Sources of Blood Lead in Children
Referencing: Seasonality and Children's Blood Lead Levels: Developing a Predictive Model Using Climatic Variables and Blood Lead Data from Indianapolis, Indiana, Syracuse, New York, and New Orleans, Louisiana (USA)
In their article on seasonality and children's blood lead (BPb) levels, Laidlaw et al. (2005) stated that "lead-contaminated soil in and of itself may be the primary driving mechanism of child BPb poisoning in the urban environment." We believe that the data presented by Laidlaw et al. (2005) do not support this conclusion and that they misrepresent the many other studies of childhood lead poisoning, which support a more comprehensive, validated approach.
To support their "soil-only" hypothesis, Laidlaw et al. (2005) made three primary arguments: a) soil lead represents a large and available reservoir of environmental lead; b) resuspension of lead from contaminated soil followed by inhalation of airborne particulate matter < 10 µm in diameter (PM10) and dust deposition on interior surfaces is the major source of lead exposure to children; and c) the major source of lead contaminated soil is fallout from the past use of tetraethyl lead in gasoline.
Laidlaw et al. (2005) did not cite the compelling body of scientific evidence demonstrating that deteriorated lead-based paint and the contaminated dust and soil it generates is highly correlated with BPb levels in children. These have been reviewed at length elsewhere (National Academy of Sciences 1993; Jacobs 1995; President's Task Force on Environmental Health Risks and Safety Risks to Children 2000). Indeed, Laidlaw et al. failed to recognize the enlightened statutory definition of the term "lead-based paint hazard," which includes not only deteriorated lead-based paint but also interior settled house dust and bare soil. Together, these constitute the principal exposure sources and pathways for most (but not all) children today (Residential Lead-Based Paint Hazard Reducation Act of 1992--Title X 1992). Furthermore, documented evidence shows that soil lead levels are highest in soil at the house drip line and greatly decrease farther away from the house, regardless of whether or not the house is in a rural area or city (Jacobs 1995).
Laidlaw et al. (2005) ignored confounding due to the coexistence of old, poorly maintained lead-painted housing and traffic congestion in urban areas. They failed to develop any rationale to exclude lead paint as a prominent source of lead exposure and should have included a measure of it in their models. Furthermore, they did not support their assumption that PM10 data can be used as a surrogate for airborne lead particulate. Laidlaw et al. should have used the more direct measures of airborne lead particulate levels, which are available from the U.S. Environmental Protection Agency's (EPA) National Ambient Air Quality program (U.S. EPA 2004), rather than the convoluted indirect measures of particulate matter < 10 µm in diameter (PM10), soil moisture, and other variables.
Studies of the effectiveness of soil removal in urban residential areas without addressing deteriorated lead paint have demonstrated that the "soil-only" approach being recommended by Laidlaw et al. (2005) is of limited value (U.S. EPA 1996). Even in Superfund sites where old mining and smelter wastes have resulted in very high soil lead levels, efforts that do not also address deteriorated lead paint often are disappointing. Furthermore, in the largest and most recent study of lead-based paint hazard control (which addressed lead paint hazards in > 3,000 homes in a dozen jurisdictions), house dust lead levels remained below preintervention levels for at least 3 years following the intervention (National Center for Healthy Housing and University of Cincinnati 2004). In a smaller follow-up study, dust lead levels remained between 11% and 75% lower than baseline levels for 6 years following lead-based paint hazard intervention (Wilson J, Pivetz T, Ashley P, Jacobs D, Strauss W, Menkedick J, et al., unpublished data). If the contention of Laidlaw et al. (2005) is correct (i.e., that urban soil lead is being resuspended and deposited inside homes), dust lead levels should have increased after intervention in these studies. In fact, they did not. This directly contradicts the authors' conclusions.
Finally, Laidlaw et al. (2005) erroneously cited a pooled analysis (Lanphear et al. 1998), which they believe supports their view that soil and dust lead are the most significant predictors of children's BPb. In fact, the model used in that study also included paint lead and paint condition as variables. If the dust and soil lead terms are forced out of the model, paint lead becomes the most significant predictor, which is consistent with the now well-known pathway of paint to settled house dust and bare soil, to children's hands, to ingestion through hand-to-mouth contact. The pooled analysis (co-authored by D.E.J.) cannot be used to justify Laidlaw et al.'s "soil-only" approach.
The latest figures from the National Health and Nutrition Examination Survey indicate that the enormous disparity in the prevalence of BPb levels > 10 µg/dL once seen between African-American and white children has diminished greatly [Centers for Disease Control and Prevention (CDC) 2005]. Overall, the number of children in the United States with excessive BPb levels has declined from 890,000 in 1991-1994 to 310,000 in 1999-2002. Much of this is the result of federal, state, and local efforts to create a reservoir of lead-safe housing in communities at greatest risk. This success is tempered by recent evidence that a safe BPb level for children has not been demonstrated. The lack of a safe threshold reinforces the realization that to prevent the adverse health effects caused by lead exposure, we must exercise the wisdom to recognize and address the many sources of lead in children's environments. The reality is too complicated and the cost of failure too devastating to reduce this to a one-source solution.
The authors declare they have no competing financial interests.
Mary Jean Brown
Lead Poisoning Prevention Branch
Centers for Disease Control and Prevention
Atlanta, Georgia
E-mail: mjb5@cdc.gov
David E. Jacobs
U. S. Department of Housing and Urban Development
Washington, DC
References
CDC (Centers for Disease Control and Prevention). 2005. Blood lead levels--United States, 1999-2002. MMWR Morb Mortal Wkly Rep 54:513-516.
