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Environmental Health and Preventive Medicine
Erschienen in: Environmental Health and Preventive Medicine 1/2018

Open Access 01.12.2018 | Research article

Association of airborne particles, protein, and endotoxin with emergency department visits for asthma in Kyoto, Japan

verfasst von: Mohammad Shahriar Khan, Souleymane Coulibaly, Takahiro Matsumoto, Yoshitaka Yano, Makoto Miura, Yukio Nagasaka, Masayuki Shima, Nobuyuki Yamagishi, Keiji Wakabayashi, Tetsushi Watanabe

Erschienen in: Environmental Health and Preventive Medicine | Ausgabe 1/2018

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Abstract

Background

The health effects of biological aerosols on the respiratory system are unclear. The purpose of this study was to clarify the association of airborne particle, protein, and endotoxin with emergency department visits for asthma in Kyoto City, Japan.

Methods

We collected data on emergency department visits at a hospital in Kyoto from September 2014 to May 2016. Fine (aerodynamic diameter ≤ 2.5 μm) and coarse (≥ 2.5 μm) particles were collected in Kyoto, and protein and endotoxin levels were analyzed. The association of the levels of particles, protein, endotoxin, and meteorological factors (temperature, relative humidity, wind speed, and air pressure) with emergency department visits for asthma was estimated.

Results

There were 1 to 15 emergency department visits for asthma per week, and the numbers of visits increased in the autumn and spring, namely many weeks in September, October, and April. Weekly concentration of protein in fine particles was markedly higher than that in coarse particles, and protein concentration in fine particles was high in spring months. Weekly endotoxin concentrations in fine and coarse particles were high in autumn months, including September 2014 and 2015. Even after adjusting for meteorological factors, the concentrations of coarse particles and endotoxin in both particles were significant factors on emergency department visits for asthma.

Conclusions

Our results suggest that atmospheric coarse particles and endotoxin are significantly associated with an increased risk of asthma exacerbation.
Begleitmaterial
Hinweise

Electronic supplementary material

The online version of this article (https://​doi.​org/​10.​1186/​s12199-018-0731-2) contains supplementary material, which is available to authorized users.
Abkürzungen
LAL
Limulus amebocyte lysate
PM2.5
Particulate matter ≤ 2.5 μm

Background

Many epidemiological studies have shown that exposure to airborne particles is associated with the exacerbation of asthmatic symptoms and the increase of asthma-related emergency department visits [13]. However, other studies have reported contradictory results [4, 5]. Airborne particles are a mixture of diverse materials; this variation may cause differences in the health effects. Biological aerosols, or bioaerosols, are suspended airborne particles comprising microorganisms such as bacteria and fungi and organic materials originating from living organisms. For instance, allergic proteins originating from fungi and pollen have been detected in airborne particles [6, 7]. Total protein concentration is often used as an all-inclusive indicator of airborne biological material that may enhance allergic and asthmatic responses in aerobiological studies [810]. Endotoxins or lipopolysaccharides are the major components of the outer membrane of Gram-negative bacteria and have been detected in both fine (aerodynamic diameter ≤ 2.5 μm; PM2.5) and coarse (aerodynamic diameter ≥ 2.5 μm) particles collected in urban and rural regions [1114]. The inhalation of endotoxins stimulates the alveolar macrophages and respiratory epithelial tissue to release cytokines or chemoattractants that initiate an inflammatory cascade [15]. Epidemiological and controlled exposure studies have indicated that endotoxin exposure is positively associated with the exacerbation of asthma [16, 17]. As described above, airborne particles, protein, and endotoxin may cause the exacerbation of asthma; therefore, knowing the concentrations of these air pollutants is important for patients with asthma to avoid exacerbation of their symptoms. However, there are few reports on the long-term levels of proteins and endotoxins in the outdoor air of Japan [14].
The purpose of this study was to measure the concentrations of airborne particles, protein, and endotoxin in outdoor air and their associations with asthma. We collected fine (aerodynamic diameter ≤ 2.5 μm) and coarse (≥ 2.5 μm) particles and data on emergency department visits for asthma at a hospital in Kyoto City, Japan, from September 2014 to May 2016 and analyzed proteins and endotoxin levels in both types of particle. Kyoto is a core city of the Keihanshin metropolitan area, which is the second largest metropolitan area of Japan. The population of Kyoto City is 1.5 million, and its key industries are information technology, electronics, and tourism. Because meteorological factors such as temperature and relative humidity are reportedly associated with emergency department visits for asthma [18, 19], we used regression analysis to investigate the association of the levels of particles, protein, endotoxin, temperature, relative humidity, wind speed, and air pressure with emergency department visits for asthma.

Methods

Data on emergency department visits

We obtained anonymized data on emergency department visits for asthma at the Rakuwakai Emergency and Critical Care Center in Kyoto from September 2014 to May 2016. The data included information on patient age, diagnosis, and date of visit. The patients in this study were adults (aged 15 years or older) and children (< 15 years). This retrospective observational study was approved by the ethics committee of Kyoto Pharmaceutical University (Approval No. 17-16-18) and Rakuwakai Otowa Hospital (Approval No. 16-018).

