兰州市臭氧对儿童哮喘的短期影响及其季节性差异

doi:10.19723/j.issn.1671-167X.2022.02.005

摘要/Abstract

摘要：

目的: 分析不同季节不同度量方式的臭氧(ozone, O₃)浓度对儿童哮喘门诊就诊人次的影响,探讨该影响在不同类型人群中的差异。方法: 收集兰州市三所三级甲等综合医院2014年1月1日至2017年12月31日儿童哮喘门诊的就诊资料,收集同期空气污染数据和气象数据,考虑到O₃浓度与儿童哮喘门诊就诊人次及气象因素之间的非线性关系,利用广义相加时间序列模型分析O₃浓度变化与儿童哮喘门诊就诊人次的短期关联性,同时进一步对性别、年龄进行分层分析,考虑到O₃在1 d内浓度变化情况,同时采用每日1 h最大值浓度(O₃max1h)、每日8 h最大值浓度(O₃8h)以及每日24 h均值浓度(O₃24h)这三种O₃暴露的不同度量方式作为O₃短期暴露指标,并分别开展模型分析。结果: 夏季时,O₃短期暴露水平的升高对于儿童哮喘门诊就诊人次的增加有显著影响。在滞后当天(lag0)的情况下,大气O₃max1h浓度每增加10 μg/m³,儿童哮喘门诊就诊人次增加3.351% (95%CI:1.231%~5.516%);O₃8h浓度每增加10 μg/m³,儿童哮喘门诊就诊人次增加3.320% (95%CI:0.197%~3.829%);O₃24h浓度每增加10 μg/m³,夏季儿童哮喘门诊就诊人次增加6.600% (95%CI:0.914%~12.607%);此外,O₃max1h暴露增加也会引起0~5岁儿童及男性哮喘门诊就诊人次的显著增加。结论: 兰州市夏季时O₃短期暴露水平的升高对于儿童哮喘门诊就诊风险的增加有显著影响,O₃max1h与儿童哮喘门诊就诊人次增加的关联更密切。

关键词: 臭氧, 空气污染物, 儿童, 哮喘, 门诊病人

Abstract:

Objective: To analyze the effects of ozone (O₃) concentrations measured with different approaches across different seasons on the total number of childhood asthma-related clinical visits, as well as the differentiation of such effects across different groups of patients. Methods: The outpatient data of three grade A tertiary hospitals in Lanzhou City spanning from 1 January 2014 to 31 December 2017, as well as air pollution and meteorological data during the same period were collected. Considering the nonlinear relationship between O₃ concentrations and the total number of childhood asthma-related clinical visits and meteorological factors, a generalized additive temporal sequence model was employed to analyze the short-term association between changes in O₃ concentrations and the total number of childhood asthma-related clinical visits. Taking into account of the variations in O₃ concentrations within 1 day, this study adopted different measurement approaches to address the three types of O₃ exposures, namely, the maximum 1 h daily concentration (O₃max1h), the maximum 8 h daily concentration (O₃8h) and the mean 24 h daily concentration (O₃24h) as the short term exposure indicators to O₃, followed by a model-based analysis. Results: The increase in short-term exposure levels to O₃ in summer had a significant effect on the increase in the total number of childhood asthma-related clinical visits. With lag0 for the current day, every 10 μg/m³ increase in atmospheric concentration of O₃max1h was associated with an increase in the total number of childhood asthma-related clinical visits by 3.351% (95%CI: 1.231%-5.516%); for every 10 μg/m³ increase in O₃8h concentration, the total number of childhood asthma-related clinical visits increased by 3.320% (95%CI: 0.197%-3.829%); for every 10 μg/m³increase in O₃24h concentration, the total number of childhood asthma-related clinical visits in summer increased by 6.600% (95%CI: 0.914%-12.607%); moreover, an increase in exposure to O₃max1h also led to a significant rise in the total number of childhood asthma-related clinical visits among the males. Conclusion: The increase in short-term exposure levels to O₃ in summer in Lanzhou City has a significant effect on the increase in the total number of childhood asthma-related clinical visits; O₃max1h is more closely correlated with the increase in the total number of childhood asthma-related clinical visits.

Key words: Ozone, Air pollutants, Child, Asthma, Outpatients

中图分类号:

R725.6

张宏,董继元,王建军,范临夏,曲强,刘洋. 兰州市臭氧对儿童哮喘的短期影响及其季节性差异[J]. 北京大学学报（医学版）, 2022, 54(2): 227-235.

