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. 1996 Oct;104(10):1050–1054. doi: 10.1289/ehp.961041050

Results of lead research: prenatal exposure and neurological consequences.

R A Goyer 1
PMCID: PMC1469478  PMID: 8930545

Abstract

The history of advances in the understanding of the toxic effects of lead over the past 20 years is an outstanding example of how knowledge learned from research can impact public health. Measures that have had the greatest impact on reducing exposure to lead are reduction of lead from gasoline, elimination of lead solder from canned food, removal of lead from paint, and abatement of housing containing lead-based paint. Nevertheless, continuing factors that enhance risk to lead exposure, particularly during fetal life, are low socioeconomic status, old housing with lead-containing paint, and less than ideal nutrition, particularly low dietary intake of calcium, iron, and zinc. Prenatal exposure may result from endogenous sources such as lead in the maternal skeletal system or maternal exposures from diet and the environment. Experimental studies have shown that the developing nervous system is particularly sensitive to the toxic effects of lead and that a large number of the effects in the nervous system are due to interference of lead with biochemical functions dependent on calcium ions and impairment of neuronal connections dependent on dendritic pruning. There is need for more study to determine whether these effects are a continuum of prenatal lead exposure or whether prenatal exposure to lead produces unique effects.

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