Environmental data

Fine and coarse particles were collected on glass filters (Advantec Co., Ltd., Tokyo, Japan) and quartz filters (Pall Life Sciences, Port Washington, NY, USA), respectively, in Kyoto (135.81° E, 34.99° N) using a high-volume air sampler (HV1000R; Shibata Scientific Technology, Soka, Japan) equipped with an impactor (Shibata Scientific Technology) at a flow rate of 1 m3/min for 1 week per filter. The filters were heated at 250 °C for 2 h prior to use. Particle collection was performed for 2 to 4 weeks per month from September 2014 to May 2016 (Table 1). In total, 154 samples (77 sets each of fine and coarse particles) were collected. In October 1–14, 2014, we could not collect samples for seven consecutive days because of a typhoon. We eliminated 3 weeks, namely April 30 to May 6 and September 18–24, 2015, and May 2–8, 2016, because these weeks included three or four national holidays, and the number of emergency department visits for asthma might have increased in these weeks. The filters were weighed before and after the collection of airborne particles. After the sample collection, the filters were kept in a freezer at − 80 °C until protein and endotoxin measurement.
Table 1
Sampling periods of the particles
Year
Month
Week
2014
September
1st (Sep. 1–7), 2nd (8–14), 3rd (15–21), 4th (22–28)
October
1st (Oct. 15–21), 2nd (22–28)
November
1st (Oct. 31–Nov. 6), 2nd (7–13), 3rd (14–20), 4th (21–27)
December
1st (Dec. 1–7), 2nd (8–14), 3rd (15–21), 4th (22–28)
2015
January
1st (Jan. 6–12), 2nd (13–19), 3rd (20–26)
February
1st (Feb. 2–8), 2nd (9–15), 3rd (16–22), 4th (Feb. 23Mar. 1)
March
1st (Mar. 2–8), 2nd (9–15), 3rd (1622), 4th (23–29)
April
1st (Apr. 2–8), 2nd (9–15), 3rd (16–22), 4th (23–29)
May
1st (May 7–13), 2nd (15–21th), 3rd (22nd–28th)
June
1st (Jun. 1–7), 2nd (814), 3rd (15–21), 4th (22–28)
July
1st (Jul. 3–9), 2nd (10–16), 3rd (17–23), 4th (24–30)
August
1st (Aug. 3–9), 2nd (10–16), 3rd (17–23), 4th (24–30)
September
1st (Sep. 4–10), 2nd (11–17), 3rd (Sep. 25–Oct. 1)
October
1st (Oct. 2–8), 2nd (9–15), 3rd (16–22), 4th (23–29)
November
1st (Nov. 4–10), 2nd (11–17), 3rd (18–24), 4th (Nov. 25–Dec. 1)
December
1st (Dec. 2–8), 2nd (9–15), 3rd (16–22)
2016
January
1st (Jan. 6–12), 2nd (13–19), 3rd (20–26), 4th (Jan. 27–Feb. 2)
February
1st (Feb. 3–9), 2nd (10–16), 3rd (17–23), 4th (Feb. 24–Mar. 1)
March
1st (Mar. 3–9), 2nd (10–16), 3rd (17–23), 4th (24–30)
April
1st (Apr. 1–7), 2nd (8–14), 3rd (15–21), 4th (2228)
May
1st (May 9–15), 2nd (16–22), 3rd (23–29)
The Asian dust event was observed in Kyoto by Japan Meteorological Agency on the following days: Feb. 23 and 24, Mar. 22, and Jun. 13 in 2015, and Apr. 24 and 25 in 2016. The weeks written in italics are periods that Asian dust event was observed
To analyze protein and endotoxin levels, 15% of the sample filters (corresponding to 1512 m3 of air) were extracted using 0.025% Tween 20 for 30 min by an ultrasonic apparatus [14]. The extract was centrifuged, and a portion of the supernatant was used for the protein and endotoxin analyses.
The protein levels were analyzed using a bicinchoninic acid assay (Micro BCA Protein Assay Kit; Thermo Fisher Scientific, Rockford, IL, USA) according to the manufacturer’s protocols and a microplate reader (Sunrise Thermo RC-R; Tecan Austria GmbH, Groedig, Austria), as described previously [14]. The absorption of all 154 samples was higher than the detection limit (2.5 μg/mL), while that of a blank filter was lower than the detection limit.
The endotoxin levels were analyzed using the kinetic chromogenic Limulus amebocyte lysate (LAL) method (Limulus Color KY Test Wako kit; Wako Pure Chemical Industries, Ltd., Osaka, Japan) according to the manufacturer’s protocols with a microplate reader (Sunrise Thermo RC-R), as described previously [14]. Absorption of all 154 samples was higher than the detection limit (0.0005 EU/mL), while that of a blank filter was lower than the detection limit. For the spiked samples, the recovery rates were in the range of 50–200%, which were considered acceptable according to the instructions for the LAL assay kit.
Data on the daily mean ambient temperature, relative humidity, wind speed, and air pressure in Kyoto City were acquired from the Japan Meteorological Agency [20].

