Effects of Temperature and Air Pollutants on Cardiovascular and Respiratory Diseases for Males and Females Older than 65 Years of Age in Tokyo, July and August 1980-1995.We studied exposures to higher daily maximum temperatures and concentrations of air pollutants pollutants see environmental pollution. in Tokyo during the summer months of July and August from 1980 to 1995 and their effects on hospital emergency transports for cardiovascular and 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 for males and females [is greater than] 65 years of age. Cardiovascular diseases Cardiovascular disease Disease that affects the heart and blood vessels. Mentioned in: Lipoproteins Test cardiovascular disease were 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. , cardiac insufficiency cardiac insufficiency n. See heart failure. cardiac insufficiency Heart failure, see there , hypertension, and myocardial infarction myocardial infarction: see under infarction. . Respiratory diseases were asthma, acute and chronic bronchitis chronic bronchitis n. Inflammation of the bronchial mucous membrane, characterized by cough, hypersecretion of mucus, and expectoration of sputum over a long period of time and associated with increased vulnerability to bronchial infection. , and pneumonia. Except for pneumonia, daily maximum temperatures were not associated with hospital emergency transports. Increasing daily maximum temperatures, however, were associated with decreased hospital emergency transports for hypertension. Concentrations of 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. or 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. [is less than or equal to] 10 [micro]m, however, were associated with daily hospital emergency transports for angina, cardiac insufficiency, myocardial infarction, asthma, acute and chronic bronchitis, and pneumonia. For cardiac insufficiency, hypertension, myocardial infarction, asthma, chronic bronchitis, and pneumonia, the expected daily number of emergency transports per million were greater for males than for females. For angina and acute bronchitis acute bronchitis Pulmonology A lower RTI–up to 95% of which are viral–that causes reversible bronchial inflammation Clinical Cough, fever, sputum, wheezing, rhonchi DiffDx Asthma, aspergillosis, occupational exposure, chronic bronchitis, sinusitis, , there were no differences for the expected daily numbers of emergency transports per million between males and females. Key words: air pollutants, cardiovascular disease, elderly, respiratory disease, temperature. Environ Health Perspect 109:355-359 (2001). [Online 13 March 2001] http://ehpnet1.niehs.nih.gov/docs/2001/109p355-359ye/abstract.html Previous studies have examined exposures to daily maximum temperatures and air pollutant pol·lut·ant n. Something that pollutes, especially a waste material that contaminates air, soil, or water. concentrations during the warm summer months of July and August in Tokyo and their effect on the daily number of hospital emergency transports per million for heat stroke (1) and three cerebral vascular diseases vascular diseases, n.pl diseases of the peripheral circulatory system. : cerebral hemorrhage cerebral hemorrhage n. Bleeding into the substance of the cerebrum, usually in the internal capsule. Also called encephalorrhagia, hematencephalon. , cerebral infarction cerebral infarction n. See stroke. cerebral infarction, n the blockage of the flow of blood to the cerebrum, causing or resulting in brain tissue death. , and cerebral ischemia cerebral ischemia, n the reduction or loss of oxygen to the cerebrum; prolonged ischemia may lead to cerebral infarction. (2). Both studies indicated that males and females [is greater than] 65 years of age had the highest daily number of heat stroke and cerebral vascular disease hospital emergency transports per million of any age group to four Tokyo city This article is about the historical Tokyo City. For present-day Tokyo, see Tokyo. Tokyo City (東京市 hospitals. For heat stroke, exposures to daily maximum temperatures ([T.sub.max]) and concentrations of nitrogen dioxide were associated with the daily number of hospital emergency transports per million residents. Exposures to higher [T.sub.max] were associated with a decrease in the daily number of hospital emergency transports per million residents for cerebral hemorrhage. For cerebral infarction, hospital emergency transports per million were associated with increasing daily average [NO.sub.2] concentrations. For cerebral ischemia, exposures to [T.sub.max] and daily average ozone concentrations were associated with the daily hospital emergency transports per million residents. For these four diseases, it was evident that increasing or decreasing numbers of hospital emergency transports per million were not associated with the same set of temperature and air pollutant variables. Therefore, additional studies to examine hospital emergency transports for other diseases as functions of daily maximum temperatures and air pollutant concentrations needed to be conducted on a disease-by-disease basis. The studies on cardiovascular and respiratory diseases in Tokyo were undertaken because in the next 50-100 years, there could be a doubling of atmospheric concentrations of carbon