Air Pollution and Markers of Inflammation and Coagulation in Patients with Coronary Heart Disease
http://www.100md.com
《美国呼吸和危急护理医学》
GSF–National Research Center for Environment and Health, Institute of Epidemiology, and Focus-Network Aerosols and Health, Neuherberg
IBE Department of Epidemiology, Ludwig-Maximilians-University of Munich, Munich
Department of Internal Medicine II, Cardiology, University of Ulm Medical Center, Ulm, Germany
Department of Medicine and Dentistry, Vascular Medicine, and Pulmonary and Critical Care Unit, Rochester School of Medicine and Dentistry, Rochester, New York
ABSTRACT
Rationale: Ambient air pollution has been shown to be associated with cardiovascular morbidity and mortality.
Objectives: A prospective panel study was conducted to study the early physiologic reactions characterized by blood biomarkers of inflammation, endothelial dysfunction, and coagulation in response to daily changes in air pollution in Erfurt, Germany.
Methods: Blood parameters were repeatedly measured in 57 male patients with coronary heart disease during the winter of 2000/2001. Fixed-effects linear and logistic regression models were applied, adjusting for trend, weekday, and meteorologic parameters.
Measurements: Hourly data on ultrafine particles (UFPs; number concentration of particles from 0.01 to 0.1 μm), mass concentration of particles less than 10 (PM10) and 2.5 μm in diameter, elemental and organic carbon, gaseous pollutants, and meteorologic data were collected at central monitoring sites.
Main Results: Increased levels of C-reactive protein above the 90th percentile were observed for an increase in air pollution concentrations of one interquartile range. The effect was strongest for accumulation mode particles, with a delay of 2 d (odds ratio [OR], 3.2; confidence interval [CI], 1.7, 6.0). Results were consistent for UFPs and PM10, which also showed a 2-d delayed response (OR, 2.3; CI, 1.3, 3.8; and OR, 2.2; CI, 1.2, 3.8, respectively). However, not all of the blood markers of endothelial dysfunction and coagulation increased consistently in association with air pollutants.
Conclusion: These results suggest that inflammation as well as parts of the coagulation pathway may contribute to the association between particulate air pollution and coronary events.
Key Words: acute-phase reaction air pollution blood coagulation cardiovascular diseases C-reactive protein
Increasing evidence suggests that ambient air pollution may adversely affect the cardiovascular system. It has been shown that ambient air pollution leads to increased cardiovascular mortality (1–6), and studies found associations between ambient air pollution and hospital admissions for various cardiovascular diseases, including congestive heart failure (7–9). Also, an increased risk for acute myocardial infarction (MI) (10) and cardiorespiratory symptoms (11) has been reported in association with particulate air pollution.
The exact mechanisms linking the inhalation of ambient air particles to an acute exacerbation of cardiovascular disease are not completely understood (12). Seaton and coworkers (13) hypothesized that inhaled particles would lead to alveolar inflammation, which increases the level of blood coagulability, thus leading to an increased risk of ischemic events in susceptible individuals. DeMeo and colleagues (14) found reduced oxygen saturation in association with particulate matter of less than 2.5 μm in diameter (PM2.5). Pope and colleagues (15), who linked long-term exposure to particulate air pollution to various causes of mortality, found a strong and robust association between PM2.5 and cardiovascular disease mortality. They concluded that exposure to particulate air pollution and cardiopulmonary mortality risk is linked by accelerated pulmonary and systemic inflammation. Moreover, Peters and coworkers (16) demonstrated increased levels of plasma viscosity during an air pollution episode in central Europe, compared with less polluted days. Increased plasma concentrations of C-reactive protein (CRP), the classic acute-phase protein, were also shown during the 1985 air pollution episode (17).
There is a strong link between inflammation and coronary heart disease (CHD) because factors involved in inflammation and infection seem to play a proatherogenic role and inflammation has been identified as a potent risk factor for acute coronary syndrome. Systemic inflammation could result in destabilization or even rupture of vulnerable atheromatous plaques, leading to acute ischemic events.
Most of the cited studies have been conducted in the general population or in elderly healthy subjects. This study looks at a susceptible subgroup to provide insight into the ways in which air pollution might precipitate death in persons with underlying heart disease, based on the hypothesis that particulate air pollution can alter cardiovascular function.
Repeated measurements of markers of an early inflammatory response, cell recruitment and coagulation, were compared with concurrent levels of air pollution. Our primary hypothesis was that CRP, a well-known marker for inflammation, would increase in association with a rise in levels of air pollution. Moreover, we analyzed various other markers of inflammation (serum amyloid A [SAA]), cell adhesion (E-selectin, von Willebrand factor antigen [vWf], intercellular adhesion molecule 1 [ICAM-1]), and coagulation (fibrinogen, factor VII [FVII], prothrombin fragment 1+2, D-dimer) on a more explorative basis hypothesizing that the levels of these blood markers would also go up in association with higher levels of air pollution, as seen in Figure 1. Some results have been previously presented in form of an abstract (18).
METHODS
Study Design
As part of the University of Rochester Particulate Matter Center, a prospective panel study was conducted between October 15, 2000, and April 27, 2001, in Erfurt, Germany. The panel consisted of male patients with CHD who were scheduled for 12 subsequent clinical visits. Each clinical visit included a short interview and the withdrawal of a blood sample. At the first visit, a baseline questionnaire was administered regarding health status, pulmonary and cardiac symptoms, medication intake, and smoking history.
Sixty-one nonsmoking men, aged 50 yr or older, with physician-diagnosed CHD were recruited through a local cardiologist. Patients with pacemakers, recent (< 3 mo ago) MI, bypass surgery, or balloon dilatation were not included because the inflammatory processes involved in such a procedure might not yet have subsided. Persons with type 1 diabetes or on anticoagulation therapy (except for antiplatelet agents) were also not included. A written, informed consent was obtained from all subjects. The study protocol was approved by the German Ethics Committee of the "Bayerische Landesrztekammer" in Munich, Germany. All methods used in the study were conducted according to standard operating procedures and were tested beforehand in a 2-wk pilot study.
Air Pollution Monitoring
Concentrations of different ambient air pollutants were measured at one fixed monitoring site in the city center representing urban background levels. The measurement site was put up especially for carrying out epidemiologic studies (19, 20) and all measurements were conducted according to the standard operating procedures developed within the framework of previous studies (21–23).
Continuous ultrafine particle (UFP) counts (0.01–0.1 μm), accumulation mode particle (AP) counts (0.1–1.0 μm), and fine-particle mass (PM2.5) were measured with the mobile aerosol spectrometer (MAS). The MAS, described previously (24, 25), consists of two different, commercially available instruments covering different size ranges. Particles in the size range from 0.01 to 0.5 μm were measured using a differential mobility particle sizer (TSI, Aachen, Germany). Particles in the size range from 0.1 to 2.5 μm were classified by an optical laser aerosol spectrometer (PMS, Leonberg, Germany).
PM10 (particulate matter < 10 μm in diameter) data were collected by the tapered element oscillating microbalance method (TEOM 1400a; Rupprecht and Patashnik, Albany, NY) and continuous data on elemental (EC) and organic carbon (OC) were measured with an ambient carbon monitor (ACM 5400; Rupprecht and Patashnick). Data on meteorologic variables for this period as well as concentrations of gaseous air pollutants were collected from existing networks. Missing values of the ambient UFPs between January 20 and February 13 were imputed by a linear regression model based on parallel measurements with a condensation particle counter and a scanning mobility particle sizer. The R squares for the regression model was 0.96. Also, between December 2000 and May 2001, approximately 15% of the PM2.5 measurements by MAS were lost. These missing values were replaced by corrected data based on parallel measurements with TEOM-PM10 and Harvard Impactor-PM2.5. (Air Diagnostic and Engineering, Inc., Naples, ME).
For each person and visit, the individual 24-h average of pollutants immediately preceding the clinical visit (lag 0) up to Day 5 (lag 1–4) and 5-d running means before the examination were calculated if more than two-thirds of the hourly measurements were available for this period.
Clinical Measurements
The clinical visits were scheduled on the same weekday (Monday to Friday) and time (8:00 A.M. to 5:00 P.M.) for each patient once every 2 wk.
At each visit, ethylenediaminetetraacetic acid and citrate plasma samples were drawn (Becton Dickinson, Franklin Lakes, NJ). Samples were centrifuged and aliquots were immediately stored at –20°C until analysis. CRP (high-sensitivity assay), SAA, and fibrinogen were analyzed by immunonephelometry (Dade Behring, Marburg, Germany). ICAM-1, E-selectin (R&D Systems, Wiesbaden, Germany), and prothrombin fragment 1+2 (Dade Behring) were measured by means of a commercial ELISA. D-dimer and vWf were analyzed using an immunoturbidimetric method and FVII by clotting time measurement (Diagnostica Stago, Asnieres-sur-Seine, France).
Study Subjects
Fifty-seven of 61 patients were included in the analyses. One patient refused to participate, and three patients had to be excluded for the following reasons: two were diagnosed with leukemia or lymphoma and one patient had constantly elevated levels of white and red blood cells, indicating an unknown hematologic disorder. Fifty-five patients participated in 12, one patient participated in nine, and one patient participated in eight scheduled visits (99% completeness). Blood samples of patients reporting an acute infection and/or surgery during the 2 wk before the examination were excluded from the analysis (46 blood samples [7%] of 19 different patients). Also, 18 blood samples (3%) in 15 patients showing implausibly low fibrinogen values (< 1.0 g/L) on nephelometry were excluded from the analysis. Finally, not all patients were able to give the scheduled amount of blood at each visit. Therefore, between 544 blood samples (87%) and 581 blood samples (92%) remained for analysis, depending on the marker.
