Within-City Variation in Ambient Carbon Monoxide Concentrations: Leveraging Low-Cost Monitors in a Spatiotemporal Modeling Framework

Background: Based on human and animal experimental studies, exposure to ambient carbon monoxide (CO) may be associated with cardiovascular disease outcomes, but epidemiological evidence of this link is limited. The number and distribution of ground-level regulatory agency monitors are insufficient to characterize fine-scale variations in CO concentrations. Objectives: To develop a daily, high-resolution ambient CO exposure prediction model at the city scale. Methods: We developed a CO prediction model in Baltimore, Maryland, based on a spatiotemporal statistical algorithm with regulatory agency monitoring data and measurements from calibrated low-cost gas monitors. We also evaluated the contribution of three novel parameters to model performance: high-resolution meteorological data, satellite remote sensing data, and copollutant (PM2.5, NO2, and NOx) concentrations. Results: The CO model had spatial cross-validation (CV) R2 and root-mean-square error (RMSE) of 0.70 and 0.02 parts per million (ppm), respectively; the model had temporal CV R2 and RMSE of 0.61 and 0.04 ppm, respectively. The predictions revealed spatially resolved CO hot spots associated with population, traffic, and other nonroad emission sources (e.g., railroads and airport), as well as sharp concentration decreases within short distances from primary roads. Discussion: The three novel parameters did not substantially improve model performance, suggesting that, on its own, our spatiotemporal modeling framework based on geographic features was reliable and robust. As low-cost air monitors become increasingly available, this approach to CO concentration modeling can be generalized to resource-restricted environments to facilitate comprehensive epidemiological research. https://doi.org/10.1289/EHP10889

[1]  A. Szpiro,et al.  Insights from Application of a Hierarchical Spatio-Temporal Model to an Intensive Urban Black Carbon Monitoring Dataset. , 2022, Atmospheric environment.

[2]  M. Chin,et al.  New seasonal pattern of pollution emerges from changing North American wildfires , 2022, Nature Communications.

[3]  P. Sampson,et al.  Publicly available low-cost sensor measurements for PM2.5 exposure modeling: Guidance for monitor deployment and data selection. , 2021, Environment international.

[4]  Joshua P. Keller,et al.  Fine-Scale Air Pollution Models for Epidemiologic Research: Insights From Approaches Developed in the Multi-ethnic Study of Atherosclerosis and Air Pollution (MESA Air) , 2021, Current Environmental Health Reports.

[5]  Marina Zusman,et al.  Deployment, Calibration, and Cross-Validation of Low-Cost Electrochemical Sensors for Carbon Monoxide, Nitrogen Oxides, and Ozone for an Epidemiological Study , 2021, Sensors.

[6]  P. Fine,et al.  Responsive high-resolution air quality index mapping using model, regulatory monitor, and sensor data in real-time , 2020, Environmental Research Letters.

[7]  T. Borsdorff,et al.  1.5 years of TROPOMI CO measurements: comparisons to MOPITT and ATom , 2020 .

[8]  Xiaoting Liu,et al.  Low-cost sensors as an alternative for long-term air quality monitoring. , 2020, Environmental research.

[9]  Yi Liu,et al.  Satellite-Observed Variations and Trends in Carbon Monoxide over Asia and Their Sensitivities to Biomass Burning , 2020, Remote. Sens..

[10]  Howard H. Chang,et al.  Incorporating Low-Cost Sensor Measurements into High-Resolution PM2.5 Modeling at A Large Spatial Scale. , 2019, Environmental science & technology.

[11]  J. Salmond,et al.  Low-cost sensors and microscale land use regression: Data fusion to resolve air quality variations with high spatial and temporal resolution , 2019, Atmospheric Environment.

[12]  Alexei Lyapustin,et al.  Impacts of snow and cloud covers on satellite-derived PM2.5 levels. , 2019, Remote sensing of environment.

[13]  Daniel Coca,et al.  Analysing the performance of low-cost air quality sensors, their drivers, relative benefits and calibration in cities—a case study in Sheffield , 2019, Environmental Monitoring and Assessment.

[14]  Haili Hu,et al.  Mapping carbon monoxide pollution from space down to city scales with daily global coverage , 2018, Atmospheric Measurement Techniques.

[15]  Carl Malings,et al.  Development of a general calibration model and long-term performance evaluation of low-cost sensors for air pollutant gas monitoring , 2018, Atmospheric Measurement Techniques.

[16]  Geb Thomas,et al.  Evaluation of low-cost electro-chemical sensors for environmental monitoring of ozone, nitrogen dioxide, and carbon monoxide , 2018, Journal of occupational and environmental hygiene.

[17]  Brian K. Blaylock,et al.  Cloud archiving and data mining of High-Resolution Rapid Refresh forecast model output , 2017, Comput. Geosci..