ZHANG Hong,DONG Ji-yuan,WANG Jian-jun,FAN Lin-xia,QU Qiang,LIU Yang. Short-term effects and seasonal variation of ozone on daily hospital outpatient visits for childhood asthma in Lanzhou[J]. Journal of Peking University (Health Sciences), 2022, 54(2): 227-235.

图/表 11

表1

2014—2017年兰州市儿童哮喘日门诊就诊人次的描述性分析"

Category	$x -$ ±s	Minimum	Percentile			Maximum
Category	$x -$ ±s	Minimum	P₂₅	P₅₀	P₇₅	Maximum
0-14 years	6±3	1	3	5	7	31
Male	4±2	1	2	3	5	20
Female	2±1	1	1	2	3	12
0-5 years	4±2	1	2	3	5	15
6-14 years	2±1	1	1	2	4	17
Spring	4±2	1	2	4	6	18
Summer	6±4	1	3	5	8	22
Autumn	5±3	1	3	5	8	31
Winter	3±1	1	2	4	6	14

表1

表2

2014—2017年兰州市气象因素各指标和空气污染物的描述性分析"

Category	$x -$ ±s	Minimum	Percentile			Maximum
Category	$x -$ ±s	Minimum	P₂₅	P₅₀	P₇₅	Maximum
Meteorological factors
Temperature/℃	11.28±9.64	-12.30	2.45	12.90	19.80	29.90
Relative humidity/%	50.83±15.15	18.00	39.00	50.02	61.74	96.09
Air pollutants
PM_2.5/(μg/m³)	53.30±27.19	12.73	35.40	45.69	63.59	269.43
PM₁₀/(μg/m³)	122.90±78.25	18.98	81.00	107.94	145.25	1484.54
SO₂/(μg/m³)	22.39±14.47	3.54	10.88	18.29	30.42	81.87
NO₂/(μg/m³)	45.98±15.74	7.80	36.40	45.36	52.90	146.60
CO/(mg/m³)	1.34±0.73	0.34	0.83	1.09	1.62	4.65

表2

表3

2014—2017年兰州市臭氧浓度不同度量方式的描述性分析"

Category	$x -$ ±s	Minimum	Percentile			Maximum
Category	$x -$ ±s	Minimum	P₂₅	P₂₅	P₂₅	Maximum
O₃max1h/(μg/m³)	77.59±33.44	15.00	57.20	69.40	82.40	252.60
Spring	83.38±33.80	36.50	62.00	72.60	86.90	197.80
Summer	87.28±41.93	28.40	63.20	71.00	87.50	252.60
Autumn	73.15±28.77	15.00	54.40	68.00	82.80	195.20
Winter	66.29±21.59	15.80	52.20	62.00	77.20	158.60
O₃8h/(μg/m³)	84.03±36.53	8.00	56.00	78.00	106.00	221.00
Spring	99.23±32.82	20.00	78.00	98.00	118.00	221.00
Summer	104.43±39.93	10.00	76.00	103.00	134.00	197.00
Autumn	72.02±29.93	8.00	51.00	67.00	87.00	182.00
Winter	59.94±19.88	15.00	46.00	58.00	71.00	140.00
O₃24h/(μg/m³)	38.70±19.97	4.94	24.52	33.96	48.31	126.11
Spring	44.81±20.36	14.30	29.18	40.60	56.59	116.26
Summer	48.36±22.78	17.23	32.22	40.61	56.21	126.11
Autumn	31.42±14.5	8.03	20.75	28.51	38.01	84.56
Winter	29.91±13.74	4.94	19.17	26.96	38.25	78.58

