0.970 (0.909-1.036)
S[O.sub.2] (19.25 ppb)
Lag 1 1.041 (0.987-1.098) 0.953 (0.900-1.009)
Lag 2 1.041 (0.979-1.107) 0.984 (0.925-1.048)
Lag 3 1.046 (0.982-1.1141 0.987 (0.925-1.053)
CO (1.17 ppm)
Lag 1 1.049 (0.993-1.108) 0.989 (0.932-1.049)
Lag 2 1.032 (0.993-1.188) 0.986 (0.946-1.029)
Lag 3 1.051 (0.993-1.112) 0.987 (0.929-1.048)
[O.sub.3] (29 ppb)
Lag 1 0.947 (0.819-1.096) 1.039 (0.923-1.170)
Lag 2 1.006 (0.852-1.188) 1.063 (0.917-1.232)
Lag 3 1.043 (0.873-1.246) 1.057 (0.891-1.254)
P[M.sub.10] (31
[micro]g/
[m.sup.3])
Lag 1 0.996 (0.950-1.044) 1.008 (0.965-1.054)
Lag 2 1.015 (0.963-1.069) 1.036 (0.986-1.089)
Lag 3 1.022 (0.968-1.078) 1.027 (0.974-1.083)
COH (0.5)
Lag 1 1.051 (0.994-1.113) 0.977 (0.922-1.036)
Lag 2 1.032 (0.982-1.086) 0.991 (0.942-1.043)
Lag 3 1.067 (1.004-1.135) * 1.001 (0.940-1.066)
TRS (8 ppb)
Lag 1 0.990 (0.939-1.038) 0.997 (0.961-1.035)
Lag 2 0.987 (0.939-1.038) 0.999 (0.950-1.051)
Lag 3 0.976 (0.924-1.032) 1.003 (0.949-1.060)
0-14 years
Pollutants (IOR) Female Male
N[O.sub.2] (16 ppb)
Lag 1 1.114 (0.994-1.248) 0.955 (0.866-1.054)
Lag 2 1.107 (0.990-1.238) 0.918 (0.833-1.012)
Lag 3 1.108 (0.987-1.245) 0.927 (0.838-1.025)
S[O.sub.2] (19.25 ppb)
Lag 1 1.111 (1.011-1.221) * 0.952 (0.874-1.037)
Lag 2 1.090 (0.977-1.216) 0.981 (0.892-1.078)
Lag 3 1.066 (0.952-1.194) 0.995 (0.904-1.096)
CO (1.17 ppm)
Lag 1 1.077 (0.979-1.184) 1.034 (0.949-1.126)
Lag 2 1.068 (1.001-1.139) * 0.996 (0.933-1.062)
Lag 3 1.100 (0.997-1.213) 0.968 (0.881-1.064)
[O.sub.3] (29 ppb)
Lag 1 1.048 (0.830-1.322) 0.944 (0.745-1.196)
Lag 2 1.084 (0.829-1.433) 0.955 (0.731-1.246)
Lag 3 1.092 (0.796-1.497) 1.001 (0.755-1.328)
P[M.sub.10] (31
[micro]g/
[m.sup.3])
Lag 1 1.023 (0.948-1.104) 0.980 (0.912-1.053)
Lag 2 1.035 (0.948-1.130) 1.001 (0.925-1.083)
Lag 3 1.047 (0.956-1.147) 0.980 (0.901-1.065)
COH (0.5)
Lag 1 1.085 (0.986-1.195) 1.004 (0.923-1.093)
Lag 2 1.066 (0.979-1.161) 0.980 (0.907-1.058)
Lag 3 1.094 (0.985-1.216) 0.972 (0.884-1.070)
TRS (8 ppb)
Lag 1 0.957 (0.887-1.031) 0.993 (0.938-1.052)
Lag 2 1.002 (0.913-1.100) 0.982 (0.908-1.063)
Lag 3 1.063 (0.965-1.171) 0.990 (0.909-1.079)
15-64 years
Pollutants (IOR) Female Male
N[O.sub.2] (16 ppb)
Lag 1 1.013 (0.893-1.150) 0.942 (0.790-1.122)
Lag 2 1.044 (0.918-1.187) 0.992 (0.833-1.182)
