In Vitro Intestinal Lead Uptake and Transport in Relation to Speciation

Children might be exposed substantially to contaminants such as lead via soil ingestion. In risk assessment of soil contaminants there is a need for information on oral bioavailability of soilborne lead. Oral bioavailability can be seen as the result of four steps: (1) soil ingestion; (2) mobilization from soil during digestion, i.e., bioaccessibility; (3) transport across the intestinal epithelium; and (4) first-pass effect. Lead bioaccessibility and speciation in artificial human small intestinal fluid, i.e., chyme, have been investigated in previous studies. In the present study, transport of bioaccessible lead across the intestinal epithelium was investigated using the Caco-2 cell line. Cell monolayers were exposed to (diluted) artificial chyme. In 24 h, approximately 27% of the lead were associated to the cells and 3% were transported across the cell monolayer, without signs of approaching equilibrium. Lead associated to the cells showed a linear relationship with the total amount of lead in the system. Bile levels did not affect the fraction of lead associated to Caco-2 cells. Extrapolation of the lead flux across the Caco-2 monolayer to the in vivo situation indicates that only a fraction of the bioaccessible lead is transported across the intestinal epithelium. Furthermore, the results indicate that as the free Pb2+ concentration in chyme was negligible, lead species other than the free metal ion must have contributed to the lead flux toward the cells. On the basis of lead speciation in chyme, this can be attributed to dissociation of labile lead species, such as lead phosphate and lead bile complexes, and subsequent transport of the released free metal ions toward the intestinal membrane.

[1]  M. Freedman,et al.  Effect of lead speciation on toxicity , 1980, Bulletin of environmental contamination and toxicology.

[2]  Paul Mushak,et al.  Gastro-Intestinal Absorption of Lead in Children and Adults: Overview of Biological and Biophysico-Chemical Aspects , 1991 .

[3]  E. Ziegler,et al.  Absorption and Retention of Lead by Infants , 1978, Pediatric Research.

[4]  P. Zuman,et al.  Interaction between Dihydroxy Bile Salts and Divalent Heavy Metal Ions Studied by Polarography , 1995 .

[5]  B. Brunekreef,et al.  Estimated soil ingestion by children. , 1990, Environmental research.

[6]  W. Rubas,et al.  A human colonic cell line sharing similarities with enterocytes as a model to examine oral absorption: advantages and limitations of the Caco-2 model. , 1997, Critical reviews in therapeutic drug carrier systems.

[7]  A. K. Davis,et al.  Mass Balance on Surface-Bound, Mineralogic, and Total Lead Concentrations as Related to Industrial Aggregate Bioaccessibility , 1997 .

[8]  R. E. Guzman,et al.  Bioavailability of lead to juvenile swine dosed with soil from the Smuggler Mountain NPL Site of Aspen, Colorado. , 1997, Fundamental and applied toxicology : official journal of the Society of Toxicology.

[9]  H. Matthews,et al.  Comparison of lead bioavailability in F344 rats fed lead acetate, lead oxide, lead sulfide, or lead ore concentrate from Skagway, Alaska. , 1993, Journal of toxicology and environmental health.

[10]  T. Florence,et al.  Electrochemical approaches to trace element speciation in waters , 1986 .

[11]  C. O’Driscoll,et al.  A comparison of the permeation enhancement potential of simple bile salt and mixed bile salt:fatty acid micellar systems using the CaCo-2 cell culture model. , 2000, International journal of pharmaceutics.

[12]  P. Feder,et al.  Relative bioavailability of lead from mining waste soil in rats. , 1992, Fundamental and applied toxicology : official journal of the Society of Toxicology.

[13]  Staffan Skerfving,et al.  Lead—biological monitoring of exposure and effects , 1998 .

[14]  P. Campbell,et al.  Silver uptake by the green alga Chlamydomonas reinhardtii in relation to chemical speciation: Influence of chloride , 2000 .

[15]  P. Artursson Cell cultures as models for drug absorption across the intestinal mucosa. , 1991, Critical reviews in therapeutic drug carrier systems.

[16]  G. Morrison,et al.  Determination of trace element speciation and the role of speciation in aquatic toxicity. , 1992, The Science of the total environment.

[17]  J. A. Ryan,et al.  Transformation of Pb(II) from cerrusite to chloropyromorphite in the presence of hydroxyapatite under varying conditions of pH , 1999 .

[18]  H. Sezaki,et al.  Effect of bile salts on the gastrointestinal absorption of drugs. I. , 1970, Chemical & pharmaceutical bulletin.

[19]  A. Oomen,et al.  Lead Speciation in Artificial Human Digestive Fluid , 2003, Archives of environmental contamination and toxicology.

[20]  M. Ruby,et al.  Lead bioavailability : dissolution kinetics under simulated gastric conditions , 1992 .

[21]  J. Dressman,et al.  Physiochemical and physiological mechanisms for the effects of food on drug absorption: the role of lipids and pH. , 1997, Journal of pharmaceutical sciences.

[22]  Frank A. Swartjes,et al.  Risk-Based Assessment of Soil and Groundwater Quality in the Netherlands: Standards and Remediation Urgency , 1999, Risk analysis : an official publication of the Society for Risk Analysis.

[23]  K. Hillgren,et al.  In vitro systems for studying intestinal drug absorption , 1995, Medicinal research reviews.

[24]  J. Groten,et al.  Availability of polychlorinated biphenyls (PCBs) and lindane for uptake by intestinal Caco-2 cells. , 2001, Environmental health perspectives.

[25]  Soil Ingestion: A Concern for Acute Toxicity in Children , 1998, Environmental Health Perspectives.

[26]  J. Groten,et al.  Effects of cadmium chloride on the paracellular barrier function of intestinal epithelial cell lines. , 1999, Toxicology and Applied Pharmacology.

[27]  J. Blair,et al.  Factors influencing the transport of lead across the small intestine of the rat. , 1980, Environmental research.

[28]  H. P. Leeuwen Metal Speciation Dynamics and Bioavailability: Inert and Labile Complexes , 1999 .

[29]  S. Felter,et al.  Gastrointestinal absorption of metals. , 1997, Drug and chemical toxicology.

[30]  P. Artursson,et al.  Correlation between oral drug absorption in humans and apparent drug permeability coefficients in human intestinal epithelial (Caco-2) cells. , 1991, Biochemical and biophysical research communications.

[31]  T. Fujita,et al.  Effectiveness and toxicity screening of various absorption enhancers using Caco-2 cell monolayers. , 1998, Biological & pharmaceutical bulletin.

[32]  J. A. Ryan,et al.  In Vitro Soil Pb Solubility in the Presence of Hydroxyapatite , 1998 .