dioxide carbon dioxide, chemical compound, CO2, a colorless, odorless, tasteless gas that is about one and one-half times as dense as air under ordinary conditions of temperature and pressure. (3). This could raise surface temperatures year-round by 1-3 [degrees] C and result in a greater frequency and longer duration of heat waves during warmer months of the year not only in Tokyo but in many other major urban areas worldwide. Also the number of people [is greater than] 65 years of age in Tokyo is increasing (4), and this population appears to be most vulnerable to higher temperatures and higher air pollutant concentrations. The months of July and August in Tokyo are when daily maximum temperatures are the highest and when many air pollutants have high concentrations because of atmospheric chemical and photochemical reactions 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. and meteorological conditions Noun 1. meteorological conditions - the prevailing environmental conditions as they influence the prediction of weather environmental condition - the state of the environment that cause air pollutant concentrations to be high at ground level, especially in large, urban areas. Therefore, months of the year were selected when the frequency of exposures to both higher daily maximum temperatures and air pollutant concentrations would be the greatest. The covariates that were used to determine if temperature or air quality may be associated with each cardiovascular and respiratory disease were [T.sub.max] and air pollutant concentrations for [NO.sub.2], [O.sub.3], 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; , and particles 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. [is less than or equal to] 10 [micro]m [(PM.sub.10]). We chose [T.sub.max] temperatures over average daily temperatures ([T.sub.av]), and minimum daily temperatures ([T.sub.min]), because [T.sub.max] temperatures represented the maximum levels of heat stress that could occur on a daily basis. [T.sub.max] was also selected over the heat index because [T.sub.max] can be more directly associated with core body temperatures. The heat index is not a temperature and is calculated from a complex polynomial polynomial, mathematical expression which is a finite sum, each term being a constant times a product of one or more variables raised to powers. With only one variable the general form of a polynomial is a0xn+a expression for temperature and relative humidity relative humidity n. The ratio of the amount of water vapor in the air at a specific temperature to the maximum amount that the air could hold at that temperature, expressed as a percentage. that makes it difficult to separate the temperature contribution from the relative humidity contribution. The cardiovascular diseases that were examined and their International Classification of Disease, 9th Revision (ICD-9) codes included hypertension (ICD-9 codes The following is a list of codes for International Statistical Classification of Diseases and Related Health Problems. These codes are in the public domain. ICD abbr. 9 code 491), and asthma (ICD-9 code 493). There is an extensive literature about the association between daily mortality and hospital admissions for cardiovascular and respiratory diseases and daily changes in air pollutant concentrations and climate variables (5-36). This literature was important in selecting variables that may affect hospital emergency transports in Tokyo. Exposures to air pollutants have been associated with damage to lung tissues and have been shown to have significant effects on pulmonary function (37-42). Because of the interrelationship in·ter·re·late tr. & intr.v. in·ter·re·lat·ed, in·ter·re·lat·ing, in·ter·re·lates To place in or come into mutual relationship. in of the cardiac and pulmonary systems Pulmonary system Lungs and respiratory system of the body. Mentioned in: Pickwickian Syndrome , damage to lung tissue is an important factor not only in many respiratory diseases, but in many cardiovascular diseases as well. In many epidemiology studies with respiratory and cardiovascular diseases, regression models include adjustments for seasonal climate variability to isolate the contributions of air pollution on the daily number of deaths or hospital admissions for these diseases. The focus of this study, however, was on the months of July and August. We selected these months to obtain an indication of how prolonged exposures to both higher temperatures and air pollutant concentrations could affect hospital emergency transports for a wide variety of diseases. Data Characteristics and Model Development We obtained data on hospital emergency transports to four Tokyo city hospitals for each of the four cardiovascular and respiratory diseases for the summer months of July and August, 1980-1995, for males and females [is greater than] 65 years of age from the Tokyo Emergency Office. In all cases, if a record of transport had been entered into the data collection system for the Tokyo Emergency Office, the patient was transported by an emergency vehicle to the hospital and admitted for the diagnosed disease. The diagnosis was made by the attending physician in the emergency room and was based on the symptoms that the patient presented at the time of arrival. The daily number of hospital emergency transports per million residents for the four cardiovascular and respiratory diseases were determined from population data provided by the Ministry of Health and Welfare The Ministry of Health and Welfare is a branch of the government of South Korea. 