Lag 3 1.121 (0.978-1.285) 1.012 (0.841-1.216)
S[O.sub.2] (19.25 ppb)
Lag 1 1.031 (0.930-1.144) 0.971 (0.845-1.115)
Lag 2 1.068 (0.950-1.202) 1.046 (0.898-1.218)
Lag 3 1.054 (0.931-1.192) 0.985 (0.837-1.159)
CO (1.17 ppm)
Lag 1 1.072 (0.962-1.195) 0.994 (0.854-1.157)
Lag 2 1.025 (0.944-1.112) 0.988 (0.884-1.104)
Lag 3 1.081 (0.963-1.213) 0.951 (0.806-1.121)
[O.sub.3] (29 ppb)
Lag 1 0.817 (0.621-1.075) 0.959 (0.661-1.393)
Lag 2 0.759 (0.549-1.048) 1.268 (0.832-1.932)
Lag 3 0.893 (0.633-1.261) 1.346 (0.851-2.128)
P[M.sub.10] (31
[micro]g/
[m.sup.3])
Lag 1 1.047 (0.962-1.140) 1.096 (0.982-1.222)
Lag 2 1.049 (0.946-1.163) 1.175 (1.036-1.332) *
Lag 3 1.030 (0.922-1.150) 1.080 (0.938-1.243)
COH (0.5)
Lag 1 1.103 (0.994-1.223) 0.955 (0.820-1.113)
Lag 2 1.056 (0.958-1.164) 0.996 (0.871-1.141)
Lag 3 1.150 (1.020-1.296) * 0.948 (0.799-1.126)
TRS (8 ppb)
Lag 1 1.013 (0.942-1.090) 0.981 (0.896-1.074)
Lag 2 1.023 (0.926-1.130) 1.015 (0.904-1.140)
Lag 3 0.980 (0.874-1.100) 0.988 (0.866-1.128)
[greater than or equal to] 65 years
Pollutants (IOR) Female Male
N[O.sub.2] (16 ppb)
Lag 1 1.020 (0.930-1.1198) 0.9196 (0.832-1.016)
Lag 2 0.987 (0.881-1.106) 0.9620 (0.854-1.084)
Lag 3 0.962 (0.847-1.093) 0.9773 (0.854-1.118)
S[O.sub.2] (19.25 ppb)
Lag 1 1.030 (0.951-1.115) 0.9409 (0.860-1.029)
Lag 2 1.030 (0.927-1.145) 0.9490 (0.845-1.066)
Lag 3 1.074 (0.949-1.215) 0.9561 (0.834-1.096)
CO (1.17 ppm)
Lag 1 1.029 (0.947-1.118) 0.9010 (0.817-0.994)
Lag 2 1.030 (0.928-1.144) 0.9041 (0.803-1.019)
Lag 3 1.013 (0.899-1.142) 0.9632 (0.845-1.098)
[O.sub.3] (29 ppb)
Lag 1 0.945 (0.777-1.150) 1.0961 (0.920-1.306)
Lag 2 1.008 (0.807-1.259) 1.0624 (0.852-1.325)
Lag 3 0.963 (0.763-1.215) 0.9767 (0.757-1.261)
P[M.sub.10] (31
[micro]g/
[m.sup.3])
Lag 1 0.967 (0.900-1.040) 1.0033 (0.934-1.078)
Lag 2 0.993 (0.913-1.079) 1.0298 (0.941-1.127)
Lag 3 0.998 (0.910-1.094) 1.0768 (0.972-1.193)
COH (0.5)
Lag 1 0.996 (0.912-1.088) 0.9381 (0.852-1.033)
Lag 2 0.989 (0.884-1.107) 0.9841 (0.876-1.106)
Lag 3 0.998 (0.875-1.137) 1.0609 (0.928-1.213)
TRS (8 ppb)
Lag 1 0.997 (0.945-1.051) 1.0126 (0.958-1.070)
Lag 2 0.961 (0.892-1.034) 1.0089 (0.9341-1.090)
Lag 3 0.925 (0.845-1.011) 1.0227 (0.934-1.120)
(a) Adjusted for temperature, humidity, and change in barometric
pressure.
* Statistically significant at p < 0.05.