Statistical analyses

Microsoft Office 2013 was used to calculate correlation coefficients. For the analyses of the association between the weekly numbers of emergency department visits and the weekly levels of environmental factors, we used the generalized linear models to fit a Poisson regression. The analyses were performed using SPSS Statistics Version 22 (IBM Software Group, Chicago, IL, USA). A p value of < 0.05 was considered statistically significant.

Results

Emergency room visits for asthma

Figure 1 shows the weekly number of emergency department visits for asthma during the study period (September 2014 to May 2016). In total, there were 490 emergency department visits (229 adults and 261 children) during that period. The number of emergency department visits ranged from 1 to 15 per week, with a high number of visits in the autumn and spring months, namely September (fourth week) 2014, September (first and second weeks) and October (first and fourth weeks) 2015, and April (third week) 2016.

Weekly levels of air pollutants, temperature, relative humidity, wind speed, and air pressure

The weekly concentrations of particles, protein, and endotoxin in the outdoor air of Kyoto City during the study period are shown in Additional file 1: Figures S1, S2, and S3, respectively. Protein and endotoxin were detected in all samples examined in this study. For the entire sampling period, the weekly concentration of fine particles was slightly higher than that of coarse particles; the fine and coarse particle concentrations were 6.2–32.3 and 2.4–23.8 μg/m3, respectively (Additional file 1: Figure S1). For fine particles, the atmospheric concentrations were high in spring months, including March and April 2015 and May 2016. The atmospheric mass concentrations of coarse particles were high in the fourth week of February and spring months, including April 2015. The weekly concentration of protein in fine particles was markedly higher than that in coarse particles throughout the entire sampling period; the weekly protein concentrations of fine and coarse particles were 0.17–5.09 and 0.02–0.46 μg/m3, respectively (Additional file 1: Figure S2). The concentrations of protein in fine particles were high in spring months, including April and May 2015 and May 2016. In contrast, weekly concentrations of endotoxin in coarse particles (0.0004–0.0292 EU/m3) were higher than those in fine particles (0.00003–0.01279 EU/m3), and the weekly concentrations of endotoxin in coarse particles were high in autumn months, including September 2014 and 2015 (Additional file 1: Figure S3).
Table 2 shows the whole and seasonal mean values and standard deviations of air pollutants and meteorological factors. The mean values and standard deviations were calculated with the weekly mean value of each factor. Mean values of fine and coarse particles and protein in fine particles were high in spring 1 and spring 2. In contrast, the mean value of endotoxin in coarse particles was high in autumn 1 and autumn 2. Mean value of temperature ranged from 5.6 °C (winter 1) to 26.1 °C (summer). Other meteorological factors did not show any noticeable fluctuation.
Table 2
Weekly mean value (standard deviation) of air pollutants and meteorological factors
 
Fine particle
Coarse particle
Temperature(°C)
Relative humidity (%)
Wind speed (m/s)
Air pressure (hPa)
Particles (μg/m3)
Protein (μg/m3)
Endotoxin (EU/m3)
Particles (μg/m3)
Protein (μg/m3)
Endotoxin (EU/m3)
Whole
14.4 (5.2)
1.42 (0.84)
0.0019 (0.0022)
7.6 (3.3)
0.12 (0.08)
0.0052 (0.0052)
15.1 (7.7)
65.5 (6.4)
2.1 (0.3)
1010.2 (4.9)
Autumn 1
12.2 (2.1)
1.83 (0.74)
0.0031 (0.0035)
7.7 (1.1)
0.17 (0.11)
0.0098 (0.0089)
18.0 (5.2)
65.9 (5.0)
1.9 (0.26)
1010.7 (4.15)
Winter 1
13.2 (4.4)
1.26 (0.34)
0.0007 (0.0006)
7.1 (5.8)
0.07 (0.04)
0.0014 (0.0007)
5.6 (1.3)
69.2 (3.5)
2.0 (0.3)
1012.6 (2.7)
Spring 1
18.7 (7.4)
1.96 (0.70)
0.0020 (0.0022)
8.5 (3.3)
0.16 (0.05)
0.0039 (0.0026)
14.6 (5.6)
61.5 (9.2)
2.2 (0.2)
1010.0 (4.5)
Summer
12.7 (4.3)
0.79 (0.33)
0.0008 (0.0009)
8.1 (2.0)
0.19 (0.07)
0.0076 (0.0047)
26.1 (3.1)
68.6 (5.1)
2.2 (0.4)
1002.9 (1.8)
Autumn 2
11.3 (4.2)
0.95 (0.42)
0.0026 (0.0021)
7.4 (2.9)
0.05 (0.02)
0.0074 (0.0050)
18.1 (4.0)
67.1 (6.2)
1.9 (0.3)
1011.2 (4.2)
Winter 2
12.3 (3.1)
1.20 (0.71)
0.0010 (0.0005)
5.5 (2.1)
0.05 (0.03)
0.0017 (0.0004)
6.9 (2.6)
65.1 (4.4)
2.1 (0.3)
1014.4 (3.0)
Spring 2
17.8 (5.0)
2.05 (1.32)
0.0032 (0.0025)
8.6 (3.6)
0.12 (0.05)
0.0049 (0.0031)
15.5 (5.04)
61.0 (5.3)
2.2 (0.2)
1010.1 (3.7)
Table 3 shows the correlation coefficients for the weekly levels of airborne particles, protein, endotoxin, temperature, relative humidity, wind speed, and air pressure. For fine particles, the concentration of protein was positively correlated with that of particles (r = 0.654, p < 0.001) and endotoxin (r = 0.331, p = 0.003). For coarse particles, the concentration of protein was positively correlated with the concentration of particles (r = 0.357, p = 0.001) and endotoxin (r = 0.498, p < 0.001). The temperature was positively correlated with the coarse particle concentration and the concentrations of protein and endotoxin in coarse particles. Relative humidity was negatively correlated with the concentrations of fine particles and that of protein and endotoxin in fine particles. Air pressure was negatively correlated with the concentrations of protein and endotoxin in coarse particles.
Table 3
Correlation coefficient (p value) for environmental factors
 