表3

表4

表5

表6

表7

表8

表9

表10

表11

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Lag days	ER (95%CI)
Lag days	Spring	Summer	Autumn	Winter
Lag0	1.358 (0.126 to 2.606)^*	3.351 (1.231 to 5.516)^*	2.359 (1.052 to 3.683)^*	1.972 (0.484 to 3.482)^*
Lag1	0.233 (-0.978 to 1.458)	-1.312 (-3.078 to 0.486)	-1.868 (-3.180 to 0.539)	-0.878 (-2.268 to 0.531)
Lag2	-0.122 (-1.377 to 1.149)	-0.450 (-1.961 to 1.084)	-1.431 (-2.776 to 0.068)	0.229 (-1.152 to 1.630)
Lag3	-1.070 (-2.429 to 0.308)	0.136 (-1.504 to 1.803)	-0.311 (-1.606 to 1.002)	-1.055 (-2.613 to 0.529)
Lag4	-0.024 (-1.257 to 1.225)	-0.662 (-2.318 to 1.022)	0.035 (-1.287 to 1.375)	0.626 (-0.837 to 2.110)
Lag5	0.542 (-0.744 to 1.844)	1.419 (-0.164 to 3.027)	-0.191 (-1.537 to 1.175)	-0.136 (-1.543 to 1.291)
Lag6	0.301 (-0.906 to 1.523)	0.491 (-1.216 to 2.227)	-0.131 (-1.496 to 1.253)	-0.932 (-2.349 to 0.506)
Lag7	0.474 (-0.832 to 1.797)	-2.552 (-4.981 to 0.062)	-0.740 (-2.037 to 0.575)	0.506 (-1.054 to 2.090)
Lag01	1.536 (-0.163 to 3.264)	0.929 (-1.510 to 3.428)	-2.687 (-4.375 to 0.969)	0.814 (-1.030 to 2.694)
Lag02	1.961 (-0.216 to 4.186)	0.304 (-2.679 to 3.379)	-2.884 (-4.943 to 0.779)	0.884 (-1.221 to 3.033)
Lag03	1.419 (-1.192 to 4.100)	0.528 (-3.179 to 4.377)	-3.018 (-5.423 to 0.551)	0.270 (-2.221 to 2.824)
Lag04	1.347 (-1.671 to 4.457)	-0.656 (-5.24 to 4.149)	-1.678 (-4.610 to 1.344)	1.293 (-2.044 to 4.743)
Lag05	2.298 (-1.314 to 6.043)	1.651 (-4.132 to 7.782)	-2.068 (-5.560 to 1.552)	1.399 (-2.970 to 5.964)
Lag06	1.769 (-2.055 to 5.743)	3.614 (-3.852 to 11.659)	-2.254 (-6.414 to 2.092)	-0.008 (-5.804 to 6.145)
Lag07	0.982 (-2.616 to 4.712)	1.127 (-7.630 to 10.714)	-3.721 (-8.703 to 1.533)	0.765 (-6.056 to 8.082)

Lag days	ER (95%CI)
Lag days	Spring	Summer	Autumn	Winter
Lag0	-0.383 (-1.579 to 0.828)	3.320 (0.197 to 3.829)^*	0.552 (-1.149 to 2.283)	-2.203 (-3.787 to -0.593)
Lag1	0.360 (-0.855 to 1.590)	-1.689 (-3.761 to 0.428)	0.046 (-1.53 to 1.648)	-0.232 (-1.869 to 1.432)
Lag2	-1.449 (-2.869 to -0.008)	-1.106 (-3.083 to 0.912)	0.272 (-1.324 to 1.895)	1.171 (-0.359 to 2.724)
Lag3	0.590 (-0.805 to 2.005)	1.074 (-1.636 to 3.860)	-0.511 (-2.148 to 1.154)	0.166 (-1.401 to 1.757)
Lag4	1.367 (-0.001 to 2.753)	2.747 (-1.046 to 6.685)	0.299 (-1.281 to 1.903)	0.762 (-0.767 to 2.315)
Lag5	-0.400 (-1.672 to 0.888)	-3.538 (-7.437 to 0.525)	0.261 (-1.279 to 1.825)	-0.841 (-2.353 to 0.695)
Lag6	0.313 (-0.91 to 1.552)	-0.361 (-4.213 to 3.646)	0.273 (-1.242 to 1.811)	-0.362 (-1.941 to 1.243)
Lag7	0.060 (-1.497 to 1.641)	-0.597 (-4.584 to 3.557)	1.038 (-0.566 to 2.667)	-0.895 (-2.404 to 0.637)
Lag01	0.251 (-1.248 to 1.772)	0.542 (-2.186 to 3.346)	0.550 (-1.652 to 2.801)	-2.429 (-4.610 to 0.197)
Lag02	0.575 (-1.169 to 2.349)	-0.559 (-4.371 to 3.406)	0.813 (-1.801 to 3.496)	-1.481 (-4.234 to 1.35)
Lag03	0.052 (-2.056 to 2.206)	1.880 (-3.507 to 7.568)	0.822 (-2.172 to 3.907)	-2.040 (-5.409 to 1.448)
Lag04	0.140 (-2.718 to 3.081)	2.916 (-2.582 to 8.724)	1.124 (-2.367 to 4.74)	-2.219 (-6.268 to 2.004)
Lag05	0.864 (-2.969 to 4.848)	0.377 (-5.828 to 6.991)	1.251 (-2.773 to 5.441)	-4.524 (-9.092 to 0.274)
Lag06	-2.218 (-6.916 to 2.716)	-1.961 (-8.973 to 5.591)	1.300 (-3.317 to 6.137)	-5.045 (-10.445 to 0.680)
Lag07	-2.271 (-7.518 to 3.273)	-3.019 (-11.132 to 5.835)	2.307 (-3.077 to 7.990)	-6.712 (-8.969 to 0.050)