Table 4. RRs (95% CIs) for single-pollutant models using
case-crossover method for an increase in IQR. (a)
All age groups
Pollutants (IQR) Female Male
N[O.sub.2] (16 ppb)
Lag 1 1.078 (0.995-1.168) 0.957 (0.883-1.036)
Lag 2 1.100 (0.998-1.213) 0.960 (0.873-1.055)
Lag 3 1.085 (0.972-1.210) 0.951 (0.854-1.057)
S[O.sub.2] (19.25 ppb)
Lag 1 1.047 (0.978-1.122) 0.939 (0.874-1.009)
Lag 2 1.062 (0.969-1.164) 1.003 (0.914-1.101)
Lag 3 1.073 (0.963-1.195) 0.989 (0.886-1.103)
CO (1.17 ppm)
Lag 1 1.037 (0.968-1.111) 0.950 (0.884-1.020)
Lag 2 1.063 (0.976-1.158) 0.945 (0.862-1.036)
Lag 3 1.087 (0.982-1.203) 0.965 (0.866-1.075)
[O.sub.3] (29 ppb)
Lag 1 1.013 (0.766-1.339) 1.064 (0.930-1.217)
Lag 2 1.066 (0.778-1.462) 1.037 (0.889-1.211)
Lag 3 1.007 (0.712-1.424) 1.015 (0.855-1.207)
P[M.sub.10] (31
[micro]g/
[m.sup.3])
Lag 1 1.034 (0.974-1.098) 0.997 (0.942-1.056)
Lag 2 1.045 (0.972-1.124) 1.022 (0.953-1.097)
Lag 3 1.054 (0.970-1.145) 1.008 (0.930-1.092)
COH (0.5)
Lag 1 1.092 (1.037-1.176) * 0.974 (0.906-1.048)
Lag 2 1.097 (0.998-1.206) 1.001 (0.913-1.098)
Lag 3 1.104 (0.989-1.232) 1.020 (0.915-1.136)
TRS (8 ppb)
Lag 1 1.007 (0.961-1.054) 0.990 (0.945-1.037)
Lag 2 1.000 (0.940-1.064) 1.009 (0.948-1.075)
Lag 3 1.005 (0.935-1.081) 1.018 (0.944-1.098)
0-14 years
Pollutants (IQR) Female Male
N[O.sub.2] (16 ppb)
Lag 1 1.145 (0.996-1.317) 0.981 (0.873-1.103)
Lag 2 1.189 (1.002-1.411) * 0.933 (0.810-1.074)
Lag 3 1.178 (0.973-1.427) 0.910 (0.777-1.066)
S[O.sub.2] (19.25 ppb)
Lag 1 1.119 (0.995-1.259) 0.923 (0.831-1.025)
Lag 2 1.126 (0.957-1.325) 0.984 (0.859-1.128)
Lag 3 1.100 (0.907-1.335) 0.961 (0.819-1.126)
CO (1.17 ppm)
Lag 1 1.147 (1.006-1.307) * 1.003 (0.904-1.113)
Lag 2 1.186 (1.020-1.379) * 0.997 (0.871-1.141)
Lag 3 1.221 (1.022-1.459) * 0.970 (0.824-1.141)
[O.sub.3] (29 ppb)
Lag 1 1.046 (0.800-1.367) 1.070 (0.854-1.340)
Lag 2 1.084 (0.797-1.474) 1.024 (0.797-1.316)
Lag 3 1.013 (0.721-1.425) 1.032 (0.786-1.355)
P[M.sub.10] (31
[micro]g/
[m.sup.3])
Lag 1 1.040 (0.944-1.146) 0.965 (0.887-1.050)
Lag 2 1.032 (0.916-1.162) 0.948 (0.857-1.048)
Lag 3 1.052 (0.919-1.204) 0.914 (0.815-1.025)
COH (0.5)
Lag 1 1.101 (0.971-1.245) 1.025 (0.925-1.134)
Lag 2 1.119 (0.953-1.314) 1.004 (0.880-1.144)
Lag 3 1.086 (0.903-1.307) 0.995 (0.853-1.160)
TRS (8 ppb)
Lag 1 0.982 (0.899-1.072) 0.991 (0.923-1.063)
Lag 2 1.056 (0.941-1.184) 1.015 (0.921-1.118)
Lag 3 1.144 (0.999-1.310) 1.015 (0.933-1.185)
15-64 years
