瑞士SAPALDIA地区二氧化氮、超细颗粒物、肺部沉积表面积及其他四种颗粒物污染标志物的土地利用回归模型开发。

Development of land use regression models for nitrogen dioxide, ultrafine particles, lung deposited surface area, and four other markers of particulate matter pollution in the Swiss SAPALDIA regions.

作者信息

Eeftens Marloes, Meier Reto, Schindler Christian, Aguilera Inmaculada, Phuleria Harish, Ineichen Alex, Davey Mark, Ducret-Stich Regina, Keidel Dirk, Probst-Hensch Nicole, Künzli Nino, Tsai Ming-Yi

机构信息

Department of Epidemiology and Public Health, Swiss Tropical & Public Health Institute, Socinstrasse 57, P.O. Box 4002, Basel, Switzerland.

University of Basel, Basel, Switzerland.

出版信息

Environ Health. 2016 Apr 18;15:53. doi: 10.1186/s12940-016-0137-9.

DOI:10.1186/s12940-016-0137-9

PMID:27089921

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4835865/

Abstract

BACKGROUND

Land Use Regression (LUR) is a popular method to explain and predict spatial contrasts in air pollution concentrations, but LUR models for ultrafine particles, such as particle number concentration (PNC) are especially scarce. Moreover, no models have been previously presented for the lung deposited surface area (LDSA) of ultrafine particles. The additional value of ultrafine particle metrics has not been well investigated due to lack of exposure measurements and models.

METHODS

Air pollution measurements were performed in 2011 and 2012 in the eight areas of the Swiss SAPALDIA study at up to 40 sites per area for NO2 and at 20 sites in four areas for markers of particulate air pollution. We developed multi-area LUR models for biannual average concentrations of PM2.5, PM2.5 absorbance, PM10, PMcoarse, PNC and LDSA, as well as alpine, non-alpine and study area specific models for NO2, using predictor variables which were available at a national level. Models were validated using leave-one-out cross-validation, as well as independent external validation with routine monitoring data.

RESULTS

Model explained variance (R(2)) was moderate for the various PM mass fractions PM2.5 (0.57), PM10 (0.63) and PMcoarse (0.45), and was high for PM2.5 absorbance (0.81), PNC (0.87) and LDSA (0.91). Study-area specific LUR models for NO2 (R(2) range 0.52-0.89) outperformed combined-area alpine (R (2) = 0.53) and non-alpine (R (2) = 0.65) models in terms of both cross-validation and independent external validation, and were better able to account for between-area variability. Predictor variables related to traffic and national dispersion model estimates were important predictors.

CONCLUSIONS

LUR models for all pollutants captured spatial variability of long-term average concentrations, performed adequately in validation, and could be successfully applied to the SAPALDIA cohort. Dispersion model predictions or area indicators served well to capture the between area variance. For NO2, applying study-area specific models was preferable over applying combined-area alpine/non-alpine models. Correlations between pollutants were higher in the model predictions than in the measurements, so it will remain challenging to disentangle their health effects.

摘要

背景

土地利用回归（LUR）是一种用于解释和预测空气污染浓度空间差异的常用方法，但针对超细颗粒物（如颗粒数浓度（PNC））的LUR模型尤为稀少。此外，此前尚未有针对超细颗粒物肺部沉积表面积（LDSA）的模型。由于缺乏暴露测量和模型，超细颗粒物指标的附加价值尚未得到充分研究。

方法

在瑞士SAPALDIA研究的八个区域于2011年和2012年进行了空气污染测量，每个区域多达40个站点用于测量二氧化氮，四个区域的20个站点用于测量颗粒物空气污染标志物。我们针对PM2.5、PM2.5吸光度、PM10、粗颗粒物、PNC和LDSA的半年平均浓度开发了多区域LUR模型，以及针对二氧化氮的高山、非高山和特定研究区域模型，使用国家层面可得的预测变量。模型通过留一法交叉验证以及利用常规监测数据进行独立外部验证。

结果

对于各种PM质量分数，模型解释方差（R²）适中，PM2.5为0.57，PM10为0.63，粗颗粒物为0.45，而对于PM2.5吸光度为0.81，PNC为0.87，LDSA为0.91。在交叉验证和独立外部验证方面，特定研究区域的二氧化氮LUR模型（R²范围为0.52 - 0.89）优于联合区域的高山模型（R² = 0.53）和非高山模型（R² = 0.65），并且能够更好地解释区域间的变异性。与交通和国家扩散模型估计相关的预测变量是重要的预测因子。

结论

所有污染物的LUR模型捕捉到了长期平均浓度的空间变异性，在验证中表现良好，并且可以成功应用于SAPALDIA队列。扩散模型预测或区域指标能够很好地捕捉区域间的差异。对于二氧化氮，应用特定研究区域模型优于应用联合区域的高山/非高山模型。模型预测中污染物之间的相关性高于测量值中的相关性，因此区分它们对健康的影响仍将具有挑战性。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/1b45/4835865/828bbab409c7/12940_2016_137_Fig1_HTML.jpg

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瑞士SAPALDIA地区二氧化氮、超细颗粒物、肺部沉积表面积及其他四种颗粒物污染标志物的土地利用回归模型开发。

Development of land use regression models for nitrogen dioxide, ultrafine particles, lung deposited surface area, and four other markers of particulate matter pollution in the Swiss SAPALDIA regions.

作者信息

机构信息

出版信息

BACKGROUND

METHODS

RESULTS

CONCLUSIONS

背景

方法

结果

结论

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