Statistical Analyses
Continuous concentrations of the blood markers were analyzed using linear regression models. Also, values above the 90th percentile were assessed using logistic regression models (17). Generalized additive models, including pollutant and confounder variables, were used for fixed-effects regression with individual intercepts for each patient. Long-term time trend, an indicator variable for each subject, weekday of the visit, and the meteorologic parameters air temperature, relative humidity, and barometric pressure, each with lag 0 to lag 3, were considered as potential confounders. Because the half-life of most markers is only a couple of hours and the visits took place in 2-wk intervals, it was assumed that no autocorrelation was present in the patient data, and no adjustment for autocorrelation was made.
Prothrombin fragment 1+2, FVII, SAA, CRP, and E-selectin were log-transformed before analysis because their residuals remained skewed after multivariate modeling.
Model building was done for each blood parameter separately without an air pollution variable. To explore the shape of the association between confounders and blood markers, nonparametric smooth functions on the basis of locally weighted least squares were applied for all confounders. Model fit was rated on the basis of the Akaike information criterion (AIC). In the final model, nonparametric smooth functions were replaced by appropriate polynomials (degree 2 or 3) or natural splines based on lowest AIC. After the model fit was completed, dose–response functions of the confounders were checked visually and in case implausible shapes were observed, degrees of freedom were decreased. Each pollutant was added separately to the final model.
Data were analyzed using the statistical package SAS version 8.2 (SAS Institute, Inc., Cary, NC) and S-Plus version 6.0 (Mathsoft Engineering and Education, Inc., Cambridge, MA).
Logistic regression models were used to determine whether the effect was limited to the upper tail of the distribution. Confounder adjustment was done in the same way as described for the linear regression models; however, more parsimonious models were used. Sensitivity analyses were done to explore the influences of the different confounder models.
RESULTS
Patient Characteristics
Patient characteristics are summarized in Table 1. The study population comprised 57 nonsmoking men, aged 51 to 76 yr. Approximately 84% of them were retired. Except for one person, all patients had stopped smoking at least 1 yr before the examinations.
Air Pollutants
The distributions of the 24-h average concentrations of the particulate and gaseous pollutants as well as meteorologic data are given in Table 2.
PM10, PM2.5, and AP were highly correlated (r = 0.90–0.91), whereas UFPs were only moderately correlated with PM10 and PM2.5 (r = 0.57 and 0.41, respectively). PM2.5 showed a moderate negative correlation with air temperature (r = –0.5; Figure 2). EC and OC showed high correlation (r = 0.96) and were also highly correlated with all other particle fractions (r = 0.63–0.90). Also, CO and NO2 were highly correlated (r = 0.82), whereas the correlation for UFPs with NO2 was slightly lower than with CO (r = 0.75 and 0.82, respectively).
Blood Parameters
Levels of blood parameters are summarized in Table 3. Parameters of the acute-phase response, SAA and CRP, were correlated (r = 0.53), as were the adhesion molecules ICAM-1 and E-selectin (r = 0.53). However, no significant correlation was seen between markers of an acute-phase response and adhesion molecules (r = 0.08 to 0.31). SAA and CRP also showed a moderate correlation with fibrinogen (r = 0.44 and 0.34, respectively).
Regression Results
Results for the regression of different blood markers are summarized in Table 4 (logistic regression) and Table 5 (linear regression). Effect estimates are presented together with 95% confidence intervals (95% CI) based on an increase in air pollution concentration from the first to the third quartile (interquartile range).
Inflammation and adhesion.
For CRP, the odds of observing concentrations above the 90th percentile were consistently increased in association with PM10 and UFPs (Figure 3) as well as AP, NO2, and CO for lag 2. The highest odds ratio (OR) was seen with AP, whereas EC and OC showed no significant results.
The OR for observing high ICAM-1 levels increased, especially for lag 1 and 2. This pattern was seen for PM10 (Figure 3), AP, EC and OC, and CO. For ICAM-1, a decrease with lag 0 was also found for most pollutants. Results for SAA indicate an increase in association with particulate air pollution (e.g., with UFP concentrations); however, results are not as strong and consistent as for CRP (Figure 3). Linear regression analyses looking at the continuous distribution did not reveal significant results for CRP, ICAM-1, and SAA. Also, E-selectin did not show any association with ambient air pollution (Figure 3).
Linear regression analyses of vWf (Table 5) revealed statistically significant positive associations for most pollutants with lag 0 and for the 5-d average exposure (Figure 3). For PM2.5 and AP, the effect was limited to the 5-d average exposure. Associations for the 1-d lag were found to be even stronger than for lag 0; however, this was not consistent throughout all pollutants.
Blood coagulation.
In linear regression, a consistent decrease in the mean of percentage of activity was found with FVII for almost all pollutants for the 5-d average exposure, indicating a cumulative effect (Figure 3). With the exception of PM2.5 and NO2, this decrease was also consistently found for lag 2.
Logistic regression results for FVII were in agreement with the results of the linear regression.
For prothrombin fragment 1+2, the logistic regression revealed constant increases of the OR, with lag 4 showing a consistent pattern in all measured pollutants (data not shown). Fibrinogen only revealed very few significant effects, which might be due to chance. Analyses of D-dimer revealed a null result in linear as well as in logistic models (Figure 3).
Sensitivity analyses.
Thorough sensitivity analyses were conducted for the logistic regression models comparing different models with varying number of confounder variables.
For CRP, adding temperature, relative humidity, and air pressure resulted in higher AIC values. In these models, the results for the two-lagged effect of UFPs and AP were confirmed; however, these had generally wider confidence intervals. For prothrombin fragment 1+2, the AIC was reduced by adding air pressure to the model. However, estimates were up to twofold higher and results for the AP destabilized. Therefore, the more conservative and more stable model was used. Throughout all models, stable results were found for lag 2 with the UFPs and with lag 4 for AP, PM10, PM2.5, EC, and OC. The results for ICAM-1 also remained stable throughout all models. Moreover, we conducted sensitivity analyses comparing the results for those patients who were on lipid-lowering drugs, primarily statins, with those who were not. Results for the linear regression show that the effects were mainly driven by the patients who were not on lipid-lowering medication. The effects were larger than the overall effects but had wide confidence intervals due to reduced power. Stratified analyses for CRP showed stronger effects in the patients taking statins.
We compared the results of a random-effects model with those of the fixed-effects model for the linear regression, showing consistent effect estimates (FVII, AP, 5-d average exposure: OR, –4.3; 95% CI, –8.1, –0.5). Some associations were found to have a nonlinear exposure response function as marked in Tables 4 and 5. Nonlinearity weakens the evidence for a strong influence of these pollutants; however, for the CRP, all associations were linear (Table 4).
DISCUSSION
Summary
Our findings suggest increases in CRP and ICAM-1 in association with ambient air particles. For these markers, the effects were limited to the higher values of the parameters, showing an increase in the odds of observing high levels of the respective parameters with elevated levels of air pollution. CRP rose with a delay of 2 d for all measured pollutants except for EC and OC. For ICAM-1, a 1- and 2-d delayed increase was associated with most pollutants.
Mean concentrations of vWf were shifted toward higher values revealing the strongest effect for the 5-d average exposure to almost all pollutants. Moreover, a rise in prothrombin fragment 1+2 in association with all pollutants was seen, which was consistent for lag 4. For FVII, clear and consistent negative associations were observed.
UFPs, NO2, and CO were measured simultaneously and therefore allow a rough estimate on how well the two gases can be used as surrogates for the exposure to combustion-derived particles. Our results show a high correlation among these three pollutants, and also the estimates for the blood markers show comparable results, especially in logistic regressions. Similar conclusions have been drawn by Cyrys and colleagues (26), who found UFPs, NO2, and CO to be strongly correlated and to reflect motor vehicle traffic.
Possible Mechanisms
This study was based on the following mechanistic hypotheses (Figure 1): Airway injury or activation of blood cells, such as monocytes, caused by particles deposited in the alveoli leads to a release of proinflammatory cytokines interleukin (IL)-6 and IL-8. Increased production of IL-6 and IL-8 activates mononuclear as well as endothelial cells, initiating the hepatic synthesis of acute-phase proteins, such as CRP and SAA, and an up-regulation of the expression of adhesion molecules as markers of endothelial dysfunction. An enhanced acute-phase response as well as endothelial cell activation increase procoagulant activity, indicated by a rise in coagulation proteins or evidence of activation of the clotting cascade (27). These changes in blood parameters, together with plaque instability, may ultimately lead to a coronary event in susceptible patients.
Inflammatory Pathway
Regarding CRP, Seaton and coworkers (28) observed a positive association between exposure to ambient PM10 and CRP concentrations in elderly subjects in the United Kingdom. For CRP, our findings are in accordance with those of Seaton and colleagues and are also consistent with those previously reported from Augsburg, Germany (17). Increased concentrations of CRP are known to predict cardiovascular events in healthy subjects (29). Also, elevated levels of IL-6 have been found to be associated with total mortality (30) and with risk of future fatal and nonfatal MI (31). PM10 is suggested to affect the upper bronchi and therefore lead to an inflammation in the lung, whereas the smaller particles potentially transfer into the blood and start a systemic inflammatory response. Our data indicate a systemic delayed response to air pollution. According to Geiser (32), particles are rapidly translocated into the blood. It is therefore possible that the delay we observed is due to the time needed to initiate the acute-phase response after a rapid UFP translocation. With a half-life of 19 h (33), CRP is down-regulated rapidly and therefore does not show any elevation 3 to 4 d after an increase in air pollution.
Endothelial Dysfunction
Adhesion molecules, such as ICAM-1, mediate the contact between circulating leukocytes and endothelial cells. ICAM-1 induces a tight binding of leukocytes to the endothelium. In this way, leukocytes can leave the blood stream and enter the subendothelial space (34–37). ICAM-1 has been shown to predict acute coronary events as well as angina pectoris in a prospective cohort of apparently healthy men (38). Also, an increase in ICAM-1 in association with diesel exhaust was shown in bronchial biopsies in a panel of 15 human volunteers (39). Moreover, particles collected in Provo, Utah (40), enhanced the expression of ICAM-1 in primary cultures of human epithelium. Our data are in accordance with the literature indicating an up-regulation in ICAM-1 expression primarily with lag 1 and 2.