Pollutants (IQR) Female Male
N[O.sub.2] (16 ppb)
Lag 1 1.004 (0.870-1.159) 0.988 (0.806-1.210)
Lag 2 1.055 (0.883-1.260) 1.004 (0.789-1.277)
Lag 3 1.114 (0.915-1.356) 0.972 (0.744-1.268)
S[O.sub.2] (19.25 ppb)
Lag 1 1.002 (0.879-1.141) 0.944 (0.798-1.116)
Lag 2 1.057 (0.893-1.252) 1.071 (0.859-1.334)
Lag 3 1.055 (0.864-1.289) 1.022 (0.785-1.330)
CO (1.17 ppm)
Lag 1 1.005 (0.884-1.141) 1.036 (0.870-1.233)
Lag 2 1.007 (0.859-1.181) 1.033 (0.821-1.299)
Lag 3 1.032 (0.858-1.240) 0.991 (0.760-1.293)
[O.sub.3] (29 ppb)
Lag 1 0.937 (0.723-1.214) 0.899 (0.630-1.282)
Lag 2 0.838 (0.625-1.123) 0.974 (0.651-1.457)
Lag 3 0.877 (0.639-1.203) 0.972 (0.625-1.513)
P[M.sub.10] (31
[micro]g/
[m.sup.3])
Lag 1 1.038 (0.937-1.151) 1.055 (0.926-1.203)
Lag 2 1.051 (0.920-1.200) 1.136 (0.964-1.339)
Lag 3 1.020 (0.872-1.194) 1.026 (0.852-1.236)
COH (0.5)
Lag 1 1.135 (0.997-1.292) 1.013 (0.845-1.214)
Lag 2 1.196 (1.003-1.426) * 1.040 (0.823-1.315)
Lag 3 1.289 (1.051-1.582) * 0.968 (0.740-1.267)
TRS (8 ppb)
Lag 1 0.985 (0.903-1.076) 0.994 (0.895-1.103)
Lag 2 0.960 (0.858-1.074) 1.035 (0.907-1.181)
Lag 3 0.932 (0.813-1.069) 1.016 (0.867-1.192)
[greater than or equal to] 65 years
Pollutants (IQR) Female Male
N[O.sub.2] (16 ppb)
Lag 1 1.081 (0.964-1.212) 0.915 (0.810-1.034)
Lag 2 1.063 (0.925-1.222) 0.959 (0.832-1.105)
Lag 3 1.001 (0.856-1.172) 0.973 (0.829-1.142)
S[O.sub.2] (19.25 ppb)
Lag 1 1.020 (0.924-1.126) 0.968 (0.867-1.082)
Lag 2 1.011 (0.888-1.152) 0.994 (0.861-1.147)
Lag 3 1.044 (0.896-1.216) 1.008 (0.852-1.192)
CO (1.17 ppm)
Lag 1 1.014 (0.922-1.116) 0.867 (0.775-0.970)
Lag 2 1.024 (0.907-1.156) 0.865 (0.752-0.994)
Lag 3 1.035 (0.893-1.200) 0.946 (0.807-1.109)
[O.sub.3] (29 ppb)
Lag 1 1.122 (0.919-1.369) 1.095 (0.896-1.339)
Lag 2 1.147 (0.912-1.444) 1.039 (0.826-1.308)
Lag 3 1.161 (0.901-1.496) 0.987 (0.765-1.273)
P[M.sub.10] (31
[micro]g/
[m.sup.3])
Lag 1 1.027 (0.936-1.125) 0.999 (0.912-1.094)
Lag 2 1.051 (0.943-1.171) 1.059 (0.942-1.191)
Lag 3 1.073 (0.949-1.214) 1.125 (0.985-1.284)
COH (0.5)
Lag 1 1.058 (0.946-1.184) 0.898 (0.799-1.008)
Lag 2 1.029 (0.897-1.181) 0.966 (0.837-1.115)
Lag 3 1.016 (0.865-1.193) 1.048 (0.886-1.241)
TRS (8 ppb)
Lag 1 1.030 (0.965-1.098) 0.990 (0.925-1.061)
Lag 2 0.987 (0.903-1.078) 0.992 (0.902-1.092)
Lag 3 0.967 (0.872-1.073) 0.991 (0.886-1.110)
(a) Adjusted for temperature, humidity, and change in barometric
pressure.
* Statistically significant at p < 0.05.