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• • (4). Because information was not available on the percentage of males and females in this age group from 1980 to 1995, we,assumed that 50% was male and 50% was female. From 1980 to 1995, the percentage of the population within the city limits of Tokyo of males and females [is greater than] 65 years of age has increased from 7.7% (894,586) in 1980 to 13.2% (1,553,772) in 1995, even though the total population has remained relatively constant at 11.8 million. To determine if there were annual trends in the daily number of hospital emergency transports per million for July and August, we calculated the annual daily average number of cardiovascular disease hospital emergency transports per million for each disease for males and females (Figure 1). The data indicated that the annual daily average numbers of angina and cardiac insufficiency hospital emergency transports per million increased for both males and females in July and August from 1980 to 1995, whereas the annual daily average number of hypertension hospital emergency transports per million appeared to decrease for males and females. There did not appear to be much change in the annual daily average number of myocardial infarction hospital emergency transports per million from 1980 to 1995. However, there did appear to be significant differences in response between males and females for all diseases. From these observations, we concluded that classification variables were needed in the regression model for each cardiovascular disease to account for differences between sexes and annual changes in the July and August number of emergency transports per million. [GRAPH OMITTED] In a similar manner, we calculated the annual daily average number of hospital emergency transports per million for July and August for each respiratory disease (Figure 2). The annual daily average number of pneumonia and asthma hospital emergency transports per million appeared to increase for both males and females from 1980 to 1995. The annual daily average number of hospital emergency transports per million for acute and chronic bronchitis, however, appeared to be unchanged from 1980 to 1995. There did appear to be significant differences in response between males and females for all diseases. As with the cardiovascular diseases, this behavior indicated that classification variables were needed in the regression models for each respiratory disease to account for differences between sexes and for annual changes in the July and August number of emergency transports per million. [GRAPH OMITTED] For the daily number of emergency transports for each cardiovascular and respiratory disease for July and August, 1980-1995, calculations of means and variances of their density functions for each disease are given in Table 1. For the most part, these calculations indicated that the density functions for each disease could be assumed to be Poisson distributed. However, the means and variances were not equal for the distributions for cardiac insufficiency, asthma, and pneumonia. As a result, there may be overdispersion in the distributions for all diseases that will need to be evaluated.
Table 1. Cardiovascular and respiratory diseases studied: means and
variances of the daily number of hospital emergency transports for
males and females > 65 years of age in Tokyo July-August, 1980-1995.
Males Females
Disease (ICD-9 code) Mean Variance Mean Variance
Cardiovascular diseases
Angina(413) 1.79 2.03 1.88 2.25
Cardiac insufficiency(428) 2.21 2.65 2.56 3.70
Hypertension(401-405) 0.96 0.97 1.54 1.61
Myocardial infarction(410) 1.93 2.05 1.35 1.43
Respiratory diseases
Acute bronchitis(466) 0.21 0.23 0.19 0.20
Asthma(493) 1.28 1.55 1.16 1.41
Chronic bronchitis(491) 0.11 0.12 0.07 0.07
Pneumonia(486) 2.33 3.75 1.86 3.14
The population in Tokyo of males and females > 65 years of age
increased from 0.895 million in 1980 to 1.544 million in 1995.
The total population remained relatively constant at 11.8 million
from 1980 to 1995. About 50% of the population is assumed to be
male and 50% is assumed to be female.
We obtained daily average concentrations of air pollutants and climate variables for Tokyo from the Japan Environment Agency. Summary statistics for each of the variables used in this analysis for July and August, 1980-1995 are given in Table 2. Table 3 contains the Pearson correlation coefficients Correlation Coefficient A measure that determines the degree to which two variable's movements are associated. The correlation coefficient is calculated as: among air-quality variables and [T.sub.max]. For the study periods, these results indicate possible correlations between [NO.sub.2] and [PM.sub.10], [NO.sub.2] and CO, and [PM.sub.10] and CO. The daily average concentrations of [NO.sub.2] and CO and [T.sub.max] temperatures increased slightly during this time, indicating that yearly trends in model covariates would need to be taken into account by model calculations.