In addition, vWf may serve as a marker of endothelial dysfunction. In healthy mice, increased vWf expression on hepatic endothelium was detected after application of UFPs (41). vWf reflects endothelial cell release and probably vascular reactivity. Vascular reactivity could be secondary to inflammation, and because vWf can mediate platelet adhesion to damaged endothelium, this could be a predictor of coronary events (34, 42).
Coagulation Pathway
In contrast to our initial hypothesis, the various clotting factor levels showed no consistent pattern in association with air pollution.
FVII, one of the key enzymes of the extrinsic system of the coagulation cascade, is activated by tissue factor. Complexes of tissue factor with factor VIIa are central to the activation of factor X and to the formation of thrombin, which mediates the conversion of fibrinogen to fibrin (43). Results for FVII in the literature are inconsistent (28, 44). In our study, FVII activity decreased significantly in association with most pollutants.
Regarding fibrinogen levels, we did not find any consistent results in association with air pollution. Controlled human exposure studies (45, 46) as well as epidemiologic studies (47, 48) demonstrated positive associations between fibrinogen or plasma viscosity and air pollution. However, decreases in fibrinogen levels also have been reported and the significance of these results is unknown (28, 41).
Prothrombin fragment 1+2 is cleaved from prothrombin when it is activated to thrombin by factor Xa, thereby representing a marker of activation of the coagulation pathway (34, 49, 50). Our data indicate an increased concentration in association with ambient air pollutants. This significant increase indicates that an early step of blood coagulation has been activated. However, this activation was not associated with increased formation of fibrin, as would be detected by elevated D-dimer levels. The elevated levels of prothrombin fragment 1+2 are an important finding that shows that air pollution not only induces inflammation but also coagulation.
The large number of blood markers measured in this study revealed inconsistencies that were already observed in previous studies (13). One possible explanation is that various particle fractions or components differ in their effects. CRP, for example, did not show any association with EC and OC, whereas other blood markers showed quite strong effects. Moreover, diverse time patterns in the reaction to air pollution, due to the differing biological mechanisms, are conceivable and were also seen in the data.
While the results for inflammation and air pollution seem consistent, inhomogeneity exists in terms of coagulation markers. Our data strongly indicate that the pathway that links airway injury from air pollution and coronary events may include increased expression of adhesion molecules and a proinflammatory response. Furthermore, the coagulation system (prothrombin fragment 1+2) is activated, although not sufficiently enough to cause increased fibrin formation, as would have been reflected by elevated D-dimer levels. We do not have an explanation for the decreased concentrations of fibrinogen and FVII, but, whatever the cause, they may act to protect against clinical events secondary to coronary thrombosis. Our study represents measurements of background levels of blood markers and does not reflect changes that might relate to acute clinical events.
Strengths and Limitations
A strength of this study is the achievement of 99% of all scheduled visits. Moreover, a wide range of markers, reflecting different pathways, were measured within the same setting. All of the measured biomarkers may increase in response to a number of unspecific stimuli, such as infectious diseases or surgery. CRP is particularly sensitive and can increase a thousandfold within a short time in response to such triggers (34). Therefore, we excluded all blood samples that potentially might have been affected by sources other than air pollution. All patients were asked about infections and surgery in the 2 wk before the blood withdrawal. Reasons for physician visits as well as hospital admissions were recorded, and study nurses documented signs of an acute respiratory infection in the patient during regular clinic visits. None of the samples that revealed especially high or low levels of the respective biomarker were excluded unless a reason was known.
We used logistic regression analyses in addition to linear regression because Peters and colleagues (16) had suggested that effects of air pollution may be seen on a small number of subjects with high values of a particular marker with less effect on the mean level. Also, some parameters showed a few extreme outliers, which strongly influenced the regression results.
Although the fixed-effect models were adjusted for individual time-invariant factors, by design no adjustment for time-dependent individual-level variables was possible.
A variety of pollutants were used for the analyses, because different pollutants may point toward different properties of the aerosol, and also represent different sources of air pollution. However, by testing multiple blood parameters and a set of air pollutants, the possibility that some effects might have occurred by chance cannot be excluded. Because the air pollution parameters are closely correlated, we considered especially consistent patterns in the data as actual effects. Moreover, thorough confounder adjustment for meteorologic variables was done to rule out the possibility that the detected associations resulted from meteorologic influences or seasonal differences.
Only one central measurement site was used for the collection of ambient air pollution. However, the spatial representativeness of this site has been analyzed in detail previously by Cyrys and colleagues (51), who measured sulfate and PM10 levels simultaneously at three additional monitoring sites in the Erfurt area. The relatively high intersite correlation between the monitoring stations (0.69–0.98) indicates that regional episodes of sulfates and PM10 in Erfurt can be identified using one fixed monitoring site and that our site is generally representative for the urban background level of air pollution within Erfurt. Erfurt is a small city with one air mass confined by a mountain ridge on three sides and high rises on the fourth side. Because most of the participants of our panel were already retired, we assume that they spent the greater part of their day within the vicinity of their residence within the city of Erfurt.
Many studies have demonstrated that individual exposures to PM are poorly correlated spatially with ambient concentrations (52). Some longitudinal exposure assessment studies of PM and specific PM components with repeated measures have found higher correlations between personal exposures and ambient concentrations. Janssen and coworkers (53) showed, for example, that ambient, indoor, and personal concentrations of PM2.5 were highly correlated in two European cities.
However, the correlation many epidemiologists are interested in is not that between total personal exposure and outdoor concentrations but the correlation between that component of personal exposure that can be attributed to outdoor particles and the outdoor concentrations. Ebelt and colleagues (54) demonstrated that ambient concentrations and the contribution of ambient particles to personal PM exposure were highly correlated, with a Pearson correlation coefficient of 0.81 for PM2.5, of 0.71 for PM10 and of 0.73 for the coarse fraction (PM10 – PM2.5). Moreover, they show that ambient concentrations and exposure to nonambient PM2.5 are independent, which is an important assumption in epidemiologic studies that use ambient concentration as a surrogate for personal exposure. They conclude that their results give support to the use of ambient monitoring data in time series analyses. Cyrys and coworkers (55), who compared the relationship of indoor and outdoor levels of fine-particulate mass, particle number concentrations, and black smoke, concluded that ambient concentrations of PM2.5 and black smoke can be used as good approximations of indoor concentrations.
A limitation to the study is that the examined panel consisted of male patients only, with a history of CHD, who were all taking cardiac medication. Therefore, they represent a highly selected group and the study results might not be generalizable to other population groups, such as females with CHD or healthy subjects.
A differentiation between chronic and acute effects of higher levels of blood markers in the patients is not possible with this study design. Because of the short observation time, it is not clear whether these changes can lead to an onset or exacerbation of the disease. We observed short-term changes in various blood parameters; however, the implications for patients remain speculative. On the other hand, changes in blood markers due to air pollution have recently been observed not only in patients with CHD but also in young and healthy persons (56).
Conclusions
The study adds to the evidence that elevated levels of ambient air pollution may cause systemic inflammatory and coagulation responses. These changes in blood markers could represent additional risk factors, which, in susceptible individuals, such as patients with CHD, could increase the likelihood of serious arterial vascular thrombotic events on exposure to high levels of air pollutants.
Acknowledgments
The authors thank Dr. O. Manuwald and his team and the German Weather Service (DWD). The study is funded through the U.S. Environmental Protection Agency STAR Center grant R-827354 and the Focus-Network of Aerosols and Health, GSF. The Focus-Network of Aerosols and Health coordinates and focuses all GSF research on health effects and the characterization of aerosols. It comprises research projects of the Institutes of Ecological Chemistry, Epidemiology, Inhalation Biology, Radiation Protection, and Toxicology at GSF.
FOOTNOTES
Supported by the U.S. Environmental Protection Agency STAR center grant R-827354 and the Focus-Network of Aerosols and Health, GSF.
Originally Published in Press as DOI: 10.1164/rccm.200507-1123OC on November 17, 2005
Conflict of Interest Statement: None of the authors have a financial relationship with a commercial entity that has an interest in the subject of this manuscript.
REFERENCES
Schwartz J, Marcus A. Mortality and air pollution in London: a time series analysis. Am J Epidemiol 1990;131:185–194.
Peters A, Skorkovsky J, Kotesovec F, Brynda J, Spix C, Wichmann HE, Heinrich J. Associations between mortality and air pollution in Central Europe. Environ Health Perspect 2000;108:283–287.
Schwartz J, Dockery DW. Particulate air pollution and daily mortality in Steubenville, Ohio. Am J Epidemiol 1992;135:12–19.
Schwartz J. Particulate air pollution and daily mortality in Detroit. Environ Res 1991;56:204–213.
Schwartz J. Air pollution and daily mortality in Birmingham, Alabama. Am J Epidemiol 1993;137:1136–1147.
Forastiere F, Stafoggia M, Picciotto S, Bellander T, D'Ippoliti D, Lanki T, von Klot S, Nyberg F, Paatero P, Peters A, et al. A case-crossover analysis of out-of-hospital coronary deaths and air pollution in Rome, Italy. Am J Respir Crit Care Med 2005;172:1549–1555.
Burnett RT, Dales RE, Brook JR, Raizenne ME, Krewski D. Association between ambient carbon monoxide levels and hospitalizations for congestive heart failure in the elderly in 10 Canadian cities. Epidemiology 1997;8:162–167.
Schwartz J. Air pollution and hospital admissions for cardiovascular disease in Tucson. Epidemiology 1997;8:371–377.
Schwartz J. Air pollution and hospital admissions for heart disease in eight US counties. Epidemiology 1999;10:17–22.
Peters A, Dockery DW, Muller JE, Mittleman MA. Increased particulate air pollution and the triggering of myocardial infarction. Circulation 2001;103:2810–2815.
de Hartog JJ, Hoek G, Peters A, Timonen KL, Ibald-Mulli A, Brunekreef B, Heinrich J, Tiittanen P, van Wijnen JH, Kreyling W, et al. Effects of fine and ultrafine particles on cardiorespiratory symptoms in elderly subjects with coronary heart disease: the ULTRA study. Am J Epidemiol 2003;157:613–623.