Fine particles
Protein (fine particles)
Endotoxin (fine particles)
Coarse particles
Protein (coarse particles)
Endotoxin (coarse particles)
Temperature
Relative humidity
Wind speed
Air pressure
Fine particles
1.00
         
Protein (fine particles)
0.654 (< 0.001)
1.00
        
Endotoxin (fine particles)
0.212 (0.064)
0.331 (0.003)
1.00
       
Coarse particles
0.551 (< 0.001)
0.175 (0.128)
0.134 (0.246)
1.00
      
Protein (coarse particles)
0.233 (0.041)
0.169 (0.142)
0.045 (0.695)
0.357 (0.001)
1.00
     
Endotoxin (coarse particles)
− 0.104 (0.367)
− 0.085 (0.465)
0.474 (< 0.001)
0.187 (0.103)
0.498 (< 0.001)
1.00
    
Temperature
0.015 (0.897)
− 0.045 (0.698)
0.218 (0.057)
0.244 (0.032)
0.592 (< 0.001)
0.633 (< 0.001)
1.00
   
Relative humidity
− 0.548 (< 0.001)
− 0.516 (< 0.001)
− 0.523 (< 0.001)
− 0.187 (0.103)
0.015 (0.897)
− 0.006 (0.960)
− 0.033 (0.779)
1.00
  
Wind speed
0.026 (0.822)
0.037 (0.750)
0.088 (0.445)
0.020 (0.860)
0.104 (0.366)
0.081 (0.485)
0.082 (0.476)
− 0.367 (0.001)
1.00
 
Air pressure
0.043 (0.709)
0.176 (0.126)
− 0.102 (0.378)
− 0.135 (0.240)
− 0.567 (< 0.001)
− 0.463 (< 0.001)
− 0.511 (< 0.001)
0.008 (0.944)
− 0.294 (0.009)
1.00
Correlation coefficient (p value) was calculated with the weekly levels of airborne particles, protein, endotoxin, temperature, relative humidity, wind speed, and air pressure. Statistically significant, p < 0.05

Association of environmental factor levels with emergency department visits for asthma