Table 2. Summary statistics for [T.sub.max] and concentrations of
[NO.sub.2], [O.sub.3], [PM.sub.10], [SO.sub.2], and CO in Tokyo,
July-August, 1980-1995.
No. of ob- Min- Max-
Variable servations imum imum Mean (SD)
[T.sub.max] ([degrees] C) 992 17.3 36.5 28.9 (3.8)
[NO.sub.2] (ppb) 988 5.3 72.2 25.4 (11.4)
[O.sub.3] (ppb) 990 0.05 59.4 13.9 (9.8)
[PM.sub.10] ([micro]g/ 902 7.3 185.4 46.0 (27.1)
[m.sup.3])
[SO.sub.2] (ppb) 948 0.6 28.8 7.7 (4.8)
CO (ppb) 972 41.7 2354.2 667.2 (314.9)
Table 3. Pearson correlation coefficients for [T.sub.max] and air
pollution variables.
Variable [T.sub.max] [NO.sub.2] [O.sub.3]
[T.sub.max] 1.000 0.021 0.313
[NO.sub.2] -- 1.000 0.183
[O.sub.3] -- -- 1.000
[PM.sub.10] -- -- --
[SO.sub.2] -- -- --
CO -- -- --
Variable [PM.sub.10] [SO.sub.2] CO
[T.sub.max] 0.122 0.078 0.066
[NO.sub.2] 0.643 0.333 0.759
[O.sub.3] 0.376 0.259 0.202
[PM.sub.10] 1.000 0.306 0.754
[SO.sub.2] -- 1.000 0.389
CO -- -- 1.000
Analysis Methods We fit generalized linear models Not to be confused with general linear model. In statistics, the generalized linear model (GLM) is a useful generalization of ordinary least squares regression. It relates the random distribution of the measured variable of the experiment (the (GLMs) to hospital emergency transport data for each disease to determine which covariates were significantly associated with each of the four cardiovascular and four respiratory diseases (43). A GLM GLM Global Language Monitor GLM Global Marine (stock symbol) GLM Graduated Length Method (ski instruction) GLM Good Looking Mom (used in pediatric practices) GLM God Loves Me was used because daily numbers of hospital emergency transports per million for each disease were count data. Because only data for emergency transports for July and August were used, confounding confounding when the effects of two, or more, processes on results cannot be separated, the results are said to be confounded, a cause of bias in disease studies. confounding factor effects from seasonal variability were likely to be minimal. In addition, because only data from July and August were being used in this study, it was assumed that the daily number of hospital emergency transports per million for each disease and the daily data for each covariate within any given year were independent of daily disease count and daily covariate data from previous years. Within each 2-month period in each year, however, the daily number of hospital emergency transports and the daily maximum temperature and daily average air pollutant concentration data for a given day can be correlated with the data for each of these variables from previous days. To account for autocorrelations in the temperature and air quality variables, we included lag times of 1-4 days for each of these covariates as additional model variables. Generalized estimating equations that accounted for serial correlations serial correlation The relationship that one event has to a series of past events. In technical analysis, serial correlation is used to test whether various chart formations are useful in projecting a security's future price movements. in the daily number of emergency transports per million data for each disease were used to estimate values for the coefficients of each model covariate (44). The correlation structure for the covariance matrix In statistics and probability theory, the covariance matrix is a matrix of covariances between elements of a vector. It is the natural generalization to higher dimensions of the concept of the variance of a scalar-valued random variable. of these generalized estimating equations was assumed to be autoregressive. When an exchangeable correlation structure was used, model parameter estimates were nearly the same as those estimates given by the autoregressive structure of the covariance matrix. Based on the data given in Figures 1 and 2, classification variables were also included in the models for each disease to account for sex and for unexpected annual trends in the daily number of hospital emergency transports per million and annual trends in [T.sub.max] and air pollutant concentrations. We used PROC (language) PROC - The job control language used in the Pick operating system. ["Exploring the Pick Operating System", J.E. Sisk et al, Hayden 1986]. GENMOD from SAS (1) (SAS Institute Inc., Cary, NC, www.sas.com) A software company that specializes in data warehousing and decision support software based on the SAS System. Founded in 1976, SAS is one of the world's largest privately held software companies. See SAS System. software (45) to model the number of hospital emergency transports per million for each cardiovascular and respiratory disease for males and females for July and August from 1980 to 1995 and to provide parameter estimates for model covariates. The model for the expected daily number of emergency transports per million for each cardiovascular and respiratory disease (ET) for males and females [is greater than] 65 years of age is given as [1] ln(ET) = X[Beta], where X is a matrix that includes a column of 1s for the intercept; classification variable columns for sex and for annual trends; columns