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This commentary considers the long arc of lead (Pb) poisoning from antiquity to the 21st century. While Pb exposure is commonly attributed to paint or water, this article aims to discuss the underrecognized impacts of air Pb and soil Pb and to address controversial misconceptions related to these exposure sources. The Roman Aristocracy experienced lead poisoning mainly from the ingestion of foods, lead cookware, and lead-contaminated water and wine, but by the 20th century, lead exposure occurred by ingestion and inhalation. The introduction of tetraethyl lead (TEL) additives in gasoline was approved in 1925 in the US and produced an exponential increase in inhalable air lead exhaust particles through the 1970s. These five decades of widespread lead aerosol exposure were enabled by the Lead Industries Association (LIA), which confounded pediatricians, healthcare providers, and government agencies by promoting lead-based paint as the primary agent of childhood lead exposure. Empirical evidence of lead poisoning, environmental exposures, and proactive lead prevention in the general population was impossible until analytical instruments became commonly available for clinical studies and environmental measurements in the 1960s and 1970s. Soil studies in Baltimore, Maryland, beginning in the mid-1970s, indicated that lead particles exhausted from vehicles fueled by leaded gasoline excessively contaminated urban soils compared with non-urban soils. The invisible lead-contaminated air fouled multiple exposure routes via inhalation and ingestion. In addition to misunderstandings about sources of lead exposure, misinformation currently abounds regarding the timeline of banning lead in gasoline. The US Center for Disease Control (CDC) lists the ban as beginning in 1996. The banning of leaded gasoline first occurred in Japan starting in 1972, and after a 1984 Senate Hearing, the US Congress agreed on a rapid phasedown. A US Environmental Protection Agency (EPA) timeline confirmed that most leaded gasoline was banned by the end of 1986. Banning leaded gasoline was associated with sharp declines in the US population’s blood lead, which prompted global efforts to ban leaded gasoline. The eventual result was a complete global ban on highway use of leaded gasoline achieved in August 2021. Leaded gasoline is still used in piston-engine aircraft and the US EPA is proceeding to complete the ban on lead additives in fuel. Using precautionary principles to recover lead-contaminated urban environments and prevent new toxicant exposures are essential challenges and opportunities for present and future generations.
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Positive outcomes from U.S. lead regulations, continued challenges, and lessons learned for regulating emerging contaminants
Albeit slow and not without its challenges, lead (Pb) emissions and sources in the United States (U.S.) have decreased immensely over the past several decades. Despite the prevalence of childhood Pb poisoning throughout the twentieth century, most U.S. children born in the last two decades are significantly better off than their predecessors in regard to Pb exposure. However, this is not equal across demographic groups and challenges remain. Modern atmospheric emissions of Pb in the U.S. are nearly negligible since the banning of leaded gasoline in vehicles and regulatory controls on Pb smelting plants and refineries. This is evident in the rapid decrease of atmospheric Pb concentrations across the U.S. over the last four decades. One of the most significant remaining contributors to air Pb is aviation gasoline (avgas), which is minor compared to former Pb emissions. However, continual exposure risks to Pb exist in older homes and urban centers, where leaded paint and/or historically contaminated soils + dusts can still harm children. Thus, while effective in eliminating nearly all primary sources of Pb in the environment, the slow rate of U.S. Pb regulation has led to legacy sources of Pb in the environment. More proactive planning, communication, and research of commonly used emerging contaminants of concern that can persist in the environment long after their initial use (i.e., PFAS) should be prioritized so that the same mistakes are not made again.
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- Award ID(s):
- 2052589
- PAR ID:
- 10401278
- Date Published:
- Journal Name:
- Environmental Science and Pollution Research
- ISSN:
- 1614-7499
- Format(s):
- Medium: X
- Sponsoring Org:
- National Science Foundation
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- Free Publicly Accessible Full Text
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Accepted Manuscript1.0
- Journal Article:
- https://doi.org/10.1007/s11356-023-26319-4