Figure 2 shows the scatter plots of protein and endotoxin levels with the number of emergency department visits. The influences of the concentrations of airborne particles, protein, and endotoxin in fine and coarse particles on the emergency department visits for asthma were evaluated by generalized linear models to fit a Poisson regression to adjust for meteorological factors (temperature, relative humidity, wind speed, and air pressure). As shown in Table 4, the concentrations of coarse particles and endotoxin in fine and coarse particles were statistically significant factors on emergency department visits for asthma. Among the meteorological factors, temperature was a significant factor in all cases. The concentrations of coarse particles and endotoxin in fine and coarse particles and temperature were positively associated with the number of emergency department visits for asthma.
Table 4
Results of Poisson regressions of air pollutants and meteorological factors on emergency department visits
Variables
Coef
SE
p value
Fine particles
− 0.009
0.011
0.414
 Intercept
− 16.799
16.449
0.307
 Temperature
0.046
0.010
< 0.001
 Relative humidity
− 0.009
0.009
0.322
 Wind speed
− 0.213
0.174
0.222
 Air pressure
0.019
0.016
0.235
Protein (fine particles)
0.032
0.062
0.609
 Intercept
− 16.566
16.538
0.317
 Temperature
0.046
0.010
< 0.001
 Relative humidity
− 0.002
0.009
0.823
 Wind speed
− 0.170
0.172
0.324
 Air pressure
0.018
0.016
0.264
Endotoxin (fine particles)
59.792
20.907
0.004
 Intercept
− 18.420
16.674
0.269
 Temperature
0.043
0.010
< 0.001
 Relative humidity
0.009
0.009
0.333
 Wind speed
− 0.100
0.170
0.556
 Air pressure
0.019
0.016
0.242
Coarse particles
0.044
0.013
0.001
 Intercept
− 17.309
16.523
0.295
 Temperature
0.042
0.010
< 0.001
 Relative humidity
− 0.001
0.008
0.944
 Wind speed
− 0.172
0.171
0.314
 Air pressure
0.018
0.016
0.251
Protein (coarse particles)
− 1.011
0.702
0.150
 Intercept
− 12.459
16.738
0.457
 Temperature
0.049
0.010
< 0.001
 Relative humidity
− 0.004
0.007
0.588
 Wind speed
− 0.186
0.168
0.270
 Air pressure
0.014
0.016
0.383
Endotoxin (coarse particles)
29.637
9.044
0.001
 Intercept
− 13.346
16.850
0.428
 Temperature
0.030
0.011
0.007
 Relative humidity
− 0.007
0.008
0.343
 Wind speed
− 0.210
0.174
0.226
 Air pressure
0.015
0.016
0.349
Coef regression coefficient, SE standard error of the regression
Statistically significant, p < 0.05
To consider the seasonal variation, we stratified the data by season and then analyzed the influences of environmental factors on the emergency department visits for asthma (Table 5). Coarse particle level was a statistically significant factor in spring and autumn and was positively associated with the emergency department visits for asthma. Protein level in fine particles was negatively associated with emergency department visits for asthma in summer. On the other hand, the protein level in coarse particles was a significantly positive factor in winter for emergency department visits. The endotoxin levels in both types of particles were not statistically significant in any season. Temperature was a significant factor in all cases in spring and in four of six cases in winter, and the association with emergency department visits was positive.
Table 5
Results of seasonal Poisson regressions of air pollutants and meteorological factors on emergency department visits
Variables
Spring
Summer
Autumn
Winter
Coef
SE
p value
Coef
SE
p value
Coef
SE
p value
Coef
SE
p value
Fine particles
0.024
0.018
0.199
− 0.082
0.055
0.131
0.052
0.032
0.107
0.003
0.032
0.931
 Intercept
− 29.035
37.402
0.438
− 22.254
77.335
0.774
9.183
34.969
0.793
45.921
42.385
0.279
 Temperature
0.088
0.033
0.007
0.040
0.045
0.375
0.038
0.032
0.239
0.107
0.052
0.039
 Relative humidity
0.016
0.016
0.311
− 0.021
0.043
0.621
0.016
0.019
0.419
0.036
0.029
0.214
 Wind speed
0.898
0.567
0.113
− 0.608
0.453
0.180
0.537
0.403
0.183
0.411
0.500
0.411
 Air pressure
0.026
0.036
0.477
0.027
0.079
0.736
− 0.010
0.034
0.763
− 0.048
0.041
0.245
Protein (fine particles)
− 0.128
0.121
0.291
− 1.039
0.521
0.046
0.098
0.129
0.449
0.048
0.233
0.837
 Intercept
− 48.966
38.962
0.209
− 53.432
80.320
0.506
11.460
34.557
0.740
49.651
46.418
0.285
 Temperature
0.119
0.039
0.002
0.011
0.047
0.822
0.038
0.034
0.252
0.107
0.051
0.035
 Relative humidity
< 0.001
0.015
0.974
0.001
0.030
0.977
− 0.001
0.015
0.966
0.035
0.028
0.221
 Wind speed
0.632
0.544
0.246
− 0.505
0.394
0.200
0.262
0.359
0.465
0.367
0.502
0.465
 Air pressure
0.047
0.038
0.210
0.057
0.082
0.488
− 0.010
0.034
0.756
− 0.051
0.045
0.254
Endotoxin (fine particles)
22.987
43.993
0.601
28.411
181.928
0.876
23.465
34.868
0.501
97.331
399.535
0.808
 Intercept
− 38.240
37.175
0.304
33.846
70.257
0.630
6.580
34.906
0.850
49.851
45.574
0.274
 Temperature
0.096
0.032
0.003
0.049
0.049
0.309
0.028
0.032
0.390
0.103
0.051
0.042
 Relative humidity
0.010
0.015
0.517
0.035
0.028
0.210
0.004
0.020
0.835
0.044
0.046
0.336
 Wind speed
0.732
0.552
0.185
− 0.163
0.412
0.692
0.333
0.382
0.382
0.361
0.501
0.471
 Air pressure
0.036
0.036
0.317
− 0.035
0.071
0.618
− 0.006
0.034
0.864
− 0.052
0.045
0.248
Coarse particles
0.065
0.026
0.013
0.048
0.071
0.496
0.087
0.036
0.017
0.037
0.020
0.058
 Intercept
− 40.870
37.408
0.275
42.374
70.477
0.548
− 2.956
35.372
0.933
34.113
42.135
0.418
 Temperature
0.103
0.034
0.003
0.035
0.051
0.500
0.042
0.033
0.212
0.096
0.052
0.066
 Relative humidity
0.014
0.015
0.349
0.033
0.028
0.227
0.007
0.015
0.647
0.042
0.029
0.146
 Wind speed
0.909
0.555
0.101
− 0.155
0.330
0.640
0.185
0.358
0.606
0.631
0.496
0.203
 Air pressure
0.037
0.036
0.299
− 0.044
0.071
0.537
0.003
0.034
0.933
− 0.037
0.041
0.361
Protein (coarse particles)
− 4.194
2.563
0.102
− 0.635
2.404
0.792
− 1.318
0.909
0.147
5.056
2.264
0.026
 Intercept
− 6.415
42.314
0.879
29.896
71.928
0.678
13.038
33.558
0.698
41.434
41.091
0.313
 Temperature
0.106
0.033
0.001
0.052
0.049
0.295
0.044
0.033
0.185
0.114
0.052
0.028
 Relative humidity
0.002
0.014
0.867
0.038
0.030
0.216
< 0.001
0.015
0.983
0.036
0.028
0.205
 Wind speed
0.609
0.551
0.269
− 0.165
0.359
0.646
0.256
0.355
0.471
0.361
0.467
0.440
 Air pressure
0.006
0.041
0.892
− 0.031
0.072
0.663
− 0.012
0.033
0.716
− 0.044
0.040
0.272
Endotoxin (coarse particles)
9.069
32.095
0.778
45.832
26.900
0.088
10.432
15.789
0.509
311.199
208.761
0.136
 Intercept
− 34.800
38.148
0.362
18.278
70.654
0.796
9.706
34.671
0.780
56.880
44.515
0.201
 Temperature
0.094
0.035
0.007
0.019
0.049
0.706
0.018
0.037
0.619
0.059
0.058
0.314
 Relative humidity
0.006
0.014
0.677
0.022
0.028
0.434
− 0.005
0.015
0.731
0.046
0.029
0.112
 Wind speed
0.657
0.545
0.228
− 0.315
0.362
0.384
0.243
0.359
0.498
0.254
0.485
0.600
 Air pressure
0.033
0.037
0.370
− 0.018
0.071
0.799
− 0.008
0.034
0.813
− 0.059
0.043
0.171
Coef regression coefficient, SE standard error of the regression
Statistically significant, p < 0.05