for the daily values for [T.sub.max] and/or daily average concentrations for each air pollutant variable with lag times of 1-4 days; columns for interaction effects between pairs of model covariates as indicated from the correlation analysis given in Table 3; and [Beta] is the vector of model coefficients for each model covariate. Population changes from 1980 to 1995 have been included as an offset or normalizing factor in this model so that the expected daily number of hospital emergency transports are expressed as the expected daily number of hospital emergency transports per million. This makes it possible to include changes in population for each 2month interval from 1980 to 1995. To determine which covariates were significant for each disease, we constructed an initial series of models for each of the individual covariates and their lag effects. These initial models for each disease also contained classification variables for sex and annual trends. After each round of model fitting, insignificant model variables were eliminated as indicated by their significance probabilities or p-values, and a reduced model was constructed for the next round of calculations. This process was repeated until the most significant model covariates and classification variables for each disease were identified. At this point variables that included interactions between model covariates and covariates and classification variables were added to the model to determine if they were significant. In the final models, the effects of overdispersion in the count data for each disease were negligible. Results and Discussion Table 4 provides coefficient estimates for significant model covariates, 95% 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%. for these estimates, and significance probabilities (the column designated as Pr [is greater than] |Z|) for model covariates and classification variables that were significant contributing factors for each cardiovascular and respiratory disease. Z is the coefficient estimate for a model covariate divided by its standard error. For the most part, same-day exposures to either [T.sub.max] or an air pollutant variable were significantly associated with each disease. For chronic bronchitis, however, [PM.sub.10] with a lag time of 2 days was the most statistically significant model covariate. When interaction variables were included in the models for each disease, their impacts were negligible. Also for each disease there was a classification variable for sex that indicated diseases for which there were differences in response between males and females. For cardiac insufficiency, hypertension, myocardial infarction, asthma, chronic bronchitis, and pneumonia, the expected daily number of emergency transports per million were greater for males than for females. For angina and acute bronchitis, there were no differences for the expected daily numbers of emergency transports per million between males and females. [T.sub.max] was a significant model covariate only for pneumonia. Concentrations of [NO.sub.2] were significant model covariates for angina, cardiac insufficiency, myocardial infarction, and acute bronchitis. Concentrations of [PM.sub.10] were significant model covariates for asthma, chronic bronchitis, and pneumonia. For hypertension, the daily expected number of hospital emergency transports per million decreased as daily [T.sub.max] increased.
Table 4. Model covariates for cardiovascular and respiratory diseases
for males and females > 65 years of age in Tokyo, July-August,
1980-1995.
95% Confidence
limits
Model Coefficient
Disease covariate(a) estimate(SE) Lower Upper
Cardiovascular
diseases
Angina [NO.sub.2] 0.007 (0.001) 0.004 0.009
Cardiac [NO.sub.2] 0.006 (0.002) 0.003 0.01
insufficiency Male -0.152 (0.03) -0.209 -0.095
Hypertension [T.sub.max] -0.014 (0.005) -0.02 -0.004
Male -0.44 (0.04) -0.52 -0.36
Myocardial [NO.sub.2] 0.006 (0.002) 0.003 0.01
infarction Male 0.374 (0.03) 0.31 0.43
Respiratory diseases
Asthma [PM.sub.10] 0.003 (0.001) 0.001 0.004
Male 0.115 (0.03) 0.06 0.17
Acute bronchitis [NO.sub.2] 0.014 (0.005) 0.004 0.024
Chronic bronchitis [PM.sub.10]-2 0.006 (0.002) 0.001 0.01
Male 0.483 (0.1) 0.28 0.69
Pneumonia [T.sub.max] 0.038 (0.007) 0.02 0.05
[PM.sub.10] 0.003 (0.001) 0.002 0.005
Male 0.226 (0.02) 0.19 0.26
Model
Disease covariate(a) Z-Value(b) Pr > |Z|(c)
Cardiovascular
diseases
Angina [NO.sub.2] 4.8 0.0000
Cardiac [NO.sub.2] 3.54 0.0004
insufficiency Male -5.26 0.0000
Hypertension [T.sub.max] -2.8 0.0056
Male -11.0 0.0000
Myocardial [NO.sub.2] 3.56 0.0004
infarction Male 12.1 0.0000
Respiratory diseases
Asthma [PM.sub.10] 3.32 0.0009
Male 4.1 0.0000
Acute bronchitis [NO.sub.2] 2.67 0.0075
Chronic bronchitis [PM.sub.10]-2 2.6 0.0102
Male 4.63 0.0000
Pneumonia [T.sub.max] 5.24 0.0000
[PM.sub.10] 4.3 0.0000
Male 13.0 0.0000
(a) [T.sub.max], [PM.sub.10], and [NO.sub.2] are the time series for
same-day [T.sub.max] and concentration of [PM.sub.10] and [NO.sub.2];
[PM.sub.10]-2 is the time series for [PM.sub.10] concentrations with a
2-day lag time. (b) Z-values are calculated as the coefficient
estimate/SE. (c) Pr > |Z| is the significance probability.