Brook R, Franklin B, Cascio WE, Hong Y, Howard G, Lipsett M, Luepker R, Mittleman MA, Samet J, Smith S, et al. Air pollution and cardiovascular disease: a statement for healthcare professionals from the Expert Panel on Population and Prevention Science of the American Heart Association. Circulation 2004;109:2655–2671.
Seaton A, MacNee W, Donaldson K, Godden D. Particulate air pollution and acute health effects. Lancet 1995;345:176–178.
DeMeo DL, Zanobetti A, Litonjua AA, Coull BA, Schwartz J, Gold DR. Ambient air pollution and oxygen saturation. Am J Respir Crit Care Med 2004;170:383–387.
Pope CA, Burnett RT, Thurston GD, Thun MJ, Calle EE, Krewski D, Godleski JJ. Cardiovascular mortality and long-term exposure to particulate air pollution: epidemiological evidence of general pathophysiological pathways of disease. Circulation 2004;109:71–77.
Peters A, Dring A, Wichmann HE, Koenig W. Increased plasma viscosity during air pollution episode: a link to mortality Lancet 1997;349:1582–1587.
Peters A, Frohlich M, Doring A, Immervoll T, Wichmann HE, Hutchinson WL, Pepys MB, Koenig W. Particulate air pollution is associated with an acute phase response in men: results from the MONICA-Augsburg study. Eur Heart J 2001;22:1198–1204.
Rückerl R, Ibald-Mulli A, Koenig W, Henneberger A, Woelke G, Cyrys J, Wichmann H-E, Peters A. Ambient air pollution and systemic inflammatory responses in patients with coronary heart disease. Eur Respir J 2004;24:237.
Kreyling WG, Tuch T, Peters A, Pitz M, Heinrich J, Stolzel M, Cyrys J, Heyder J, Wichmann HE. Diverging long-term trends in ambient urban particle mass and number concentrations associated with emission changes caused by the German unification. Atmos Environ 2003;37:3841–3848.
Ibald-Mulli A. Effects of particulate air pollution on blood pressure and heart rate in subjects with cardiovascular disease: results from the ULTRA study. 2003.
Wichmann HE, Spix C, Tuch T, Woelke G, Peters A, Heinrich J, Kreyling WG, Heyder J. Daily mortality and fine and ultrafine particles in Erfurt, Germany: part I: role of particle number and particle mass. Res Rep Health Eff Inst 2000;98:5–86.
Tuch T, Mirme A, Tamm E, Heinrich J, Heyder J, Brand P, Roth C, Wichmann HE, Pekkanen J, Kreyling WG. Comparison of two particle-size spectrometers for ambient aerosol measurements in environmental epidemiology. Atmos Environ 2000;34:139–149.
Kreyling WG, Tuch T, Peters A, Pitz M, Heinrich J, Stolzel M, Cyrys J, Heyder J, Wichmann HE. Diverging long-term trends in ambient urban particle mass and number concentrations associated with emission changes caused by the German unification. Atmos Environ 2003;37:3841–3848.
Brand P, Gerhardt J, Below M, Georgi B, Heyder J. Technical note: performance of a mobile aerosol spectrometer for an in situ characterisation of environmental aerosols in Frankfurt city. Atmos Environ 1992;26:2451–2457.
Tuch T, Brand P, Wichmann HE, Heyder J. Variation of particle number and mass concentration in various size ranges of ambient aerosols in Eastern Germany. Atmos Environ 1997;31:4193–4197.
Cyrys J, Stolzel M, Heinrich J, Kreyling WG, Menzel N, Wittmaack K, Tuch T, Wichmann HE. Elemental composition and sources of fine and ultrafine ambient particles in Erfurt, Germany. Sci Total Environ 2003;305:143–156.
Utell MJ, Frampton MW. Acute health effects of ambient air pollution: the ultrafine particle hypothesis. J Aerosol Med 2000;13:355–359.
Seaton A, Soutar A, Crawford V, Elton R, McNerlan S, Cherrie J, Watt M, Agius R, Stout R. Particulate air pollution and the blood. Thorax 1999;54:1027–1032.
Danesh J, Whincup P, Walker M, Lennon L, Thomson A, Appleby P, Gallimore JR, Pepys MB. Low grade inflammation and coronary heart disease: prospective study and updated meta-analyses. BMJ 2000;321:199–204.
Harris TB, Ferrucci L, Tracy RP, Corti MC, Wacholder S, Ettinger WH Jr, Heimovitz H, Cohen HJ, Wallace R. Associations of elevated interleukin-6 and C-reactive protein levels with mortality in the elderly. Am J Med 1999;106:506–512.
Ridker PM, Rifai N, Stampfer MJ, Hennekens CH. Plasma concentration of interleukin-6 and the risk of future myocardial infarction among apparently healthy men. Circulation 2000;101:1767–1772.
Geiser M. Morphological aspects of particle uptake by lung phagocytes. Microsc Res Tech 2002;57:512–522.
Koenig W, Sund M, Frohlich M, Lowel H, Hutchinson WL, Pepys MB. Refinement of the association of serum C-reactive protein concentration and coronary heart disease risk by correction for within-subject variation over time. Am J Epidemiol 2003;158:357–364.
Thomas L. Labor und diagnose. Frankfurt a. Main, Germany: TH-Books Verlagsgesellschaft; 1998.
Rubin E, Farber JL. Pathology. Philadelphia: J.B. Lippincott; 1998.
von Andrian UH, Mackay CR. Advances in immunology: T-cell function and migration: two sides of the same coin. N Engl J Med 2000;343:1020–1033.
Luster AD. Chemokines: chemotactic cytokines that mediate inflammation. N Engl J Med 1998;338:436–445.
Luc G, Arveiler D, Evans A, Amouyel P, Ferrieres J, Bard JM, Elkhalil L, Fruchart JC, Ducimetiere P. Circulating soluble adhesion molecules ICAM-1 and VCAM-1 and incident coronary heart disease: the PRIME Study. Atherosclerosis 2003;170:169–176.
Salvi S, Blomberg A, Rudell B, Kelly F, Sandstrom T, Holgate ST, Frew A. Acute inflammatory responses in the airways and peripheral blood after short-term exposure to diesel exhaust in healthy human volunteers. Am J Respir Crit Care Med 1999;159:702–709.
Kennedy T, Ghio AJ, Reed W, Samet J, Zagorski J, Quay J, Carter J, Dailey L, Hoidal JR, Devlin RB. Copper-dependent inflammation and nuclear factor-kappaB activation by particulate air pollution. Am J Respir Cell Mol Biol 1998;19:366–378.
Khandoga A, Stampfl A, Takenaka S, Schulz H, Radykewicz R, Kreyling W, Krombach F. Ultrafine particles exert prothrombotic but not inflammatory effects on the hepatic microcirculation in healthy mice in vivo. Circulation 2004;109:1320–1325.
Gardiner E, Andrews R, Shen Y, Berndt M. Platelet interactions in thrombosis. IUBMB Life 2004;56:13–18.
Marder V, Rosove M, Minning D. Foundation and sites of action of antithrombotic agents. Best Pract Res Clin Haematol 2004;17:3–22.
Pekkanen J, Brunner EJ, Anderson HR, Tiittanen P, Atkinson RW. Daily concentrations of air pollution and plasma fibrinogen in London. Occup Environ Med 2000;57:818–822.
Huang YC, Ghio AJ, Stonehuerner J, McGee J, Carter JD, Grambow SC, Devlin RB. The role of soluble components in ambient fine particles-induced changes in human lungs and blood. Inhal Toxicol 2003;15:327–342.
Ghio AJ, Kim C, Devlin RB. Concentrated ambient air particles induce mild pulmonary inflammation in healthy human volunteers. Am J Respir Crit Care Med 2000;162:981–988.
Schwartz J. Air pollution and blood markers of cardiovascular risk. Environ Health Perspect 2001;109:405–409.
Pekkanen J, Brunner EJ, Anderson HR, Tiittanen P, Atkinson RW. Daily concentrations of air pollution and plasma fibrinogen in London. Occup Environ Med 2000;57:818–822.
Bauer K, Barzegar S, Rosenberg R. Influence of anticoagulants used for blood collection on plasma prothrombin fragment F1+2 measurements. Thromb Res 1991;63:617–628.
Rybak M, Lau H, Tomkins B, Rosenberg R, Handin R. Relationship between platelet secretion and prothrombin cleavage in native whole blood. J Clin Invest 1981;68:405–412.
Cyrys J, Heinrich J, Brauer M, Wichmann HE. Spatial variability of acidic aerosols, sulfate and PM10 in Erfurt, Eastern Germany. J Expo Anal Environ Epidemiol 1998;8:447–464.
U.S. Environmental Protection Agency. Air quality criteria for particulate matter. Research Triangle Park, NC: National Center for Environmental Assessment-RTP Office; 1996. Publication No. EPA/600/P-95/001aF-cF.3v.
Janssen NAH, Hoek G, Brunekreef B, Harssema H, Mensink I, Zuidhoh A. Personal sampling of particles in adults: relation among personal, indoor, and outdoor air concentrations. Am J Epidemiol 1998;147:537–547.
Ebelt ST, Wilson WE, Brauer M. Exposure to ambient and nonambient components of particulate matter: a comparison of health effects. Epidemiology 2005;16:396–405.
Cyrys J, Pitz M, Bischof W, Wichmann HE, Heinrich J. Relationship between indoor and outdoor levels of fine particle mass, particle number concentrations and black smoke under different ventilation conditions. J Expo Anal Environ Epidemiol 2004;14:275–283.