Discussion

In this study, we collected fine and coarse airborne particles in Kyoto City for 77 weeks (21 months), analyzed protein and endotoxin concentrations, and investigated the association of these concentrations, temperature, relative humidity, wind speed, and air pressure with the number of emergency department visits for asthma. We found that the concentrations of coarse particles and endotoxin in fine and coarse particles were significantly positively correlated with the number of emergency department visits in a generalized linear model to fit a Poisson regression to adjust for meteorological factors (Table 4). To our knowledge, this is the first report to show that atmospheric endotoxin is significantly associated with asthma exacerbation in Japan.
Many studies have examined the relationship between exposure to fine and coarse particles and asthma, but their results have not been consistent. Some studies have reported a significant association between exposure to these particles and an increased risk of clinic visits and hospitalization for asthma, whereas others have found no significant association [1, 2, 5]. These results suggest that the constituents of airborne particles cause the exacerbation of asthma and that diversity among these constituents may result in inconsistencies regarding the health effects. In the present study, the concentrations of airborne fine particles and protein in particles were not significantly associated with the number of emergency department visits for asthma in the case of the whole study period (Table 4). Asthma is an allergic disease, and there are several reports on allergic proteins originating from pollen and fungi in outdoor air [6, 7]. In addition, various materials such as animal dander, as well as activities such as the combustion of organic materials, are also potential sources of protein in outdoor air [8, 10, 21, 22]. Kang et al. analyzed the protein and other constituents in airborne particles collected in Hefei, China, and concluded that anthropogenic activities and biomass combustion were the main sources of protein in the outdoor air in the study area [8]. In a previous study, we found that the concentration of protein in fine particles was higher than that in coarse particles in Sasebo, Nagasaki, Japan, and that the protein concentration was positively associated with the concentrations of combustion products (nitrate and sulfate ions), indicating that the combustion of organic materials may be a source of protein. In this study, the concentration of protein in fine particles was higher than that in coarse particles collected in Kyoto (Additional file 1: Figure S2). These results suggest that the protein detected in this study may have originated from the combustion of organic materials and that the chemical structures of the proteins were altered by heat and photochemical reactions during transportation in the atmosphere and had lost their biological activity.
In this study, endotoxins in fine and coarse particles were significantly correlated with the number of emergency department visits for asthma. Endotoxin inhalation in a challenge setting induced the hallmarks of asthma, bronchoconstriction, airway inflammation, and bronchial hyper-responsiveness [23, 24]. The Institute of Medicine reviewed articles published from 2000 to 2013 on indoor environmental exposure and exacerbation of asthma, concluding that there was sufficient evidence of an association between indoor exposure to endotoxins and the exacerbation of asthma [25]. However, the association between endotoxin in outdoor air and the exacerbation of asthma is unclear. Endotoxins are the major component of the outer membrane of Gram-negative bacteria. Park et al. reported that the abundance of bacteria on airborne particles increases on Asian dust days in Osaka, Japan, and that several classes of Gram-negative bacteria are dominant [26]. Asian dust are soil particles that are carried eastward by winds from arid and semiarid areas of northern China and Mongolia. Asian dust events are mainly observed in the spring and autumn in Japan [27]. Ichinose et al. detected endotoxins in soil samples collected from Asian dust source regions [28]. In this study period, Asian dust events were found on 6 days in February, March, April, and June by Japan Meteorological Agency, and endotoxin levels in particles collected for weeks including these days were high. In addition, high levels of endotoxin were detected in particles collected in autumn (Additional file 1: Figure S3). Further investigation is needed to determine the exact sources of endotoxins in airborne particles.
In the analysis considering the effects of seasonality (Table 5), the association of protein on emergency department visits for asthma was inconclusive; the regression coefficient of protein in fine particles was negative in summer, but that in coarse particles was positive in winter. To our knowledge, there were no reports on the atmospheric protein that improve asthmatic symptoms. The number of data in each season was small (12–22), and the inconsistency of the effects of protein may be caused by the insufficiency of data. Further sampling and analysis are necessary to confirm seasonal variation.
This study has several limitations. First, because we chose emergency department visits for asthma as a surrogate measurement for asthma exacerbation, the patients in this study may have had moderate to severe symptoms. This deviation of patients may have affected the association between environmental factors (particles, protein, and endotoxin) and the increased risk of asthma exacerbation. Second, we measured weekly levels of environmental factors and examined the association of these factors with emergency department visits for asthma, because the purpose of this study was to clarify the association for long term and daily measurement of these environmental factors was too laborious for long-term study. However, the levels of environmental factors may fluctuate every day. Therefore, further investigation using daily data should also be performed in the future. Third, we were unable to measure the effect of indoor endotoxin level on the exacerbation of asthma in this study. However, because endotoxin concentrations in indoor air are significantly correlated with those in outdoor air [29], we believe that the endotoxin concentration of outdoor air is a suitable surrogate for endotoxin in the environment in order to analyze its association with health effects in a large population study. Fourth, data were available for 21 months in this study; thus, more long-term study is necessary to clarify the seasonal patterns.

