Department of Environmental and Occupational Health Sciences, School of Public Health, University of Washington, Hans Rosling Center for Population Health, 3980 15th Ave NE, Seattle, WA, 98195, USA.
Department of Civil & Environmental Engineering, College of Engineering, University of Washington, 201 More Hall, Box 352700, Seattle, WA, 98195, USA.
J Expo Sci Environ Epidemiol. 2023 May;33(3):465-473. doi: 10.1038/s41370-022-00470-5. Epub 2022 Aug 31.
Short-term mobile monitoring campaigns to estimate long-term air pollution levels are becoming increasingly common. Still, many campaigns have not conducted temporally-balanced sampling, and few have looked at the implications of such study designs for epidemiologic exposure assessment.
We carried out a simulation study using fixed-site air quality monitors to better understand how different short-term monitoring designs impact the resulting exposure surfaces.
We used Monte Carlo resampling to simulate three archetypal short-term monitoring sampling designs using oxides of nitrogen (NOx) monitoring data from 69 regulatory sites in California: a year-around Balanced Design that sampled during all seasons of the year, days of the week, and all or various hours of the day; a temporally reduced Rush Hours Design; and a temporally reduced Business Hours Design. We evaluated the performance of each design's land use regression prediction model.
The Balanced Design consistently yielded the most accurate annual averages; while the reduced Rush Hours and Business Hours Designs generally produced more biased results.
A temporally-balanced sampling design is crucial for short-term campaigns such as mobile monitoring aiming to assess long-term exposure in epidemiologic cohorts.
Short-term monitoring campaigns to assess long-term air pollution trends are increasingly common, though they rarely conduct temporally balanced sampling. We show that this approach produces biased annual average exposure estimates that can be improved by collecting temporally-balanced samples.
短期移动监测活动越来越多地用于估算长期空气污染水平。尽管如此,许多活动并未进行时间平衡采样,而且很少有研究关注此类研究设计对流行病学暴露评估的影响。
我们使用固定站点空气质量监测器进行了一项模拟研究,以更好地了解不同的短期监测设计如何影响最终的暴露面。
我们使用蒙特卡罗重采样技术,根据加利福尼亚州 69 个监管站点的氮氧化物(NOx)监测数据,模拟了三种典型的短期监测采样设计:全年平衡设计,在一年中的所有季节、每周的天数以及每天的所有或部分小时进行采样;时间缩短的高峰时段设计;以及时间缩短的工作日设计。我们评估了每种设计的土地使用回归预测模型的性能。
平衡设计始终产生最准确的年度平均值;而减少的高峰时段和工作日设计通常会产生更有偏差的结果。
对于旨在评估流行病学队列中长期暴露的短期监测活动(如移动监测),时间平衡采样设计至关重要。
评估长期空气污染趋势的短期监测活动越来越常见,但它们很少进行时间平衡采样。我们表明,这种方法会产生有偏差的年度平均暴露估计值,通过采集时间平衡的样本可以改善这些估计值。