Characterization and quantification of chlordecone elimination in ewes.

To reduce the exposure of the French West Indies population to the organochlorine insecticide chlordecone (Kepone; CLD), the contamination of currently consumed foodstuffs must be reduced. Depuration of contaminated animals before slaughter could be a strategy to obtain safe animal products. The aim of this study was to characterize and quantify CLD elimination in contaminated ewes during depuration process. Experiments A and B consisted in a single intravenous (i.v.) administration of CLD (n = 5) and CLDOH (chlordecol; n = 3) followed by a 84-d and 3-d depuration period respectively with collection of blood, faeces and urine samples. After CLD administration, CLD and conjugated-CLDOH (CLDOH-C) were quantified in serum and urine and CLD and CLDOH were quantified in faeces. Based on calculations of faecal, urinary and body clearances of CLD and CLDOH-C, faeces appeared as the major route of CLD excretion with 86 % of the CLD administered dose eliminated in faeces, either as CLD (51 %) or as CLDOH (35 %).

Amendment of soil by biochars and activated carbons to reduce chlordecone bioavailability in piglets.

Chlordecone (Kepone or CLD) is a highly persistent pesticide formerly used in French West Indies. Nowadays high levels of this pesticide are still found in soils which represent a subsequent source of contamination for outdoor-reared animals. In that context, sequestering matrices like biochars or activated carbons (ACs) are believed to efficiently decrease the bioavailability of such compounds when added to contaminated soils. The present study intends to test the respective efficiency of soil amendment strategies using commercial ACs or biochars (obtained by a 500 °C or 700 °C pyrolysis of 4 distinct type of wood). This study involved three experimental steps. The first one characterized specific surface areas of biochars and ACs. The second one assessed CLD-availability of contaminated artificial soils (50 µg g-1 of Dry Matter) amended with 5% of biochar or AC (mass basis). The third one assessed CLD bioavailability of those artificial soils through an in vivo assay. To limit ethically the number of animals, selections of the most promising media were performed between each experimental steps. Forty four castrated male 40-day-old piglets were exposed during 10 day by amended artificial soils according to their group (n = 4). Only treatment groups exposed through amended soil with AC presented a significant decrease of concentrations of CLD in liver and adipose tissue in comparison with the control group (p < 0.001). A non-significant decrease was obtained by amending artificial soil with biochars. This decrease was particularly high for a coconut shell activated carbon were relative bioavailability was found lower than 3.2% for both tissues. This study leads to conclude that AC introduced in CLD contaminated soil should strongly reduce CLD bioavailability.

Toxicokinetics of chlordecone in goats: Implications for risk management in French West Indies.

The former use of chlordecone (CLD) in the French West Indies has resulted in long-term pollution of soils. CLD is known to be potentially transferred towards animal products of animals reared outdoors, mainly through accidental soil ingestion. Several studies indicate that soil bound CLD is bioavailable when administered to farm animals. Currently there is a need to quantify the level of CLD absorption and its toxicokinetic characteristics in the ruminant and particularly in the goat. These are considered as important farm species in the French West Indies. The objective of this study was to evaluate the absorption rate and the half-life of CLD in the non-lactating goat. The goats were administered either intravenously (i.v., n = 6) or orally (p.o., n = 6) one dose (1 mg kg-1 body weight) of CLD. Blood samples were collected at defined times up to 160 days post-dosing. CLD was analyzed in serum by high-resolution gas chromatography. A comparison of the area under the serum concentration-time curves (AUC) showed that the i.v. route is equivalent to the oral route. Thus, CLD is considered almost completely absorbed after p.o. administration, as shown by the mean absolute bioavailability. The comparison between the pharmacokinetic profiles of CLD following oral and intravenous dose showed a difference during the first 14 days and a similar kinetic after this period. The half-life of CLD in serum was close to 20 days. These results highlight a possible strategy of decontamination due to the short half-life of CLD, obtained in dry goats that did not excrete fat matter.

Organochlorine (chlordecone) uptake by root vegetables.