Many studies (3,25,27-34) have shown correlations between hospital admissions for cardiovascular diseases and CO concentrations. However, the associations between the four cardiovascular diseases and concentrations of CO in these studies for July and August in Tokyo do not appear to be very strong. A possible explanation for this observation may be that daily average concentrations of CO during the summer months from 1980 to 1995 in Tokyo were not high compared to other cities where correlations between CO concentrations and cardiovascular diseases were much stronger. The mean CO concentration for Tokyo during the study period was 0.67 ppm (SD = 0.31 ppm). Morris et al. (5), in their study of seven U.S. cities, found average year-round mean concentrations 3-9 times higher than those observed in the present study. Because of the lower mean CO concentration in Tokyo, exposures to CO appear to have minimal impact on the daily number of hospital emergency transports for the four cardiovascular diseases that were studied. For this group of cardiovascular and respiratory diseases, even though conditions were chosen so that daily temperatures would be at their maximum values, exposures to concentrations of [NO.sub.2] and [PM.sub.10] during the summer months of July and August in Tokyo appeared to be much more significant model covariates for many of these diseases than were exposures to daily maximum temperatures. However, [T.sub.max] was a contributing factor for pneumonia. It would be incorrect to conclude, however, that higher temperatures that may occur as a result of climate change would not be a significant covariate for many of these diseases. Any time increased cardiac output cardiac output n. Abbr. CO The volume of blood pumped from the right or left ventricle in one minute. It is equal to the stroke volume multiplied by the heart rate. is required to return core body temperatures to normal ranges and there are people with cardiovascular and respiratory systems respiratory system: see respiration. respiratory system Organ system involved in respiration. In humans, the diaphragm and, to a lesser extent, the muscles between the ribs generate a pumping action, moving air in and out of the lungs through a that are not functioning at optimal levels because of age or 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. disease, there is an increased probability of emergency transport for a particular cardiovascular or respiratory disease as daily maximum temperatures increase. Future modeling work for these diseases will examine the year-round response to temperature and concentrations of air pollutants and will require the use of 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. (14,46). As with the heat stroke and cerebral vascular disease studies, it is important to note that the model covariates were not the same for each disease. This is not a surprising result because the physiologic and molecular mechanisms for each disease are different, even though cardiovascular and respiratory functions are highly interconnected. Even so, the results of this study strongly suggest that each disease should be considered separately rather than grouped together. It should be noted that possible factors that could be confounders in these studies are the smoking habits of this age group of males and females. Smoking habits and the presence of chronic cardiovascular and respiratory diseases, however, should not change from day to day. Therefore, these existing conditions should not be confounding factors in this study (31). Finally, it is well known that hypertension is a precursor for 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. (cardiac insufficiency in our nomenclature nomenclature /no·men·cla·ture/ (no´men-kla?cher) a classified system of names, as of anatomical structures, organisms, etc. binomial nomenclature ), but it was not possible to account for the possible interrelationships between these two diseases because data on blood pressure at the time of emergency transport and hospital admission for individual patients were not available. REFERENCES AND NOTES (1.) Piver WT, Ando M, Ye F, Portier CJ. Temperature and air pollution as risk factors for heat stroke in Tokyo, July-August 1980-1995. Environ Health Perspect 107:911-916 (1999). (2.) Piver WT, Ando M, Ye F, Pottier CJ. Temperature and air pollution as risk factors for cerebral vascular diseases for 65+ males and females, Tokyo, July-August 1980-1995. World Res Rev 11:337-345 (1999). (3.) Houghton JT, Meira Filho LG, Bruce J, Lee H, Callander BA, Harris N, Kattenberg A, Maskell K. Climate Change 1995. The Science of Climate Change. 