Using Community Science to Better Understand Lead Exposure Risks

Overview

Journal Geohealth

Date 2022 Apr 4

PMID 35372744

Authors

Matthew Dietrich

John T Shukle

Mark P S Krekeler

Leah R Wood

Gabriel M Filippelli

Affiliations

Soon will be listed here.

Abstract

Lead (Pb) is a neurotoxicant that particularly harms young children. Urban environments are often plagued with elevated Pb in soils and dusts, posing a health exposure risk from inhalation and ingestion of these contaminated media. Thus, a better understanding of where to prioritize risk screening and intervention is paramount from a public health perspective. We have synthesized a large national data set of Pb concentrations in household dusts from across the United States (U.S.), part of a community science initiative called "DustSafe." Using these results, we have developed a straightforward logistic regression model that correctly predicts whether Pb is elevated (>80 ppm) or low (<80 ppm) in household dusts 75% of the time. Additionally, our model estimated 18% false negatives for elevated Pb, displaying that there was a low probability of elevated Pb in homes being misclassified. Our model uses only variables of approximate housing age and whether there is peeling paint in the interior of the home, illustrating how a simple and successful Pb predictive model can be generated if researchers ask the right screening questions. Scanning electron microscopy supports a common presence of Pb paint in several dust samples with elevated bulk Pb concentrations, which explains the predictive power of housing age and peeling paint in the model. This model was also implemented into an interactive mobile app that aims to increase community-wide participation with Pb household screening. The app will hopefully provide greater awareness of Pb risks and a highly efficient way to begin mitigation.

Citing Articles

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Neighborhood-scale lead (Pb) speciation in Akron, Ohio (USA) soils: primary sources, post-deposition diagenesis, and high concentrations of labile Pb.

Santoro N, Singer D, Mulvey B, Halasa K, Teutsch N, Shedleski A Environ Geochem Health. 2024; 46(5):164.

PMID: 38592563 PMC: 11003916. DOI: 10.1007/s10653-024-01954-z.

Direct Environmental Lead Detection by Photoluminescent Perovskite Formation with Nanogram Sensitivity.

Helmbrecht L, van Dongen S, van der Weijden A, van Campenhout C, Noorduin W Environ Sci Technol. 2023; 57(49):20494-20500.

PMID: 38008908 PMC: 10720378. DOI: 10.1021/acs.est.3c06058.

Assessing lead exposure in U.S. pregnant women using biological and residential measurements.

Stanek L, Grokhowsky N, George B, Thomas K Sci Total Environ. 2023; 905:167135.

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Using Community Science to Better Understand Lead Exposure Risks.

Dietrich M, Shukle J, Krekeler M, Wood L, Filippelli G Geohealth. 2022; 6(2):e2021GH000525.

PMID: 35372744 PMC: 8859494. DOI: 10.1029/2021GH000525.

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