Conclusion

In this study, we found that atmospheric endotoxin was a significant factor on emergency department visits for asthma even after adjusting for meteorological factors. Endotoxin level was positively associated with the number of emergency department visits for asthma. In contrast, the association between atmospheric protein and asthma exacerbation was inconclusive. This is the first report on the association of atmospheric endotoxin and protein with asthma exacerbation. Further study is necessary to ascertain the effects of atmospheric endotoxin and protein on asthma exacerbation.

Funding

This study was supported by the Environment Research and Technology Development Fund (5-1453) of the Japanese Ministry of the Environment and JSPS KAKENHI grant number JP17k08396. MSK was granted a scholarship assistance (Rakuchu Kirita Scholarship) by the Rotary Club of Kyoto Rakuchu.

Availability of data and materials

The datasets used and analyzed in the current study are available from the corresponding author on reasonable request.
This study was approved by the ethics committee of Kyoto Pharmaceutical University (Approval No. 17-16-18) and Rakuwakai Otowa Hospital (Approval No. 16-018).
Not applicable.

Competing interests

The authors declare that they have no competing interests.

Publisher’s Note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Open AccessThis article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://​creativecommons.​org/​licenses/​by/​4.​0/​), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The Creative Commons Public Domain Dedication waiver (http://​creativecommons.​org/​publicdomain/​zero/​1.​0/​) applies to the data made available in this article, unless otherwise stated.
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Literatur
1.
Zheng XY, Ding H, Jiang LN, Chen SW, Zheng JP, Qiu M, et al. Association between air pollutants and asthma emergency room visits and hospital admissions in time series studies: a systematic review and meta-analysis. PLoS One. 2015;10(9):e0138146.CrossRefPubMedPubMedCentral
2.
Fan J, Li S, Fan C, Bai Z, Yang K. The impact of PM2.5 on asthma emergency department visits: a systematic review and meta-analysis. Environ Sci Pollut Res. 2016;23:843–50.CrossRef
3.
Nakamura T, Hashizume M, Ueda K, Shimizu A, Takeuchi A, Kubo T, et al. Asian dust and pediatric emergency department visits due to bronchial asthma and respiratory diseases in Nagasaki, Japan. J Epidemiol. 2016;26(11):593–601.CrossRefPubMed
4.
Ueda K, Nitta H, Odajima H. The effects of weather, air pollutants, and Asian dust on hospitalization for asthma in Fukuoka. Environ Health Prev Med. 2010;15:350–7.CrossRefPubMedPubMedCentral
5.
Atkinson RW, Anderson HR, Sunyer J, Ayres J, Baccini M, Vonk JM, Boumghar A, Forastiere F, Forsberg B, Touloumi G, Schwartz J, Katsouyanni K. Acute effects of particulate air pollution on respiratory admissions: results from APHEA 2 project. Am J Respir Crit Care Med. 2001;164:1860–6.CrossRefPubMed
6.
Vermani M, Vijayan VK, Menon B, Kausar MA, Agarwal MK. Physico-chemical and clinico-immunologic studies on the allergic significance of Aspergillus tamarii, a common airborne fungus. Immunobiology. 2011;216:393–401.CrossRefPubMed
7.
Parrado ZG, Gonzalez DF, Camazon B, Barrera RMV, Maray AMV, Asturias JA, et al. Molecular aerobiology – Plantago allergen Pla l 1 in the atmosphere. Ann Agric Environ Med. 2014;21(2):282–9.CrossRef
8.
Kang H, Xie Z, Hu Q. Ambient protein concentration in PM10 in Hefei, central China. Atmos Environ. 2012;54:73–9.CrossRef
9.
Schappi GF, Monn C, Wuthrich B, Wanner HU. Direct determination of allergens in ambient aerosols: methodological aspects. Int Arch Allergy Immunol. 1996;110:364–70.CrossRefPubMed
10.
Miguel AG, Cass GR, Glovsky MM, Weiss J. Allergens in paved road dust and airborne particles. Environ Sci Technol. 1999;33:4159–68.CrossRef
11.