[18]  C. Jang,et al.  A System for Developing and Projecting PM2.5 Spatial Fields to Correspond to Just Meeting National Ambient Air Quality Standards. , 2017, Atmospheric environment.

[19]  Laurent Francis,et al.  Assessment of air quality microsensors versus reference methods: The EuNetAir joint exercise , 2016 .

[20]  Haili Hu,et al.  Carbon monoxide total column retrievals from TROPOMI shortwave infrared measurements , 2016 .

[21]  J. Landgraf,et al.  High-resolution tropospheric carbon monoxide profiles retrieved from CrIS and TROPOMI , 2016 .

[22]  Yujie Wang,et al.  Assessing PM2.5 Exposures with High Spatiotemporal Resolution across the Continental United States. , 2016, Environmental science & technology.

[23]  Lianne Sheppard,et al.  Satellite-Based NO2 and Model Validation in a National Prediction Model Based on Universal Kriging and Land-Use Regression. , 2016, Environmental science & technology.

[24]  Casey Olives,et al.  Development of Long-term Spatiotemporal Models for Ambient Ozone in Six Metropolitan regions of the United States: The MESA Air Study. , 2015, Atmospheric environment.

[25]  Johan Lindström,et al.  A Unified Spatiotemporal Modeling Approach for Predicting Concentrations of Multiple Air Pollutants in the Multi-Ethnic Study of Atherosclerosis and Air Pollution , 2014, Environmental health perspectives.

[26]  P. Sampson,et al.  A flexible spatio-temporal model for air pollution with spatial and spatio-temporal covariates , 2014, Environmental and Ecological Statistics.

[27]  O. Hasekamp,et al.  CH4, CO, and H2O spectroscopy for the Sentinel-5 Precursor mission: an assessment with the Total Carbon Column Observing Network measurements , 2012 .

[28]  Jean-Noël Thépaut,et al.  The MACC reanalysis: an 8 yr data set of atmospheric composition , 2012 .

[29]  P. Sampson,et al.  Pragmatic Estimation of a Spatio-Temporal Air Quality Model With Irregular Monitoring Data , 2011 .

[30]  Johan Lindström,et al.  Comparing universal kriging and land-use regression for predicting concentrations of gaseous oxides of nitrogen (NOx) for the Multi-Ethnic Study of Atherosclerosis and Air Pollution (MESA Air). , 2011, Atmospheric environment.

[31]  Thomas Lumley,et al.  Predicting intra‐urban variation in air pollution concentrations with complex spatio‐temporal dependencies , 2009, Environmetrics.

[32]  Vlad Isakov,et al.  Traffic and Meteorological Impacts on Near-Road Air Quality: Summary of Methods and Trends from the Raleigh Near-Road Study , 2008, Journal of the Air & Waste Management Association.

[33]  Morton Lippmann,et al.  Acute respiratory health effects of air pollution on children with asthma in US inner cities. , 2008, The Journal of allergy and clinical immunology.

[34]  J. Sarnat,et al.  Multipollutant modeling issues in a study of ambient air quality and emergency department visits in Atlanta , 2007, Journal of Exposure Science and Environmental Epidemiology.

[35]  Michelle L. Bell,et al.  Ambient Air Pollution and Low Birth Weight in Connecticut and Massachusetts , 2007, Environmental health perspectives.

[36]  Andrea Polidori,et al.  Indoor/Outdoor Relationships, Trends, and Carbonaceous Content of Fine Particulate Matter in Retirement Homes of the Los Angeles Basin , 2007, Journal of the Air & Waste Management Association.

[37]  T. Woodruff,et al.  Relationships between air pollution and preterm birth in California. , 2006, Paediatric and perinatal epidemiology.

[38]  Joel Schwartz,et al.  The Effects of Air Pollution on Hospitalizations for Cardiovascular Disease in Elderly People in Australian and New Zealand Cities , 2006, Environmental health perspectives.

[39]  Joshua Millstein,et al.  Birth Outcomes and Prenatal Exposure to Ozone, Carbon Monoxide, and Particulate Matter: Results from the Children’s Health Study , 2005, Environmental health perspectives.

[40]  Francesca Dominici,et al.  Revised Analyses of the National Morbidity, Mortality, and Air Pollution Study: Mortality Among Residents Of 90 Cities , 2005, Journal of toxicology and environmental health. Part A.

[41]  Chun-Yuh Yang,et al.  Air pollution and hospital admissions for cardiovascular disease in Taipei, Taiwan. , 2005, Environmental research.

[42]  Edo D Pellizzari,et al.  Asthma symptoms in Hispanic children and daily ambient exposures to toxic and criteria air pollutants. , 2002, Environmental health perspectives.

[43]  W. Aronow,et al.  Effect of carbon monoxide on maximal treadmill exercise. A study in normal persons. , 1975, Annals of internal medicine.