REFERENCES Akaike H. 1973. Information theory and an extension of the maximum likelihood principle. In: Second International Symposium on Information Theory (Petrov BN, Csaki F, eds). Budapest:Academiai Kiado, 267-281. Atkinson RW, Anderson HR, Strachan DP, Bland JM, Bremner SA, Ponce de Leon A. 1999. Short-term associations between outdoor air pollution and visits to accident and emergency departments in London for respiratory complaints. Eur Respir J 13(2):257-265. Bates CV, Sizto R. 1987. Air pollution and hospital admissions in southern Ontario: the acid summer haze effect. Envrion Res 43:317-331. Bateson TF, Schwartz J. 1999. Control for seasonal variation and time trend in case-crossover studies of acute effects of environmental exposures. Epidemiology epidemiology, field of medicine concerned with the study of epidemics, outbreaks of disease that affect large numbers of people. Epidemiologists, using sophisticated statistical analyses, field investigations, and complex laboratory techniques, investigate the cause 10:539-544. Burnett RT, Brook JR, Yung WT, Dales RE, Krewski D. 1997. Association between ozone and hospitalization for respiratory diseases in 16 Canadian cities. Environ Res 72:24-31. Burnett RT, Cakmak S, Brook JR. 1998. The effect of the urban ambient air pollution mix on daily mortality rates in Canadian Cities. Can J Public Health 89(3):152-156. Burnett RT, Dales RE, Raizenne ME, Krewski D, Summers PW, Roberts GR, et al. 1994. Effect of low ambient levels of ozone and sulfates on the frequency of respiratory admissions to Ontario hospitals. Environ Res 05:172-179. Burnett RT, Smith Doiron M, Stieb D, Cakrnak S, Brook JR. 1999. Effects of particulate par·tic·u·late adj. Of or occurring in the form of fine particles. n. A particulate substance. particulate composed of separate particles. and gaseous gas·e·ous adj. 1. Of, relating to, or existing as a gas. 2. Full of or containing gas; gassy. air pollution on cardio-respiratory hospitalizations. Arch Environ Health 54:139-139. Canadian Council for Tobacco Control. 2002. How Have Smoking Rates Changed in the Last 30 Years? Ottawa, Ontario:National Clearinghouse on Tobacco and Health. Available: http:// www.ncth.ca/NCTH_new.nsf/Docs/DirectLink~Smokingrates last30years?OpenDocument [accessed 14 November 2004]. Chen Y, Dales R, Krewski D, Breithaupt K. 1999. Increased effects of smoking and obesity obesity, condition resulting from excessive storage of fat in the body. Obesity has been defined as a weight more than 20% above what is considered normal according to standard age, height, and weight tables, or by a complex formula known as the body mass index. on asthma among female Canadians: the National Population Health Survey, 1994-1995. Am J Epidemiol 159:255-202. Cho B, Choi J, Yum Yr. 2000. Air pollution and hospital admissions for respiratory disease in certain areas of Korea. J Occup Health 42(4):185-191. Chock DP, Winker SL, Chen C. 2000. A study of the association between daily mortality and ambient air pollution concentrations in Pittsburg, Pennsylvania. J Air Waste Manage Assoc 50:1481-1500. CIHI. 2002. Discharge Abstract Database. Toronto, Ontario: Canadian Institute for Health Information. Available: http:// secure.cihi.ca/cihiweb/dispPage.jsp?cw_page=services dad_e.html [accessed 14 August 2002]. Dab W, Medina S, Quenel P. 1996. Short-term respiratory health effects of ambient air pollution: results of the APHEA project in Paris. J Epidemiol Community Health 50(1):S42-S46. Dockery DW, Pope AC III, Xu X, Spengler JG, Ware JH, Fay ME, et al. 1993. An association between air pollution and mortality in six U.S. cities. N Engl J Med 329:1753-1759. Dominici F, McDermott A, Zeger SL, Samet JM. 2002. On the use of generalized additive models in time series of air pollution and health. Am J Epidemiol 156:193-203. Environment Canada. 