Cheng JYW, Hui ELC, Lau PC. Bioactive and total endotoxins in atmospheric aerosols in the Pearl River Delta region, China. Atmos Environ. 2012;47:3–11.CrossRef
12.
Heinrich J, Pitz M, Bischof W, Krug N, Borm PJA. Endotoxin in fine (PM2.5) and coarse (PM2.5-10) particle mass of ambient aerosols. A temporo-spatial analysis. Atmos Environ. 2003;37:3659–67.CrossRef
13.
Nilsson S, Merritt AS, Bellander T. Endotoxins in urban air in Stockholm, Sweden. Atmos Environ. 2011;45:266–70.CrossRef
14.
Khan MS, Coulibaly S, Abe M, Furukawa N, Kubo Y, Nakaoji Y, et al. Seasonal fluctuation of endotoxin and protein concentrations in outdoor air in Sasebo, Japan. Biol Pharm Bull. 2018;41:115–22.CrossRefPubMed
15.
Thorne PS. Inhalation toxicology models of endotoxin- and bioaerosol-induced inflammation. Toxicology. 2000;152:13–23.CrossRefPubMed
16.
Rabinovitch N, Liu AH, Zhan L, Rodes CE, Foarde K, Dutton SJ, et al. Importance of the personal endotoxin cloud in school-age children with asthma. J Allergy Clin Immunol. 2005;116:1053–7.CrossRefPubMed
17.
Kitz R, Rose MA, Borgmann A, Schubert R, Zielen S. Systemic and bronchial inflammation following LPS inhalation in asthmatic and healthy subjects. J Endotoxin Res. 2006;12(6):367–74.CrossRefPubMed
18.
Chen CH, Xirasagar S, Lin HC. Seasonality in adult asthma admissions, air pollutants levels, and climate: a population-based study. J Asthma. 2006;43:287–92.CrossRefPubMed
19.
Abe T, Tokuda Y, Ohde S, Ishimatsu S, Nakamura T, Birrer RB. The relationship of short-term air pollution and weather to ED visits for asthma in Japan. Am J Emerg Med. 2009;27(2):153–9.CrossRefPubMed
20.
21.
Castilloa JA, Statona SJR, Taylorb TJ, Herckesa P, Hayesa MA. Exploring the feasibility of bioaerosol analysis as a novel fingerprinting technology. Anal Bioanal Chem. 2012;403(1):15–26.CrossRef
22.
Song T, Shan Wang S, Yingyi Zhang Y, Song J, Liu F, Fu P, et al. Proteins and amino acids in fine particulate matter in rural Guangzhou, Southern China: seasonal cycles, sources, and atmospheric processes. Environ Sci Technol. 2017;51:6773–81.CrossRefPubMed
23.
Mitchel O, Ginanni R, Bon BL, Content J, Duchateau J, Sergysels R. Inspiratory response to acute inhalation of endotoxin in asthmatic patients. Am Rev Respir Dis. 1992;146:352–7.CrossRef
24.
Kline JN, Cowden JD, Huninghake GW, Schutte BC, Watt JL, Lelane CLW, et al. Variable airway responsiveness to inhaled lipopolysaccharide. Am J Respir Crit Care Med. 1999;160:297–303.CrossRefPubMed
25.
Kanchongkittiphone W, Mendell MJ, Gaffin JM, Wang G, Phipatanakul W. Indoor environmental exposures and exacerbation of asthma: an update to the 2000 review by the Institute of Medicine. Environ Health Perspect. 2015;123:6–19.CrossRef
26.
Park J, Ichijo T, Nasu M, Yamaguchi N. Investigation of bacterial effects of Asian dust events through comparison with seasonal variability in outdoor airborne bacterial community. Sci Rep. 2016;6:35706.CrossRefPubMedPubMedCentral
27.
28.
Ichinose T, Nishikawa M, Takano H, Sera N, Sadakane K, Mori I, et al. Pulmonary toxicity induced by intratracheal instillation of Asian yellow dust (Kosa) in mice. Environ Toxicol Pharmacol. 2005;20:48–56.CrossRefPubMed
29.
Yoda Y, Tamura K, Shima M. Airborne endotoxin concentrations in indoor and outdoor particulate matter and their predictors in an urban city. Indoor Air. 2017;27(5):955–64.CrossRefPubMed
Metadaten
Titel
Association of airborne particles, protein, and endotoxin with emergency department visits for asthma in Kyoto, Japan
verfasst von
Mohammad Shahriar Khan
Souleymane Coulibaly
Takahiro Matsumoto
Yoshitaka Yano
Makoto Miura
Yukio Nagasaka
Masayuki Shima
Nobuyuki Yamagishi
Keiji Wakabayashi
Tetsushi Watanabe
Publikationsdatum
01.12.2018
Verlag
BioMed Central
Erschienen in
Environmental Health and Preventive Medicine / Ausgabe 1/2018
Print ISSN: 1342-078X
Elektronische ISSN: 1347-4715
DOI
https://doi.org/10.1186/s12199-018-0731-2

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