Riediker M, Cascio WE, Griggs TR, Herbst MC, Bromberg PA, Neas L, Williams RW, Devlin RB. Particulate matter exposure in cars is associated with cardiovascular effects in healthy young men. Am J Respir Crit Care Med 2004;169:934–940.(Regina Rückerl, Angela Ibald-Mulli, Wolf)
IBE Department of Epidemiology, Ludwig-Maximilians-University of Munich, Munich
Department of Internal Medicine II, Cardiology, University of Ulm Medical Center, Ulm, Germany
Department of Medicine and Dentistry, Vascular Medicine, and Pulmonary and Critical Care Unit, Rochester School of Medicine and Dentistry, Rochester, New York
ABSTRACT
Rationale: Ambient air pollution has been shown to be associated with cardiovascular morbidity and mortality.
Objectives: A prospective panel study was conducted to study the early physiologic reactions characterized by blood biomarkers of inflammation, endothelial dysfunction, and coagulation in response to daily changes in air pollution in Erfurt, Germany.
Methods: Blood parameters were repeatedly measured in 57 male patients with coronary heart disease during the winter of 2000/2001. Fixed-effects linear and logistic regression models were applied, adjusting for trend, weekday, and meteorologic parameters.
Measurements: Hourly data on ultrafine particles (UFPs; number concentration of particles from 0.01 to 0.1 μm), mass concentration of particles less than 10 (PM10) and 2.5 μm in diameter, elemental and organic carbon, gaseous pollutants, and meteorologic data were collected at central monitoring sites.
Main Results: Increased levels of C-reactive protein above the 90th percentile were observed for an increase in air pollution concentrations of one interquartile range. The effect was strongest for accumulation mode particles, with a delay of 2 d (odds ratio [OR], 3.2; confidence interval [CI], 1.7, 6.0). Results were consistent for UFPs and PM10, which also showed a 2-d delayed response (OR, 2.3; CI, 1.3, 3.8; and OR, 2.2; CI, 1.2, 3.8, respectively). However, not all of the blood markers of endothelial dysfunction and coagulation increased consistently in association with air pollutants.
Conclusion: These results suggest that inflammation as well as parts of the coagulation pathway may contribute to the association between particulate air pollution and coronary events.
Key Words: acute-phase reaction air pollution blood coagulation cardiovascular diseases C-reactive protein
Increasing evidence suggests that ambient air pollution may adversely affect the cardiovascular system. It has been shown that ambient air pollution leads to increased cardiovascular mortality (1–6), and studies found associations between ambient air pollution and hospital admissions for various cardiovascular diseases, including congestive heart failure (7–9). Also, an increased risk for acute myocardial infarction (MI) (10) and cardiorespiratory symptoms (11) has been reported in association with particulate air pollution.
The exact mechanisms linking the inhalation of ambient air particles to an acute exacerbation of cardiovascular disease are not completely understood (12). Seaton and coworkers (13) hypothesized that inhaled particles would lead to alveolar inflammation, which increases the level of blood coagulability, thus leading to an increased risk of ischemic events in susceptible individuals. DeMeo and colleagues (14) found reduced oxygen saturation in association with particulate matter of less than 2.5 μm in diameter (PM2.5). Pope and colleagues (15), who linked long-term exposure to particulate air pollution to various causes of mortality, found a strong and robust association between PM2.5 and cardiovascular disease mortality. They concluded that exposure to particulate air pollution and cardiopulmonary mortality risk is linked by accelerated pulmonary and systemic inflammation. Moreover, Peters and coworkers (16) demonstrated increased levels of plasma viscosity during an air pollution episode in central Europe, compared with less polluted days. Increased plasma concentrations of C-reactive protein (CRP), the classic acute-phase protein, were also shown during the 1985 air pollution episode (17).
There is a strong link between inflammation and coronary heart disease (CHD) because factors involved in inflammation and infection seem to play a proatherogenic role and inflammation has been identified as a potent risk factor for acute coronary syndrome. Systemic inflammation could result in destabilization or even rupture of vulnerable atheromatous plaques, leading to acute ischemic events.
Most of the cited studies have been conducted in the general population or in elderly healthy subjects. This study looks at a susceptible subgroup to provide insight into the ways in which air pollution might precipitate death in persons with underlying heart disease, based on the hypothesis that particulate air pollution can alter cardiovascular function.
Repeated measurements of markers of an early inflammatory response, cell recruitment and coagulation, were compared with concurrent levels of air pollution. Our primary hypothesis was that CRP, a well-known marker for inflammation, would increase in association with a rise in levels of air pollution. Moreover, we analyzed various other markers of inflammation (serum amyloid A [SAA]), cell adhesion (E-selectin, von Willebrand factor antigen [vWf], intercellular adhesion molecule 1 [ICAM-1]), and coagulation (fibrinogen, factor VII [FVII], prothrombin fragment 1+2, D-dimer) on a more explorative basis hypothesizing that the levels of these blood markers would also go up in association with higher levels of air pollution, as seen in Figure 1. Some results have been previously presented in form of an abstract (18).
METHODS
Study Design
As part of the University of Rochester Particulate Matter Center, a prospective panel study was conducted between October 15, 2000, and April 27, 2001, in Erfurt, Germany. The panel consisted of male patients with CHD who were scheduled for 12 subsequent clinical visits. Each clinical visit included a short interview and the withdrawal of a blood sample. At the first visit, a baseline questionnaire was administered regarding health status, pulmonary and cardiac symptoms, medication intake, and smoking history.
Sixty-one nonsmoking men, aged 50 yr or older, with physician-diagnosed CHD were recruited through a local cardiologist. Patients with pacemakers, recent (< 3 mo ago) MI, bypass surgery, or balloon dilatation were not included because the inflammatory processes involved in such a procedure might not yet have subsided. Persons with type 1 diabetes or on anticoagulation therapy (except for antiplatelet agents) were also not included. A written, informed consent was obtained from all subjects. The study protocol was approved by the German Ethics Committee of the "Bayerische Landesrztekammer" in Munich, Germany. All methods used in the study were conducted according to standard operating procedures and were tested beforehand in a 2-wk pilot study.
Air Pollution Monitoring
Concentrations of different ambient air pollutants were measured at one fixed monitoring site in the city center representing urban background levels. The measurement site was put up especially for carrying out epidemiologic studies (19, 20) and all measurements were conducted according to the standard operating procedures developed within the framework of previous studies (21–23).
Continuous ultrafine particle (UFP) counts (0.01–0.1 μm), accumulation mode particle (AP) counts (0.1–1.0 μm), and fine-particle mass (PM2.5) were measured with the mobile aerosol spectrometer (MAS). The MAS, described previously (24, 25), consists of two different, commercially available instruments covering different size ranges. Particles in the size range from 0.01 to 0.5 μm were measured using a differential mobility particle sizer (TSI, Aachen, Germany). Particles in the size range from 0.1 to 2.5 μm were classified by an optical laser aerosol spectrometer (PMS, Leonberg, Germany).
PM10 (particulate matter < 10 μm in diameter) data were collected by the tapered element oscillating microbalance method (TEOM 1400a; Rupprecht and Patashnik, Albany, NY) and continuous data on elemental (EC) and organic carbon (OC) were measured with an ambient carbon monitor (ACM 5400; Rupprecht and Patashnick). Data on meteorologic variables for this period as well as concentrations of gaseous air pollutants were collected from existing networks. Missing values of the ambient UFPs between January 20 and February 13 were imputed by a linear regression model based on parallel measurements with a condensation particle counter and a scanning mobility particle sizer. The R squares for the regression model was 0.96. Also, between December 2000 and May 2001, approximately 15% of the PM2.5 measurements by MAS were lost. These missing values were replaced by corrected data based on parallel measurements with TEOM-PM10 and Harvard Impactor-PM2.5. (Air Diagnostic and Engineering, Inc., Naples, ME).
For each person and visit, the individual 24-h average of pollutants immediately preceding the clinical visit (lag 0) up to Day 5 (lag 1–4) and 5-d running means before the examination were calculated if more than two-thirds of the hourly measurements were available for this period.
Clinical Measurements
The clinical visits were scheduled on the same weekday (Monday to Friday) and time (8:00 A.M. to 5:00 P.M.) for each patient once every 2 wk.
At each visit, ethylenediaminetetraacetic acid and citrate plasma samples were drawn (Becton Dickinson, Franklin Lakes, NJ). Samples were centrifuged and aliquots were immediately stored at –20°C until analysis. CRP (high-sensitivity assay), SAA, and fibrinogen were analyzed by immunonephelometry (Dade Behring, Marburg, Germany). ICAM-1, E-selectin (R&D Systems, Wiesbaden, Germany), and prothrombin fragment 1+2 (Dade Behring) were measured by means of a commercial ELISA. D-dimer and vWf were analyzed using an immunoturbidimetric method and FVII by clotting time measurement (Diagnostica Stago, Asnieres-sur-Seine, France).
Study Subjects
Fifty-seven of 61 patients were included in the analyses. One patient refused to participate, and three patients had to be excluded for the following reasons: two were diagnosed with leukemia or lymphoma and one patient had constantly elevated levels of white and red blood cells, indicating an unknown hematologic disorder. Fifty-five patients participated in 12, one patient participated in nine, and one patient participated in eight scheduled visits (99% completeness). Blood samples of patients reporting an acute infection and/or surgery during the 2 wk before the examination were excluded from the analysis (46 blood samples [7%] of 19 different patients). Also, 18 blood samples (3%) in 15 patients showing implausibly low fibrinogen values (< 1.0 g/L) on nephelometry were excluded from the analysis. Finally, not all patients were able to give the scheduled amount of blood at each visit. Therefore, between 544 blood samples (87%) and 581 blood samples (92%) remained for analysis, depending on the marker.
Statistical Analyses
Continuous concentrations of the blood markers were analyzed using linear regression models. Also, values above the 90th percentile were assessed using logistic regression models (17). Generalized additive models, including pollutant and confounder variables, were used for fixed-effects regression with individual intercepts for each patient. Long-term time trend, an indicator variable for each subject, weekday of the visit, and the meteorologic parameters air temperature, relative humidity, and barometric pressure, each with lag 0 to lag 3, were considered as potential confounders. Because the half-life of most markers is only a couple of hours and the visits took place in 2-wk intervals, it was assumed that no autocorrelation was present in the patient data, and no adjustment for autocorrelation was made.