2002. Daily Climate Data. Toronto, Ontario:Atmospheric Issues Division, Ontario Climate Centre. Fung KY, Krewski D, Chen Y, Burnett RT, Cakmak S. 2003. Comparison of time series and case-crossover analyses of air pollution and hospital admission data. Int J Epidemiol 32:1064-1070. Fung K, Luginaah IN, Gorey K, Webster Webster, town (1990 pop. 16,196), Worcester co., S Mass., near the Conn. line; settled c.1713, set off from Dudley and Oxford and inc. 1832. The chief manufactures are footwear, fabrics, and textiles. G. 2005. Air pollution and daily hospital admissions for cardiovascular diseases in Windsor, Ontario. Can J Public Health 96(1):29-33. Gilbertson M, Brophy J. 2001. Community health profile of Windsor, Ontario, Canada: anatomy anatomy (ənăt`əmē), branch of biology concerned with the study of body structure of various organisms, including humans. Comparative anatomy is concerned with the structural differences of plant and animal forms. of a Great Lakes Great Lakes, group of five freshwater lakes, central North America, creating a natural border between the United States and Canada and forming the largest body of freshwater in the world, with a combined surface area of c.95,000 sq mi (246,050 sq km). area of concern. Environ Health Perspect 109:827-843. Goldberg MS, Burnett R, Bailar JC III, Brook J, Bonvalot Y, Tamblyn R, et al. 2001. The association between daily mortality and short-term effects of ambient air particle pollution in Montreal, Quebec. 1. Nonaccidental mortality. Environ Res A86:12-25. Goodman DE, Israel E, Rosenberg M, Johnston R, Weiss ST, Drazen JM. 1994. The influence of age, diagnosis, and gender on proper use of metered-dose inhalers metered-dose inhaler Pharmacology A device used to deliver a specified number of doses of a therapeutic inhalant–eg, β-agonist for asthma . Am J Respir Crit Care Med 150(5):1256-1261. Hastie T, Tibshirani R. 1990. Generalized Additive Models. London:Chapman & Hall. Health Canada. 2000. Data and Statistics Compilations for Great Lakes Areas of Concern Great Lakes Areas of Concern are designated geographic areas within the Great Lakes Basin that show severe environmental degradation. There are a total of forty-three areas of concern within the Great Lakes, the majority of twenty-six being in the U.S. . Ottawa:Great Lakes Health Effects Program, Health Canada. Hitzfeld B, Friedrichs KH, Ring J, Behrendt H. 1997. Airborne particulate matter modulates the production of reactive oxygen species reactive oxygen species, n molecules and ions of oxygen that have an unpaired electron, thus rendering them extremely reactive. Many cellular structures are susceptible to attack by ROS contributing to cancer, heart disease, and cerebrovascular disease. in human polymorphonuclear polymorphonuclear /poly·mor·pho·nu·cle·ar/ (-noo´kle-er) having a nucleus so deeply lobed or so divided as to appear to be multiple. pol·y·mor·pho·nu·cle·ar adj. Having a lobed nucleus. granulocytes Granulocytes White blood cells. Mentioned in: Blood Donation and Registry granulocytes (granˑ·y . Toxicology toxicology, study of poisons, or toxins, from the standpoint of detection, isolation, identification, and determination of their effects on the human body. Toxicology may be considered the branch of pharmacology devoted to the study of the poisonous effects of drugs. 120(3):185-195. Insightful Corp. 2001. S-Plus 6, Windows. Seattle, WA:Insightful Corp. Kim CS, Hu SC. 1998. Regional deposition of inhaled in·hale v. in·haled, in·hal·ing, in·hales v.tr. 1. To draw (air or smoke, for example) into the lungs by breathing; inspire. 2. particles in human lungs The human lungs are the human organs of respiration. Humans have two lungs, with the left being divided into two lobes and the right into three lobes. Together, the lungs contain approximately 1500 miles (2,400 km) of airways and 300 to 500 million alveoli, having a total : comparison between men and women. J Appl Physiol 84:1834-1844. Kohlhaufl M, Brand P, Scheuch G, Meyer TS, Schulz H, Haussinger K, et al. 1999. Increased 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. deposition in women with asymptomatic a·symp·to·mat·ic adj. Exhibiting or producing no symptoms. Asymptomatic Persons who carry a disease and are usually capable of transmitting the disease but, who do not exhibit symptoms of the disease are said to be nonspecific nonspecific /non·spe·cif·ic/ (non?spi-sif´ik) 1. not due to any single known cause. 