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Ambient air pollution hospitilization for congestive heart failure among elderly people in seven 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. cities. Am J Public Health 85:1361-1365 (1995). (6.) Burnett RT, Brook JR, Yung WT, Dales RE, Krewski D. Association between ozone and 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 respiratory diseases in 16 Canadian cities. Environ Res 72:24-31 (1999). (7.) Burnett RT, Cakmak S, Brook JR, Krewski D. The role of particulate par·tic·u·late adj. Of or occurring in the form of fine particles. n. 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Prescott GJ, Cohen cohen or kohen (Hebrew: “priest”) Jewish priest descended from Zadok (a descendant of Aaron), priest at the First Temple of Jerusalem. The biblical priesthood was hereditary and male. GR, Elton RA, Fowkes FG, Agius RM. Urban air pollution and cardiopulmonary cardiopulmonary /car·dio·pul·mo·nary/ (kahr?de-o-pool´mah-nar-e) pertaining to the heart and lungs. car·di·o·pul·mo·nar·y adj. Of, relating to, or involving both the heart and the lungs. ill health: a 14.5 year time series study. Occup Environ Med 55:697-704 (1998). (11.) Schwartz J. Air pollution and hospital admissions for respiratory disease. Epidemiology 7:20-26 (1996). (12.) Schwartz J. Short term fluctuations in air pollution and hospital admissions of the elderly for respiratory disease. 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. 50:531-553 (1995). (13.) Schwartz J. [PM.sub.10], ozone, and hospital admissions for the elderly in Minneapolis-St. Paul, Minnesota. Arch Environ Health 49:366-374 (1994). (14.) Schwartz J. Air pollution and hospital admissions for the elderly in Detroit, Michigan “Detroit” redirects here. For other uses, see Detroit (disambiguation). Detroit (IPA: [dɪˈtʰɹɔɪt]) (French: Détroit, meaning strait . Am J Respir Crit Care Med 150:648-655 (1994). (15.) Schwartz J. Total suspended particulate matter and daily mortality in Cincinnati, Ohio “Cincinnati” redirects here. For other uses, see Cincinnati (disambiguation). Cincinnati is a city in the U.S. state of Ohio and the county seat of Hamilton County. . Environ Health Perspect 102:186-189 (1994). (16.) Schwartz J. Air pollution and hospital admissions for the elderly in Birmingham, Alabama Birmingham (pronounced [ˈbɝmɪŋˌhæm]) is the largest city in the U.S. state of Alabama and is the county seat of Jefferson County. . Am J Epidemiol 139:589-598 (1994). (17.) Schwartz J, Dockery DW. Increased mortality in Philadelphia associated with daily air pollution concentrations. Am Rev Respir Dis 145:600-604 (1992). (18.) Wordley J, Walters S Wal·ters , Barbara Born 1931. American television newscaster and reporter. After working for the National Broadcasting Company (1963-1976), she joined the American Broadcasting Company (1976-1979) and became the first woman to anchor the nightly , Ayres JG. Short term variations in hospital admissions and mortality and particulate air pollution. Occup Environ Med 54:108-116 (1997). (19.) 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. 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Air pollution and emergency room visits for asthma in Santa Clara county, California Santa Clara County is a county located in the San Francisco Bay Area of the U.S. state of California. It is the primary site of Silicon Valley. As of 2000 it had a population of 1,682,585. The county seat is San Jose. . Environ Health Perspect 105:216-222 (1997). (24.) Weisel CP, Cody RP, Lioy PJ. Relationship between summertime ambient ozone levels and emergency department visits for asthma in central New Jersey. Environ Health Perspect 103(suppl 2):97-102 (1995). (25.) Chauhan AJ, Krishna MT, Frew AJ, Holgate ST. Exposure to nitrogen dioxide ([NO.sub.2]) and respiratory disease risk. Rev Environ Health 13(1-2):73-90 (1998). (26.) Ponka A, Virtanen M. Chronic bronchitis, emphysema emphysema (ĕmfĭsē`mə), pathological or physiological enlargement or overdistention of the air sacs of the lungs. 