Lag days	ER (95%CI)
Lag days	Spring	Summer	Autumn	Winter
Lag0	-1.055 (-2.897 to 0.821)	6.600 (0.914 to 12.607)^*	1.752 (-0.647 to 4.209)	-2.261 (-6.110 to 1.745)
Lag1	-0.498 (-2.373 to 1.413)	3.552 (-0.338 to 7.593)	-2.468 (-5.130 to 0.269)	-4.455 (-8.325 to 0.421)
Lag2	-1.088 (-3.358 to 1.236)	-2.162 (-5.842 to 1.662)	-0.634 (-3.473 to 2.289)	-0.220 (-3.861 to 3.559)
Lag3	-0.751 (-2.996 to 1.546)	-0.539 (-4.299 to 3.369)	2.593 (-1.779 to 7.160)	1.874 (-1.838 to 5.726)
Lag4	-0.196 (-2.382 to 2.038)	1.187 (-2.568 to 5.087)	3.030 (-2.183 to8.520)	2.030 (-1.794 to 6.004)
Lag5	-0.033 (-2.051 to 2.027)	-2.107 (-5.866 to 1.802)	3.273 (-2.055 to 8.891)	-0.651 (-4.319 to 3.156)
Lag6	1.091 (-0.798 to 3.016)	0.511 (-3.342 to 4.518)	1.103 (-4.161 to 6.656)	-2.145 (-5.963 to 1.829)
Lag7	1.067 (-1.232 to 3.418)	1.505 (-2.498 to 5.672)	-1.963 (-6.748 to 3.067)	-0.133 (-3.848 to 3.726)
Lag01	-0.509 (-2.745 to 1.779)	8.115 (-2.446 to 14.098)	-0.117 (-3.645 to 3.542)	-6.442 (-11.553 to 1.036)
Lag02	-0.801 (-3.425 to 1.895)	6.567 (-0.357 to 13.972)	-2.218 (-7.136 to 2.960)	-6.086 (-12.403 to 0.686)
Lag03	-1.475 (-4.674 to 1.831)	6.014 (-1.878 to 14.54)	-1.225 (-7.883 to 5.915)	-4.232 (-11.895 to 4.098)
Lag04	-1.773 (-5.757 to 2.38)	6.749 (-2.012 to 16.294)	-0.938 (-9.439 to 8.360)	-2.028 (-11.291 to 8.204)
Lag05	-2.023 (-6.667 to 2.851)	3.623 (-6.055 to 14.299)	0.186 (-10.06 to 11.600)	-2.631 (-13.478 to 9.575)
Lag06	-1.232 (-6.561 to 4.400)	4.382 (-6.527 to 16.564)	2.964 (-10.017 to 17.817)	-6.308 (-12.75 to 8.038)
Lag07	0.816 (-5.114 to 7.117)	4.637 (-7.882 to 18.858)	-1.652 (-14.032 to 12.511)	-6.538 (-11.281 to 9.966)

Variables	ER(95%CI)
Variables	Spring	Summer	Autumn	Winter
Male	0.382 (-1.478 to 2.277)	1.997 (0.197 to 3.829)^*	4.877 (0.818 to 9.099)^*	2.030 (1.794 to 6.004)^*
Female	0.639 (-0.556 to 1.849)	1.752 (-0.647 to 4.209)	0.552 (-1.149 to 2.283)	0.762 (-0.767 to 2.315)
0-5 years	1.551 (-0.314 to 3.451)	3.351 (1.231 to 5.516)^*	5.805 (0.686 to 11.185)^*	2.162 (0.556 to 3.794)^*
6-14 years	-0.250 (-2.683 to 2.244)	2.945 (-0.033 to 6.012)	0.939 (-0.578 to 2.480)	1.367 (-3.392 to6.361)

Variables	ER(95%CI)
Variables	Spring	Summer	Autumn	Winter
Male	1.713 (-0.626 to 4.108)	1.973 (-1.581 to 5.656)	1.987 (-0.092 to 4.108)	1.215 (-0.825 to 3.297)
Female	0.486 (-2.410 to 3.468)	-1.249 (-5.536 to 3.232)	1.713 (-4.501 to 8.331)	-0.727 (-7.147 to 6.137)
0-5 years	0.226 (-1.662 to 2.150)	3.521 (0.806 to 6.309)^*	2.926 (1.250 to 4.629)^*	1.394 (-0.378 to 3.198)
6-14 years	1.669 (-0.135 to 3.506)	-0.606 (-3.688 to 2.574)	0.331 (-2.276 to 3.007)	0.973 (-1.884 to 3.913)