Jacobs DE. 1995. Lead paint as a major source of childhood lead poisoning: a review of the evidence. In: Lead in Paint, Soil and Dust: Health Risks, Exposure Studies, Control Measures and Quality Assurance (Beard ME, Allen Iske SD, eds). ASTM STP 1226. Philadelphia:American Society for Testing and Materials.
Laidlaw MAS, Mielke HW, Filippelli GM, Johnson DL, Gonzales CR. 2005. Seasonality and children's blood lead levels: developing a predictive model using climatic variables and blood lead data from Indianapolis, Indiana, Syracuse, New York, and New Orleans, Louisiana (USA). Environ Health Perspect 113:793-800; doi:10.1289/ehp.7759 [Online 24 February 2005].
Lanphear BP, Matte TD, Rogers J, Clickner RP, Dietz B, Bornschein RL, et al. 1998. The contribution of lead-contaminated house dust and residential soil to children's blood lead levels: a pooled analysis of 12 epidemiological studies. Environ Res 79:51-68.
National Academy of Sciences. 1993. Measuring Lead Exposure in Infants, Children, and Other Sensitive Populations. Washington DC:National Academy Press.
National Center for Healthy Housing and University of Cincinnati. 2004. Evaluation of the HUD Lead-Based Paint Hazard Control Grant Program. Final Report. Washington, DC: U.S. Department of Housing and Urban Development. Aviailable: http://www.centerforhealthyhousing.org/HUD_National_Evaluation_Final_Report.pdf [accessed 21 June 2005].
President's Task Force on Environmental Health Risks and Safety Risks to Children. 2000. Eliminating Childhood Lead Poisoning: A Federal Strategy Targeting Lead Paint Hazards. Washington, DC: U.S. Department of Housing and Urban Development and U.S. Environmental Protection Agency. Available: http://www.hud.gov/offices/lead/reports/fedstrategy.cfm [accessed 5 December 2005].
Residential Lead-Based Paint Hazard Reducation Act of 1992--Title X. 1992. Public Law 102-550. Available: http://www.hud.gov/utilities/intercept.cfm?/offices/lead/regs/leatilex.pdf [accessed 5 December 2005].
U.S. EPA. 1996. Urban Soil Lead Abatement Demonstration Project: Vol I, EPA Integrated Report. EPA 600/P-93/001aF. Washington DC:U.S. Environmental Protection Agency.
U.S. EPA. 2004. The Particle Pollution Report: Current Understanding of Air Quality and Emissions through 2003. Washington DC:U.S. Environmental Protection Agency. EPA 454-R-04-002. Available: http://www.epa.gov/airtrends/pm.html [accessed 28 July 2005].
Blood Lead in Children: Laidlaw et al. Respond
Our article (Laidlaw et al. 2005) is about seasonality of blood lead (BPb) and developing a predictive model using climatic variables. It is a new and unique finding about lead, marked particularly by the fact that it identifies diffuse soil lead as a significant component of lead sources in urban children. In the article, we argued that meteorologic factors can be robustly applied as a predictor for seasonal variations in children's BPb, which can be used as a potential tool for health care clinicians in the fight to eliminate lead poisoning in youth. We did not intend to review the literature on lead sources; a vast literature already exists of such studies. Suggesting that we propose the "soil-only hypothesis" completely misconstrues our work.
Brown and Jacobs fail to appreciate our argument that lead accumulation in soil is from a combination of lead-based paint, leaded-gasoline, and many other sources, but is clearly not from lead-based paint alone. They fail to understand the fact that soil normally contains very small amounts of lead, and research from many cities has shown that there has been an excessive accumulation of lead in inner-cities (Filippelli et al. 2005; Mielke 2005). We acknowledge that multiple exposure routes for lead exist for children and likely influence the observed seasonality trends in BPb levels (Laidlaw et al. 2005). We seek to assist with scientific understanding of how and why inner-city children are commonly excessively exposed to lead, and we seek a solution to that problem.
We are concerned that people working at agencies that should champion the reduction of lead exposure do not appreciate the fact that multiple sources of lead have accumulated in urban environments and that all major sources and reservoirs need full attention if we expect to meet the goals of Healthy People 2010 (2005). Our work suggests that, to fully address the childhood lead exposure problem in the United States, a paradigm shift is required that includes all major reservoirs of active lead dust.
The authors declare they have no competing financial interest.
Mark A. S. Laidlaw
School of Population Health
University of Western Australia
Crawley, Western Australia
E-mail: mlaidlaw@sph.uwa.edu.au
Howard W. Mielke
Christopher R. Gonzalez
College of Pharmacy
Xavier University of Louisiana
New Orleans, Louisiana
Gabriel M. Filippelli
Department of Geology
Indiana University-Purdue University Indianapolis, Indiana
David L. Johnson
State University of New York
College of Environmental Science and Forestry
Syracuse, New York
References
References
Filippelli GM, Laidlaw M, Raftis R, Latimer JC. 2005. Urban lead poisoning and medical geology: an unfinished story. GSA Today 15:4-11; doi: 0.1130/1052-5173(2005)015<4:ULPAMG>2.0.CO;2.
Healthy People 2010. 2005. Healthy People 2010: What Are Its Goals? Available: http://www.healthypeople.gov/About/goals.htm/ [accessed 30 November 2005].
Mielke HW. 2005. Lead's toxic urban legacy and children's health. GeoTimes (May):22-26.
Laidlaw MAS, Mielke HW, Filippelli GM, Johnson DL, Gonzales CR. 2005. Seasonality and children's blood lead levels: developing a predictive model using climatic variables and blood lead data from Indianapolis, Indiana, Syracuse, New York, and New Orleans, Louisiana (USA). Environ Health Perspect 113:793-800; doi:10.1289/ehp.7759 [Online 24 February 2005].