2. not directed against a particular agent, but rather having a general effect. nonspecific 1. airway hyper-responsiveness. Am J Respir Crit Care Med 159:902-906. Lee JT, Schwartz J. 1999. Reanalysis of the effets of air pollution on daily mortality in Seoul, Korea, a case-crossover design. Environ Health Perspect 197:633-836. Lin M, Chen Y, Burnett RT, Villeneuve P, Krewski O. 2002. Effect of short-term exposure to gaseous pollution on asthma hospitalization in children: a bi-directional case-crossover analysis. J Epidemiol Community Health 57:50-55. Lin M, Chen Y, Villeneuve P J, Burnett RT, Lemyre L, Hertzman C, et al. 2004. Gaseous air pollutants and asthma hospitalization of children with low household income 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 , Canada. Am J Epidemiol 159(3):294-303. Maclure M. 1991. The case-crossover design: a method for studying transient effects on the risk of acute events. Am J Epidemiol 133:144-153. MOE. 2000. The Air Quality in Ontario. Toronto:Ontario Ministry of the Environment. Available: http://www.ene.gov.on.ca/ envision/air/AirQuality/2000report.htm [accessed 9 August 2002]. Navidi W. 1998. Bidirectional case-crossover designs for exposures with time trends. Biometrics The biological identification of a person. Examples are face, iris and retinal patterns, hand geometry and voice. Increasingly built into laptop computers, fingerprint readers have become popular as a secure method for identification. 54:596-605. Navidi W, Weinhandl E. 2002. Risk set sampling for case-crossover designs. Epidemiology 13(1):190-105. Neas LM, Schwartz J, Dockery D. 1999. A case-crossover analysis of air pollution and mortality in Philadelphia. Environ Health Perspect 107:629-631. Ponce de Leon A, Anderson HR, Bland JM, Strachan DP. 1996. Effects of air pollution on daily hospital admissions far respiratory disease in London between 1987-88 and 1991-92. J Epidemiol Community Health 33(suppl):S63-S70. Pope C, Dockery D, Schwartz J. 1995. Review of epidemiological epidemiological emanating from or pertaining to epidemiology. epidemiological associations the associative relationships between the frequency of occurrence of a disease and its determinants, its predisposing and precipitating evidence of health effects of particulate air pollution. Inhal Toxicol 7:1-18. Prescott E, Bjerg AM, Anderson PK, Lange P, Vestbo J. 1997. Gender differences in smoking effects on lung function and risk of hospitalization for COPD COPD chronic obstructive pulmonary disease. COPD abbr. chronic obstructive pulmonary disease Chronic obstructive pulmonary disease (COPD) : results from a Danish longitudinal lon·gi·tu·di·nal adj. Running in the direction of the long axis of the body or any of its parts. population study. Eur Respir J 10:822-827. Priestly MB. 1981. Spectral Analysis Spectral analysis may refer to:
New York, Middle Atlantic state of the United States. It is bordered by Vermont, Massachusetts, Connecticut, and the Atlantic Ocean (E), New Jersey and Pennsylvania (S), Lakes Erie and Ontario and the Canadian province of :Academic Press. Ramsay T, Burnett RT, Krewski D. 2003. Exploring bias in generalized additive model for spatial air pollution data. Environ Health Perspect 111:1283-1288. Redline S, Gold D. 1994. Challenges in interpreting gender differences in asthma. Am J Respir Crit Care Med 150:1219-1221. Samet JM, Dominici F, McDermott A, Zeger SL. 2903. New problems for an old design: time-series analyses of air pollution and health. Epidemiology 14(1):11-12. Schouten JP, Vonk JM, de Gaaf A. 1996. Short term effects of air pollution on emergency hospital admissions for respiratory disease: results of the APHEA project in two major cities in the Netherlands, 1977-89. J Epiderniol Community Health 59(suppl 1):S22-S29. Schwartz J. 1994. Air pollution and hospital admissions for the elderly in Detroit, Michigan. Am J Respir Crit Care Med 150:648-655. Schwartz J. 1996. Air pollution and hospital admissions for respiratory disease. Epidemiology 7(1):20-28. Speizer FE, Eerris B Jr, Bishop YM, Spengler J. 1980. Respiratory disease rates and pulmonary pulmonary /pul·mo·nary/ (pool´mo-nar?e) 1. pertaining to the lungs. 