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Modeling mortality fluctuations in Los Angeles as functions of pollution and weather effects. Environ Res 45:224-241 (1988). (37.) Abbey DE, Colome SD, Mills PK, Burchette R, Beeson WL, Tian Tian or T'ien (Chinese; “Heaven”) In indigenous Chinese religion, the supreme power reigning over humans and lesser gods. The term refers to a deity, to impersonal nature, or to both. Y. Chronic disease associated with long-term concentrations of nitrogen dioxide. J Expo Anal Environ Epidemiol 3:181-202 (1993). (38.) Bascom R, Bromberg PA, Costa DA, Devlin R, Dockery DW, Frampton MW, Lambert W, Samet JM, Speizer FE, Utell M. Health effects of outdoor air pollution. Am J Respir Crit Care Med 153:3-50 (1996). (39.) Koenig JQ, Pierson WE. Air pollutants and the respiratory system: toxicity and pharmacologic pharmacologic /phar·ma·co·log·ic/ (-kah-loj´ik) pertaining to pharmacology or to the properties and reactions of drugs. pharmacological, pharmacologic pertaining to pharmacology. interventions. Clin Toxicol 29:401-411 (1991). (40.) Peters A, Doring A, Wichmann H-E, Koenig W. Increased plasma viscosity during an air pollution episode: a link to mortality? Lancet 349:1582-1587 (1997). (41.) Sherwin RP. Air pollution: the pathobiologic issues. Clin Toxicol 29:385-400 (1991). (42.) Rusznak C, Devalia JL, Wang J, Davies RJ. Pollution-induced airway airway /air·way/ (-wa) 1. the passage by which air enters and leaves the lungs. 2. a device for securing unobstructed respiration. disease and the putative underlying mechanisms. Clin Rev Allergy Immunol 15:205-217 (1997). (43.) McCullagh P, Nelder JA. Generalized Linear Models. London:Chapman and Hall Chapman and Hall was a British publishing house, founded in the first half of the 19th century by Edward Chapman and William Hall. Upon Hall's death in 1847, Chapman's cousin Frederic Chapman became partner in the company, of which he became sole manager upon the retirement of , 1989. (44.) Litsitz SR, Fitzmaurice GM, Dray EJ, Laird laird n. Scots The owner of a landed estate. [Scots, from Middle English lard, variant of lord, owner, master; see lord. NM. Performance of generalized estimating equations in practical situations. Biometrics 50:270-278 (1994). (45.) SAS Institute SAS Institute Inc., headquartered in Cary, North Carolina, USA, has been a major producer of software since it was founded in 1976 by Anthony Barr, James Goodnight, John Sall and Jane Helwig. Inc. SAS/STA Software: Changes and Enhancements through Release 6.12. Cary, NC:SAS Institute Inc., 1997. (46.) Kelsall JE, Samet JM, Zeger SL, Xu J. Air pollution and mortality in Philadelphia, 1974-1988. Am J Epidemiol 146:750-762 (1997). Frank Ye,(1) Warren T. Piver,(1) Mitsuru Ando,(2) and Christopher J. Portier(1) (1) 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. , Research Triangle Park Research Triangle Park, research, business, medical, and educational complex situated in central North Carolina. It has an area of 6,900 acres (2,795 hectares) and is 8 × 2 mi (13 × 3 km) in size. Named for the triangle formed by Duke Univ. , North Carolina North Carolina, state in the SE United States. It is bordered by the Atlantic Ocean (E), South Carolina and Georgia (S), Tennessee (W), and Virginia (N). Facts and Figures Area, 52,586 sq mi (136,198 sq km). Pop. , USA; (2) National Institute for Environmental Studies, Tsukuba, Japan Address correspondence to W. Piver, National Institute of Environmental Health Sciences, MD EC-14, P.O. Box 12233, Research Triangle Park, NC 27709 USA. Telephone: (919) 541-3471. Fax: (919) 541-0144. E-mail: piver@niehs.nih.gov Received 19 July 2000; accepted 7 November 2000. |
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