Prothrombin fragment 1+2, FVII, SAA, CRP, and E-selectin were log-transformed before analysis because their residuals remained skewed after multivariate modeling.
Model building was done for each blood parameter separately without an air pollution variable. To explore the shape of the association between confounders and blood markers, nonparametric smooth functions on the basis of locally weighted least squares were applied for all confounders. Model fit was rated on the basis of the Akaike information criterion (AIC). In the final model, nonparametric smooth functions were replaced by appropriate polynomials (degree 2 or 3) or natural splines based on lowest AIC. After the model fit was completed, dose–response functions of the confounders were checked visually and in case implausible shapes were observed, degrees of freedom were decreased. Each pollutant was added separately to the final model.
Data were analyzed using the statistical package SAS version 8.2 (SAS Institute, Inc., Cary, NC) and S-Plus version 6.0 (Mathsoft Engineering and Education, Inc., Cambridge, MA).
Logistic regression models were used to determine whether the effect was limited to the upper tail of the distribution. Confounder adjustment was done in the same way as described for the linear regression models; however, more parsimonious models were used. Sensitivity analyses were done to explore the influences of the different confounder models.
RESULTS
Patient Characteristics
Patient characteristics are summarized in Table 1. The study population comprised 57 nonsmoking men, aged 51 to 76 yr. Approximately 84% of them were retired. Except for one person, all patients had stopped smoking at least 1 yr before the examinations.
Air Pollutants
The distributions of the 24-h average concentrations of the particulate and gaseous pollutants as well as meteorologic data are given in Table 2.
PM10, PM2.5, and AP were highly correlated (r = 0.90–0.91), whereas UFPs were only moderately correlated with PM10 and PM2.5 (r = 0.57 and 0.41, respectively). PM2.5 showed a moderate negative correlation with air temperature (r = –0.5; Figure 2). EC and OC showed high correlation (r = 0.96) and were also highly correlated with all other particle fractions (r = 0.63–0.90). Also, CO and NO2 were highly correlated (r = 0.82), whereas the correlation for UFPs with NO2 was slightly lower than with CO (r = 0.75 and 0.82, respectively).
Blood Parameters
Levels of blood parameters are summarized in Table 3. Parameters of the acute-phase response, SAA and CRP, were correlated (r = 0.53), as were the adhesion molecules ICAM-1 and E-selectin (r = 0.53). However, no significant correlation was seen between markers of an acute-phase response and adhesion molecules (r = 0.08 to 0.31). SAA and CRP also showed a moderate correlation with fibrinogen (r = 0.44 and 0.34, respectively).
Regression Results
Results for the regression of different blood markers are summarized in Table 4 (logistic regression) and Table 5 (linear regression). Effect estimates are presented together with 95% confidence intervals (95% CI) based on an increase in air pollution concentration from the first to the third quartile (interquartile range).
Inflammation and adhesion.
For CRP, the odds of observing concentrations above the 90th percentile were consistently increased in association with PM10 and UFPs (Figure 3) as well as AP, NO2, and CO for lag 2. The highest odds ratio (OR) was seen with AP, whereas EC and OC showed no significant results.
The OR for observing high ICAM-1 levels increased, especially for lag 1 and 2. This pattern was seen for PM10 (Figure 3), AP, EC and OC, and CO. For ICAM-1, a decrease with lag 0 was also found for most pollutants. Results for SAA indicate an increase in association with particulate air pollution (e.g., with UFP concentrations); however, results are not as strong and consistent as for CRP (Figure 3). Linear regression analyses looking at the continuous distribution did not reveal significant results for CRP, ICAM-1, and SAA. Also, E-selectin did not show any association with ambient air pollution (Figure 3).
Linear regression analyses of vWf (Table 5) revealed statistically significant positive associations for most pollutants with lag 0 and for the 5-d average exposure (Figure 3). For PM2.5 and AP, the effect was limited to the 5-d average exposure. Associations for the 1-d lag were found to be even stronger than for lag 0; however, this was not consistent throughout all pollutants.
Blood coagulation.
In linear regression, a consistent decrease in the mean of percentage of activity was found with FVII for almost all pollutants for the 5-d average exposure, indicating a cumulative effect (Figure 3). With the exception of PM2.5 and NO2, this decrease was also consistently found for lag 2.
Logistic regression results for FVII were in agreement with the results of the linear regression.
For prothrombin fragment 1+2, the logistic regression revealed constant increases of the OR, with lag 4 showing a consistent pattern in all measured pollutants (data not shown). Fibrinogen only revealed very few significant effects, which might be due to chance. Analyses of D-dimer revealed a null result in linear as well as in logistic models (Figure 3).
Sensitivity analyses.
Thorough sensitivity analyses were conducted for the logistic regression models comparing different models with varying number of confounder variables.
For CRP, adding temperature, relative humidity, and air pressure resulted in higher AIC values. In these models, the results for the two-lagged effect of UFPs and AP were confirmed; however, these had generally wider confidence intervals. For prothrombin fragment 1+2, the AIC was reduced by adding air pressure to the model. However, estimates were up to twofold higher and results for the AP destabilized. Therefore, the more conservative and more stable model was used. Throughout all models, stable results were found for lag 2 with the UFPs and with lag 4 for AP, PM10, PM2.5, EC, and OC. The results for ICAM-1 also remained stable throughout all models. Moreover, we conducted sensitivity analyses comparing the results for those patients who were on lipid-lowering drugs, primarily statins, with those who were not. Results for the linear regression show that the effects were mainly driven by the patients who were not on lipid-lowering medication. The effects were larger than the overall effects but had wide confidence intervals due to reduced power. Stratified analyses for CRP showed stronger effects in the patients taking statins.
We compared the results of a random-effects model with those of the fixed-effects model for the linear regression, showing consistent effect estimates (FVII, AP, 5-d average exposure: OR, –4.3; 95% CI, –8.1, –0.5). Some associations were found to have a nonlinear exposure response function as marked in Tables 4 and 5. Nonlinearity weakens the evidence for a strong influence of these pollutants; however, for the CRP, all associations were linear (Table 4).
DISCUSSION
Summary
Our findings suggest increases in CRP and ICAM-1 in association with ambient air particles. For these markers, the effects were limited to the higher values of the parameters, showing an increase in the odds of observing high levels of the respective parameters with elevated levels of air pollution. CRP rose with a delay of 2 d for all measured pollutants except for EC and OC. For ICAM-1, a 1- and 2-d delayed increase was associated with most pollutants.
Mean concentrations of vWf were shifted toward higher values revealing the strongest effect for the 5-d average exposure to almost all pollutants. Moreover, a rise in prothrombin fragment 1+2 in association with all pollutants was seen, which was consistent for lag 4. For FVII, clear and consistent negative associations were observed.
UFPs, NO2, and CO were measured simultaneously and therefore allow a rough estimate on how well the two gases can be used as surrogates for the exposure to combustion-derived particles. Our results show a high correlation among these three pollutants, and also the estimates for the blood markers show comparable results, especially in logistic regressions. Similar conclusions have been drawn by Cyrys and colleagues (26), who found UFPs, NO2, and CO to be strongly correlated and to reflect motor vehicle traffic.
Possible Mechanisms
This study was based on the following mechanistic hypotheses (Figure 1): Airway injury or activation of blood cells, such as monocytes, caused by particles deposited in the alveoli leads to a release of proinflammatory cytokines interleukin (IL)-6 and IL-8. Increased production of IL-6 and IL-8 activates mononuclear as well as endothelial cells, initiating the hepatic synthesis of acute-phase proteins, such as CRP and SAA, and an up-regulation of the expression of adhesion molecules as markers of endothelial dysfunction. An enhanced acute-phase response as well as endothelial cell activation increase procoagulant activity, indicated by a rise in coagulation proteins or evidence of activation of the clotting cascade (27). These changes in blood parameters, together with plaque instability, may ultimately lead to a coronary event in susceptible patients.
Inflammatory Pathway
Regarding CRP, Seaton and coworkers (28) observed a positive association between exposure to ambient PM10 and CRP concentrations in elderly subjects in the United Kingdom. For CRP, our findings are in accordance with those of Seaton and colleagues and are also consistent with those previously reported from Augsburg, Germany (17). Increased concentrations of CRP are known to predict cardiovascular events in healthy subjects (29). Also, elevated levels of IL-6 have been found to be associated with total mortality (30) and with risk of future fatal and nonfatal MI (31). PM10 is suggested to affect the upper bronchi and therefore lead to an inflammation in the lung, whereas the smaller particles potentially transfer into the blood and start a systemic inflammatory response. Our data indicate a systemic delayed response to air pollution. According to Geiser (32), particles are rapidly translocated into the blood. It is therefore possible that the delay we observed is due to the time needed to initiate the acute-phase response after a rapid UFP translocation. With a half-life of 19 h (33), CRP is down-regulated rapidly and therefore does not show any elevation 3 to 4 d after an increase in air pollution.
Endothelial Dysfunction
Adhesion molecules, such as ICAM-1, mediate the contact between circulating leukocytes and endothelial cells. ICAM-1 induces a tight binding of leukocytes to the endothelium. In this way, leukocytes can leave the blood stream and enter the subendothelial space (34–37). ICAM-1 has been shown to predict acute coronary events as well as angina pectoris in a prospective cohort of apparently healthy men (38). Also, an increase in ICAM-1 in association with diesel exhaust was shown in bronchial biopsies in a panel of 15 human volunteers (39). Moreover, particles collected in Provo, Utah (40), enhanced the expression of ICAM-1 in primary cultures of human epithelium. Our data are in accordance with the literature indicating an up-regulation in ICAM-1 expression primarily with lag 1 and 2.