2. pertaining to the pulmonary artery. pul·mo·nar·y adj. Of, relating to, or affecting the lungs. function in children associated with N02 exposure. Am Rev Respir Dis 121:3-10. Spix C, Anderson HR, Schwartz J, Vigotti MA, Le Tertre A, Vonk JM, et al. 1998. Short term effects of air pollution on hospital admissions of respiratory diseases in Europe. A quantitative summary of APHEA study results. Arch Environ Health 53:54-64. Sunyer J, Atkinson R, Ballester F, Le Tertre A, Ayres JG, Forastiere F, et al. 2003. Respiratory effects of sulphur dioxide sulphur dioxide Noun Chem a strong-smelling colourless soluble gas, used in the manufacture of sulphuric acid and in the preservation of foodstuffs Noun 1. : a hierarchical multicity analysis in the APHEA 2 study. Occup Environ. Med 60:e2. Available: http://www.occenvmed. com/cgi/content/full/60/8/e2 [accessed 27 January 2005]. Vigotti MA, Rossi G, Bisanti L, Zanobetti A, Schwartz J. 1996. Short term effects of urban air pollution on respiratory health in Milan, Italy, 1900-89. Epidemiol Community Health 33(suppl):S63-S70. Walters S, Griffiths R, Ayres J. 1994. Temporal Having to do with time. Contrast with "spatial," which deals with space. association between hospital admissions for asthma in Birmingham and ambient levels of sulphur dioxide and smoke. 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. 49:133-140. WHO. 1975. Manual of the International Statistical Classification of Diseases, Injuries, and Causes of Death. 9th revision. Geneva Geneva, canton and city, Switzerland Geneva (jənē`və), Fr. Genève, canton (1990 pop. 373,019), 109 sq mi (282 sq km), SW Switzerland, surrounding the southwest tip of the Lake of Geneva. :World Health Organization. Wong TW, Lau TS, Yu TS, Neller A, Wong SL, Tam W, et al. 1999. Air pollution and hospital and cardiovascular diseases in Hong Kong. Occup Environ Med 56:679-683. Wordley J, Walters S, Ayres JG. 1997. Short term variations in hospital admissions and mortality and particulate air pollution. Occup Environ Med 54:108-116. Xu X, Li B, Wang L. 1994. Gender difference in smoking effects on adult pulmonary function. Eur Respir J 7:477-483. Isaac N. Luginaah, (1) Karen Y. Fung, (2) Kevin M. Gorey, (3) Greg Webster, (4) and Chris Wills Chris Wills (born on 17 February 1978) is a Champion of the British game show Countdown and a veteran of numerous other shows. Countdown Chris first appeared on 14 January 2002, and quickly won eight consecutive games, scoring 875 points to make him the runaway number one (2) (1) Department of Geography, University of Western Ontario Western is one of Canada's leading universities, ranked #1 in the Globe and Mail University Report Card 2005 for overall quality of education.[2] It ranked #3 among medical-doctoral level universities according to Maclean's Magazine 2005 University Rankings. , London, Ontario, Canada; (2) Department of Mathematics and Statistics, and (3) School of Social Work, University of Windsor History In 2003, the university marked its 40th anniversary. Its history dates back to the founding of Assumption College in 1857. Originally, Assumption was one the largest colleges associated with the University of Western Ontario. , Windsor, Ontario, Canada; (4) Canadian Institute for Health Information, Toronto, Ontario, Canada Address correspondence to I.N. Luginaah, Department of Geography, Room 1409 Social Science Centre, University of Western Ontario, London, Ontario, N6A 5C2 Canada. Telephone: (519) 661-2111, Ext. 86944. Fax: (519) 661-3750. E-mail: iluginaa@uwo.ca This research was supported in part by a Natural Sciences and Engineering Research Council The Natural Sciences and Engineering Research Council (NSERC) is a Canadian government division that provides grants for research in the natural sciences and in engineering. In 2004-2005, it will invest CAD $850 million in university-based research and training. of Canada operating grant to K.Y.F., a Canadian Institutes of Health Research Canadian Institutes of Health Research (CIHR) is the major federal agency responsible for funding health research in Canada. It is the successor to the Medical Research Council of Canada. (CIHR CIHR Canadian Institutes of Health Research CIHR Cambodian Institute of Human Rights ) investigator award to K.M.G., and an associated CIHR partnership appointment to I.N.L. Received 28 May 2004; accepted 14 December 2004. |
|
||||||||||||||||||||
Printer friendly
Cite/link
Email
Feedback
Reader Opinion