Blood lead level
Blood lead level (BLL), is a measure of lead in the blood. It is measured in micrograms of lead per deciliter of blood (μg/dL); 10 µg/dL is equivalent to 0.48 micromoles per liter (µmol/L).[1]
Preindustrial human BLL is estimated to have been 0.016 ug/dL, and has increased markedly in the aftermath of the industrial revolution. Today, BLL measurements from remote human populations have ranged from 0.8-3.2 ug/dL. Children in populations adjacent to industrial centers in developing countries often have average BLL measurements above 25 ug/dL. In developed countries, governments have sought to regulate lead use in paint, gasoline and other products, and successfully reduced average lead levels among children to below 10 ug/dL for most populations. Blood lead levels remain higher for children, for the poor, for minority or disenfranchised populations, and for people living in cities. The National Academies evaluated this issue in 1991 and confirmed that the blood lead level of the average person in the US was 300 - 500 times higher than that of preindustrial humans.
Lead is toxic and can cause neurological damage, especially among children, at any detectable level. High lead levels cause decreased vitamin D and haemoglobin synthesis, anemia, acute central nervous system disorders, and possibly death.[2]
The Centers for Disease Control changed its stance on blood lead levels in 2012. Previously, the CDC had identified a "blood lead level of concern" of 10 ug/dL, which many assumed meant the CDC was saying a test showing a BLL below 10 ug/dL was in some way "safe". The CDC became concerned about mounting evidence showing that even lower blood lead levels can cause lifelong health effects. Researchers are not finding a threshold level below which lead in blood is "safe". The CDC now publishes a "reference" blood lead level which they hope they can ratchet downward in coming years. The CDC wants to identify children who have higher BLLs than almost all of their peers, so that parents, doctors, public health officials, and communities will take action. The "reference" level is to be recalculated every four years. The present level is 5 ug/dL. As the average BLL of US children declines, so will the "reference" level. The goal is to reduce the level of lead in the blood of children to as low a level as possible.
Historical trends
Prior to the industrial revolution human BLL is estimated to have been far less than it is today. Bone lead measurements from two native American populations living on the Pacific coast and the Colorado river between 1000-1300 A.D. show that BLLs would have been approximately 0.016 ug/dL.[3][4] The World Health Organization and others interpret these measurements to be broadly representative of human preindustrial BLL.[2]
Contemporary human BLLs in remote locations are estimated to be 0.8 and 3.2 ug/dL in the southern and northern hemispheres, respectively.[2][3] Blood lead levels 50-1000 times higher than preindustrial levels are commonly measured in contemporary human populations around the world.[2]
Demographic and geographic patterns
Blood lead levels are highest in countries where lead is added to petrol of gasoline, where lead is used in paint soldered products, in urban areas, in areas adjacent to high road traffic, and in developing countries.[2] In Jamaica, 44% of children living near lead production facilities had BLLs above 25 ug/dL. In Albania, 98% of preschool children and 82% of schoolchildren had BLLs above 10 ug/dL; preschoolers living near a battery factory had average BLLs of 43 ug/dL. In China, 50% of children living in rural areas had BLLs above 10 ug/dL, and children living near sites of industry and high traffic had average BLLs ranging from 22 to 68 ug/dL.[2]
BLL measurements from developed countries decreased markedly beginning in the late 1970s, when restrictions were placed upon lead use in gasoline, petrol, paint, soldering material and other products. In the United States, average BLLs measured among tens of thousands of subjects declined from 12.8 to 2.8 ug/dL between 1976 and 1991.[2] In the 1990s, BLLs of children in Australia were measured to be 5 ug/dL, and 9 ug/dL in Barcelona, Spain.[2]
In the United States, blood lead levels remain highest for children, for people in urban centers, for people of lower socioeconomic status, and for minorities.[5]
Sources
Exposure to lead occurs through ingestion, inhalation, and dermal contact. When exposed to lead, lead enters one’s bloodstream and elevates their blood lead level that results to lead poisoning or an elevated blood lead level.[6] A major source of exposure to lead comes from inhalation. Factories and industries, vehicles exhausts, and even dust in the air that people breathe all have the potential of containing lead. Other major sources of lead exposure also include ingestion and contact with products such as paint and soil that may contain lead as well. Many older claw foot bathtubs have also been found to leach lead, especially when filled with warm bath water.[7]
Health effects
The Centers for Disease Control and Prevention (CDC) states that a BLL of 5 μg/dL or above is a cause for concern in children. However, lead can impair development even at BLLs below 5 μg/dL.[8] Adults that are exposed to a dangerous amount of lead can experience anemia, nervous system dysfunction, weakness, hypertension, kidney problems, decreased fertility and increased level of miscarriages, and low birth weight and premature deliveries.[7] Children exposed to high levels of lead show similar symptoms, including anemia, kidney damage, colic, neurological impairment, and impaired vitamin D metabolism.[7] However children are susceptible to damage from lead exposure at lower levels than adults, and neurological impairment can occur in children with blood lead levels <10 µg/dL. Neurological impairment or delay, growth retardation, and delayed sexual maturation as a result of lead exposure may even affect children as they mature to adulthood.[7]
See also
Notes
- ^ http://www.health.nsw.gov.au/publichealth/chorep/env/env_pbhem.asp[dead link] Government of New South Wales, Australia: Blood lead levels in Broken Hill children
- ^ a b c d e f g h Tong, Shilu; von Schimding, Yasmine; Prapamontol, Tippawan (2000). "Environmental lead exposure: a public health problem of global dimensions". Bulletin of the World Health Organization. 78.
{{cite journal}}:|access-date=requires|url=(help) - ^ a b Patterson, Clair; Ericson, Jonathan; Mirela, Manea-Krichten; Shirahata, Hiroshi (1991). "Natural skeletal levels of lead in Homo sapiens sapiens uncontaminated by technological lead". The Science of the Total Environment. 107: 205–236.
{{cite journal}}:|access-date=requires|url=(help) - ^ Flegal, A. Russell; Smith, Donald (1992). "Lead Levels in Preindustrial Humans". The New England Journal of Medicine. 326 (19): 1293–4.
{{cite journal}}:|access-date=requires|url=(help) - ^ Jones, Robert; Homa, David; Meyer, Pamela; Brody, Debra; Caldwell, Kathleen; Pirkle, James; Brown, Mary Jean (2009). "Trends in Blood Lead Levels and Blood Lead Testing Among US Children Aged 1 to 5 Years, 1988–2004". Pediatrics. 123 (3): e376.
{{cite journal}}:|access-date=requires|url=(help) - ^ Stellman, Jeanne Mager (1998). Encyclopaedia of Occupational Health and Safety. International Labour Organization. pp. 81.2–81.4.
- ^ a b c d Agency for Toxic Substances and Disease Registry (August 2007). "ATSDR Toxicological Profile for Lead" (PDF). Retrieved 2012-03-15.
- ^ http://www.nchh.org/Portals/0/Contents/CDC_Response_Lead_Exposure_Recs.pdf
References
- Kosnett MJ, Wedeen RP, Rothenberg SJ, Hipkins KL, Materna BL, Schwartz BS, et al. 2007. Recommendations for Medical Management of Adult Lead Exposure. Environ Health Perspect 115: pg.463-471.
- Shurke, Judy. "Adult Blood Lead Levels." SHARP. Washington State Department of Labor, 2010. Web. 14 Nov. 2010.
- Voorhis, Nancy. "Lead-Elevated Blood Lead Levels in Children." Virginia Department of Health. 14 Jan. 2008. Web. 14 Nov. 2010.