In addition, vWf may serve as a marker of endothelial dysfunction. In healthy mice, increased vWf expression on hepatic endothelium was detected after application of UFPs (41). vWf reflects endothelial cell release and probably vascular reactivity. Vascular reactivity could be secondary to inflammation, and because vWf can mediate platelet adhesion to damaged endothelium, this could be a predictor of coronary events (34, 42).
Coagulation Pathway
In contrast to our initial hypothesis, the various clotting factor levels showed no consistent pattern in association with air pollution.
FVII, one of the key enzymes of the extrinsic system of the coagulation cascade, is activated by tissue factor. Complexes of tissue factor with factor VIIa are central to the activation of factor X and to the formation of thrombin, which mediates the conversion of fibrinogen to fibrin (43). Results for FVII in the literature are inconsistent (28, 44). In our study, FVII activity decreased significantly in association with most pollutants.
Regarding fibrinogen levels, we did not find any consistent results in association with air pollution. Controlled human exposure studies (45, 46) as well as epidemiologic studies (47, 48) demonstrated positive associations between fibrinogen or plasma viscosity and air pollution. However, decreases in fibrinogen levels also have been reported and the significance of these results is unknown (28, 41).
Prothrombin fragment 1+2 is cleaved from prothrombin when it is activated to thrombin by factor Xa, thereby representing a marker of activation of the coagulation pathway (34, 49, 50). Our data indicate an increased concentration in association with ambient air pollutants. This significant increase indicates that an early step of blood coagulation has been activated. However, this activation was not associated with increased formation of fibrin, as would be detected by elevated D-dimer levels. The elevated levels of prothrombin fragment 1+2 are an important finding that shows that air pollution not only induces inflammation but also coagulation.
The large number of blood markers measured in this study revealed inconsistencies that were already observed in previous studies (13). One possible explanation is that various particle fractions or components differ in their effects. CRP, for example, did not show any association with EC and OC, whereas other blood markers showed quite strong effects. Moreover, diverse time patterns in the reaction to air pollution, due to the differing biological mechanisms, are conceivable and were also seen in the data.
While the results for inflammation and air pollution seem consistent, inhomogeneity exists in terms of coagulation markers. Our data strongly indicate that the pathway that links airway injury from air pollution and coronary events may include increased expression of adhesion molecules and a proinflammatory response. Furthermore, the coagulation system (prothrombin fragment 1+2) is activated, although not sufficiently enough to cause increased fibrin formation, as would have been reflected by elevated D-dimer levels. We do not have an explanation for the decreased concentrations of fibrinogen and FVII, but, whatever the cause, they may act to protect against clinical events secondary to coronary thrombosis. Our study represents measurements of background levels of blood markers and does not reflect changes that might relate to acute clinical events.
Strengths and Limitations
A strength of this study is the achievement of 99% of all scheduled visits. Moreover, a wide range of markers, reflecting different pathways, were measured within the same setting. All of the measured biomarkers may increase in response to a number of unspecific stimuli, such as infectious diseases or surgery. CRP is particularly sensitive and can increase a thousandfold within a short time in response to such triggers (34). Therefore, we excluded all blood samples that potentially might have been affected by sources other than air pollution. All patients were asked about infections and surgery in the 2 wk before the blood withdrawal. Reasons for physician visits as well as hospital admissions were recorded, and study nurses documented signs of an acute respiratory infection in the patient during regular clinic visits. None of the samples that revealed especially high or low levels of the respective biomarker were excluded unless a reason was known.
We used logistic regression analyses in addition to linear regression because Peters and colleagues (16) had suggested that effects of air pollution may be seen on a small number of subjects with high values of a particular marker with less effect on the mean level. Also, some parameters showed a few extreme outliers, which strongly influenced the regression results.
Although the fixed-effect models were adjusted for individual time-invariant factors, by design no adjustment for time-dependent individual-level variables was possible.
A variety of pollutants were used for the analyses, because different pollutants may point toward different properties of the aerosol, and also represent different sources of air pollution. However, by testing multiple blood parameters and a set of air pollutants, the possibility that some effects might have occurred by chance cannot be excluded. Because the air pollution parameters are closely correlated, we considered especially consistent patterns in the data as actual effects. Moreover, thorough confounder adjustment for meteorologic variables was done to rule out the possibility that the detected associations resulted from meteorologic influences or seasonal differences.
Only one central measurement site was used for the collection of ambient air pollution. However, the spatial representativeness of this site has been analyzed in detail previously by Cyrys and colleagues (51), who measured sulfate and PM10 levels simultaneously at three additional monitoring sites in the Erfurt area. The relatively high intersite correlation between the monitoring stations (0.69–0.98) indicates that regional episodes of sulfates and PM10 in Erfurt can be identified using one fixed monitoring site and that our site is generally representative for the urban background level of air pollution within Erfurt. Erfurt is a small city with one air mass confined by a mountain ridge on three sides and high rises on the fourth side. Because most of the participants of our panel were already retired, we assume that they spent the greater part of their day within the vicinity of their residence within the city of Erfurt.
Many studies have demonstrated that individual exposures to PM are poorly correlated spatially with ambient concentrations (52). Some longitudinal exposure assessment studies of PM and specific PM components with repeated measures have found higher correlations between personal exposures and ambient concentrations. Janssen and coworkers (53) showed, for example, that ambient, indoor, and personal concentrations of PM2.5 were highly correlated in two European cities.
However, the correlation many epidemiologists are interested in is not that between total personal exposure and outdoor concentrations but the correlation between that component of personal exposure that can be attributed to outdoor particles and the outdoor concentrations. Ebelt and colleagues (54) demonstrated that ambient concentrations and the contribution of ambient particles to personal PM exposure were highly correlated, with a Pearson correlation coefficient of 0.81 for PM2.5, of 0.71 for PM10 and of 0.73 for the coarse fraction (PM10 – PM2.5). Moreover, they show that ambient concentrations and exposure to nonambient PM2.5 are independent, which is an important assumption in epidemiologic studies that use ambient concentration as a surrogate for personal exposure. They conclude that their results give support to the use of ambient monitoring data in time series analyses. Cyrys and coworkers (55), who compared the relationship of indoor and outdoor levels of fine-particulate mass, particle number concentrations, and black smoke, concluded that ambient concentrations of PM2.5 and black smoke can be used as good approximations of indoor concentrations.
A limitation to the study is that the examined panel consisted of male patients only, with a history of CHD, who were all taking cardiac medication. Therefore, they represent a highly selected group and the study results might not be generalizable to other population groups, such as females with CHD or healthy subjects.
A differentiation between chronic and acute effects of higher levels of blood markers in the patients is not possible with this study design. Because of the short observation time, it is not clear whether these changes can lead to an onset or exacerbation of the disease. We observed short-term changes in various blood parameters; however, the implications for patients remain speculative. On the other hand, changes in blood markers due to air pollution have recently been observed not only in patients with CHD but also in young and healthy persons (56).
Conclusions
The study adds to the evidence that elevated levels of ambient air pollution may cause systemic inflammatory and coagulation responses. These changes in blood markers could represent additional risk factors, which, in susceptible individuals, such as patients with CHD, could increase the likelihood of serious arterial vascular thrombotic events on exposure to high levels of air pollutants.
Acknowledgments
The authors thank Dr. O. Manuwald and his team and the German Weather Service (DWD). The study is funded through the U.S. Environmental Protection Agency STAR Center grant R-827354 and the Focus-Network of Aerosols and Health, GSF. The Focus-Network of Aerosols and Health coordinates and focuses all GSF research on health effects and the characterization of aerosols. It comprises research projects of the Institutes of Ecological Chemistry, Epidemiology, Inhalation Biology, Radiation Protection, and Toxicology at GSF.
FOOTNOTES
Supported by the U.S. Environmental Protection Agency STAR center grant R-827354 and the Focus-Network of Aerosols and Health, GSF.
Originally Published in Press as DOI: 10.1164/rccm.200507-1123OC on November 17, 2005
Conflict of Interest Statement: None of the authors have a financial relationship with a commercial entity that has an interest in the subject of this manuscript.
REFERENCES
Schwartz J, Marcus A. Mortality and air pollution in London: a time series analysis. Am J Epidemiol 1990;131:185–194.
Peters A, Skorkovsky J, Kotesovec F, Brynda J, Spix C, Wichmann HE, Heinrich J. Associations between mortality and air pollution in Central Europe. Environ Health Perspect 2000;108:283–287.
Schwartz J, Dockery DW. Particulate air pollution and daily mortality in Steubenville, Ohio. Am J Epidemiol 1992;135:12–19.
Schwartz J. Particulate air pollution and daily mortality in Detroit. Environ Res 1991;56:204–213.
Schwartz J. Air pollution and daily mortality in Birmingham, Alabama. Am J Epidemiol 1993;137:1136–1147.
Forastiere F, Stafoggia M, Picciotto S, Bellander T, D'Ippoliti D, Lanki T, von Klot S, Nyberg F, Paatero P, Peters A, et al. A case-crossover analysis of out-of-hospital coronary deaths and air pollution in Rome, Italy. Am J Respir Crit Care Med 2005;172:1549–1555.
Burnett RT, Dales RE, Brook JR, Raizenne ME, Krewski D. Association between ambient carbon monoxide levels and hospitalizations for congestive heart failure in the elderly in 10 Canadian cities. Epidemiology 1997;8:162–167.
Schwartz J. Air pollution and hospital admissions for cardiovascular disease in Tucson. Epidemiology 1997;8:371–377.
Schwartz J. Air pollution and hospital admissions for heart disease in eight US counties. Epidemiology 1999;10:17–22.
Peters A, Dockery DW, Muller JE, Mittleman MA. Increased particulate air pollution and the triggering of myocardial infarction. Circulation 2001;103:2810–2815.
de Hartog JJ, Hoek G, Peters A, Timonen KL, Ibald-Mulli A, Brunekreef B, Heinrich J, Tiittanen P, van Wijnen JH, Kreyling W, et al. Effects of fine and ultrafine particles on cardiorespiratory symptoms in elderly subjects with coronary heart disease: the ULTRA study. Am J Epidemiol 2003;157:613–623.
Brook R, Franklin B, Cascio WE, Hong Y, Howard G, Lipsett M, Luepker R, Mittleman MA, Samet J, Smith S, et al. Air pollution and cardiovascular disease: a statement for healthcare professionals from the Expert Panel on Population and Prevention Science of the American Heart Association. Circulation 2004;109:2655–2671.
Seaton A, MacNee W, Donaldson K, Godden D. Particulate air pollution and acute health effects. Lancet 1995;345:176–178.
DeMeo DL, Zanobetti A, Litonjua AA, Coull BA, Schwartz J, Gold DR. Ambient air pollution and oxygen saturation. Am J Respir Crit Care Med 2004;170:383–387.
Pope CA, Burnett RT, Thurston GD, Thun MJ, Calle EE, Krewski D, Godleski JJ. Cardiovascular mortality and long-term exposure to particulate air pollution: epidemiological evidence of general pathophysiological pathways of disease. Circulation 2004;109:71–77.
Peters A, Dring A, Wichmann HE, Koenig W. Increased plasma viscosity during air pollution episode: a link to mortality Lancet 1997;349:1582–1587.
Peters A, Frohlich M, Doring A, Immervoll T, Wichmann HE, Hutchinson WL, Pepys MB, Koenig W. Particulate air pollution is associated with an acute phase response in men: results from the MONICA-Augsburg study. Eur Heart J 2001;22:1198–1204.
Rückerl R, Ibald-Mulli A, Koenig W, Henneberger A, Woelke G, Cyrys J, Wichmann H-E, Peters A. Ambient air pollution and systemic inflammatory responses in patients with coronary heart disease. Eur Respir J 2004;24:237.
Kreyling WG, Tuch T, Peters A, Pitz M, Heinrich J, Stolzel M, Cyrys J, Heyder J, Wichmann HE. Diverging long-term trends in ambient urban particle mass and number concentrations associated with emission changes caused by the German unification. Atmos Environ 2003;37:3841–3848.
Ibald-Mulli A. Effects of particulate air pollution on blood pressure and heart rate in subjects with cardiovascular disease: results from the ULTRA study. 2003.
Wichmann HE, Spix C, Tuch T, Woelke G, Peters A, Heinrich J, Kreyling WG, Heyder J. Daily mortality and fine and ultrafine particles in Erfurt, Germany: part I: role of particle number and particle mass. Res Rep Health Eff Inst 2000;98:5–86.
Tuch T, Mirme A, Tamm E, Heinrich J, Heyder J, Brand P, Roth C, Wichmann HE, Pekkanen J, Kreyling WG. Comparison of two particle-size spectrometers for ambient aerosol measurements in environmental epidemiology. Atmos Environ 2000;34:139–149.
Kreyling WG, Tuch T, Peters A, Pitz M, Heinrich J, Stolzel M, Cyrys J, Heyder J, Wichmann HE. Diverging long-term trends in ambient urban particle mass and number concentrations associated with emission changes caused by the German unification. Atmos Environ 2003;37:3841–3848.
Brand P, Gerhardt J, Below M, Georgi B, Heyder J. Technical note: performance of a mobile aerosol spectrometer for an in situ characterisation of environmental aerosols in Frankfurt city. Atmos Environ 1992;26:2451–2457.
Tuch T, Brand P, Wichmann HE, Heyder J. Variation of particle number and mass concentration in various size ranges of ambient aerosols in Eastern Germany. Atmos Environ 1997;31:4193–4197.
Cyrys J, Stolzel M, Heinrich J, Kreyling WG, Menzel N, Wittmaack K, Tuch T, Wichmann HE. Elemental composition and sources of fine and ultrafine ambient particles in Erfurt, Germany. Sci Total Environ 2003;305:143–156.
Utell MJ, Frampton MW. Acute health effects of ambient air pollution: the ultrafine particle hypothesis. J Aerosol Med 2000;13:355–359.
Seaton A, Soutar A, Crawford V, Elton R, McNerlan S, Cherrie J, Watt M, Agius R, Stout R. Particulate air pollution and the blood. Thorax 1999;54:1027–1032.
Danesh J, Whincup P, Walker M, Lennon L, Thomson A, Appleby P, Gallimore JR, Pepys MB. Low grade inflammation and coronary heart disease: prospective study and updated meta-analyses. BMJ 2000;321:199–204.
Harris TB, Ferrucci L, Tracy RP, Corti MC, Wacholder S, Ettinger WH Jr, Heimovitz H, Cohen HJ, Wallace R. Associations of elevated interleukin-6 and C-reactive protein levels with mortality in the elderly. Am J Med 1999;106:506–512.
Ridker PM, Rifai N, Stampfer MJ, Hennekens CH. Plasma concentration of interleukin-6 and the risk of future myocardial infarction among apparently healthy men. Circulation 2000;101:1767–1772.
Geiser M. Morphological aspects of particle uptake by lung phagocytes. Microsc Res Tech 2002;57:512–522.
Koenig W, Sund M, Frohlich M, Lowel H, Hutchinson WL, Pepys MB. Refinement of the association of serum C-reactive protein concentration and coronary heart disease risk by correction for within-subject variation over time. Am J Epidemiol 2003;158:357–364.
Thomas L. Labor und diagnose. Frankfurt a. Main, Germany: TH-Books Verlagsgesellschaft; 1998.
Rubin E, Farber JL. Pathology. Philadelphia: J.B. Lippincott; 1998.
von Andrian UH, Mackay CR. Advances in immunology: T-cell function and migration: two sides of the same coin. N Engl J Med 2000;343:1020–1033.
Luster AD. Chemokines: chemotactic cytokines that mediate inflammation. N Engl J Med 1998;338:436–445.
Luc G, Arveiler D, Evans A, Amouyel P, Ferrieres J, Bard JM, Elkhalil L, Fruchart JC, Ducimetiere P. Circulating soluble adhesion molecules ICAM-1 and VCAM-1 and incident coronary heart disease: the PRIME Study. Atherosclerosis 2003;170:169–176.
Salvi S, Blomberg A, Rudell B, Kelly F, Sandstrom T, Holgate ST, Frew A. Acute inflammatory responses in the airways and peripheral blood after short-term exposure to diesel exhaust in healthy human volunteers. Am J Respir Crit Care Med 1999;159:702–709.
Kennedy T, Ghio AJ, Reed W, Samet J, Zagorski J, Quay J, Carter J, Dailey L, Hoidal JR, Devlin RB. Copper-dependent inflammation and nuclear factor-kappaB activation by particulate air pollution. Am J Respir Cell Mol Biol 1998;19:366–378.
Khandoga A, Stampfl A, Takenaka S, Schulz H, Radykewicz R, Kreyling W, Krombach F. Ultrafine particles exert prothrombotic but not inflammatory effects on the hepatic microcirculation in healthy mice in vivo. Circulation 2004;109:1320–1325.
Gardiner E, Andrews R, Shen Y, Berndt M. Platelet interactions in thrombosis. IUBMB Life 2004;56:13–18.
Marder V, Rosove M, Minning D. Foundation and sites of action of antithrombotic agents. Best Pract Res Clin Haematol 2004;17:3–22.
Pekkanen J, Brunner EJ, Anderson HR, Tiittanen P, Atkinson RW. Daily concentrations of air pollution and plasma fibrinogen in London. Occup Environ Med 2000;57:818–822.
Huang YC, Ghio AJ, Stonehuerner J, McGee J, Carter JD, Grambow SC, Devlin RB. The role of soluble components in ambient fine particles-induced changes in human lungs and blood. Inhal Toxicol 2003;15:327–342.
Ghio AJ, Kim C, Devlin RB. Concentrated ambient air particles induce mild pulmonary inflammation in healthy human volunteers. Am J Respir Crit Care Med 2000;162:981–988.
Schwartz J. Air pollution and blood markers of cardiovascular risk. Environ Health Perspect 2001;109:405–409.
Pekkanen J, Brunner EJ, Anderson HR, Tiittanen P, Atkinson RW. Daily concentrations of air pollution and plasma fibrinogen in London. Occup Environ Med 2000;57:818–822.
Bauer K, Barzegar S, Rosenberg R. Influence of anticoagulants used for blood collection on plasma prothrombin fragment F1+2 measurements. Thromb Res 1991;63:617–628.
Rybak M, Lau H, Tomkins B, Rosenberg R, Handin R. Relationship between platelet secretion and prothrombin cleavage in native whole blood. J Clin Invest 1981;68:405–412.
Cyrys J, Heinrich J, Brauer M, Wichmann HE. Spatial variability of acidic aerosols, sulfate and PM10 in Erfurt, Eastern Germany. J Expo Anal Environ Epidemiol 1998;8:447–464.
U.S. Environmental Protection Agency. Air quality criteria for particulate matter. Research Triangle Park, NC: National Center for Environmental Assessment-RTP Office; 1996. Publication No. EPA/600/P-95/001aF-cF.3v.
Janssen NAH, Hoek G, Brunekreef B, Harssema H, Mensink I, Zuidhoh A. Personal sampling of particles in adults: relation among personal, indoor, and outdoor air concentrations. Am J Epidemiol 1998;147:537–547.
Ebelt ST, Wilson WE, Brauer M. Exposure to ambient and nonambient components of particulate matter: a comparison of health effects. Epidemiology 2005;16:396–405.
Cyrys J, Pitz M, Bischof W, Wichmann HE, Heinrich J. Relationship between indoor and outdoor levels of fine particle mass, particle number concentrations and black smoke under different ventilation conditions. J Expo Anal Environ Epidemiol 2004;14:275–283.
Riediker M, Cascio WE, Griggs TR, Herbst MC, Bromberg PA, Neas L, Williams RW, Devlin RB. Particulate matter exposure in cars is associated with cardiovascular effects in healthy young men. Am J Respir Crit Care Med 2004;169:934–940.(Regina Rückerl, Angela Ibald-Mulli, Wolf)