Chlordecone, an organochlorine insecticide, continues to pollute soils in the French West Indies. The main source of human exposure to this pollutant is food. Root vegetables, which are staple foods in tropical regions, can be highly contaminated and are thus a very effective lever for action to reduce consumer exposure. We analyzed chlordecone contamination in three root vegetables, yam, dasheen and sweet potato, which are among the main sources of chlordecone exposure in food in the French West Indies. All soil types do not have the same potential for the contamination of root vegetables, allophanic andosols being two to ten times less contaminating than non-allophanic nitisols and ferralsols. This difference was only partially explained by the higher OC content in allophanic soils. Dasheen corms were shown to accumulate more chlordecone than yam and sweet potato tubers. The physiological nature of the root vegetable may explain this difference. Our results are in good agreement with the hypothesis that chlordecone uptake by root vegetables is based on passive and diffusive processes and limited by transport and dilution during growth.

Hepatic sequestration of chlordecone and hexafluoroacetone evaluated by pharmacokinetic modeling.

Chlordecone (CD) and mirex (M) differ by a single carbonyl group in CD in place of two chlorines in M. Although both compounds are lipophilic, their tissue distributions differ markedly: CD concentrations are highest in liver; M concentrations are highest in fat. We used tissue time course data in rats from our laboratory for CD and M and literature data from monkeys to develop PBPK models to study differences in liver and fat partitioning. The PK model for M had partitioning in tissue without specific hepatic binding. The CD model had partitioning similar to M, and also included liver binding: the maximal binding (B(max)) and binding affinity constant (Kd) required to describe the rat data were 370 nmol/g liver and 100 nM, respectively. To see if other ketones with electron withdrawing constituents at the alpha carbon were also preferentially distributed to liver, we developed a PBPK description for tissue distribution of hexafluoroacetone (HFA). Compared to acetone, HFA is known to be preferentially sequestered in liver and more slowly excreted unchanged from the body. Acetone is more equally distributed to tissues. HFA distribution was evaluated with a PBPK model that included hepatic binding. B(max) and Kd were 1.58 micromol/g liver and 301 microM. In summary, liver sequestration of CD and HFA most likely represents relatively high-affinity but reversible binding of activated carbonyls in these compounds (activated by the presence of electron withdrawing substituents on the alpha-carbons) with glutathione and glutathione transferases, that are present at much higher concentrations in liver than in other tissues. Strong, but reversible hemithioketal formation with active sulfhydryls may also be associated with the toxic responses to CD and HFA.

Kepone in James River fish: 1976-2002.

In late 1975, it was discovered that a manufacturing facility had not only exposed workers to the chlorinated pesticide, Kepone, but had also severely contaminated the James River estuary. To assess the potential for the public to be exposed to Kepone through the consumption of contaminated seafood, the Commonwealth of Virginia initiated a finfish-monitoring program in late 1975. Over 13,000 samples have been collected and analyzed as part of this effort. Kepone levels in most species began falling when the production of Kepone ended, but the average concentrations remained over the action limit of 0.3 microg g(-1) wet weight until the early 1980s. By 1988 few fish contained Kepone concentrations greater than the action limit. Kepone is still detected in the majority of white perch and striped bass samples taken from the James River and a fish consumption advisory is still in effect thirty years after the source of contamination was removed.

Percutaneous absorption and disposition of [14C]chlordecone in young and adult female rats.

The objective of this study was to evaluate the effect of age and dosage on percutaneous absorption and disposition of [14C]chlordecone (Kepone) and to describe results using a physiological based pharmacokinetic (PBPK) model. Female Fischer 344 rats 33 and 82 days old were used as the young and adult animal models, respectively, and were studied over a 10-fold dose range. [14C]Chlordecone (0.286 micromol/cm2) was applied to dorsal skin (2. 3% BSA) and radioactivity was quantified in selected tissues and excreta up to 120 h. Absorption and disposition were also determined at three dose levels up to 2.68 micromol/cm2; fraction absorbed decreased as dose increased. In vitro percutaneous absorption was measured by static and flow-through methods; these yielded similar penetration rates, which were lower than those obtained in vivo. In vivo percutaneous absorption over 120 h was 14.4+/-0.99 and 14.2+/-1. 5% dose in young and adults, respectively. Organ and tissue content increased over time (carcass>liver>kidney), indicating prolonged absorption. Statistical differences between young and old were found for liver, skin, and urine, but not for absorption. Excretion occurred primarily in feces, but also in urine. A biophysically based percutaneous model was fitted to both young and adult in vivo absorption data. This was embedded in a whole body PBPK model which, upon optimization with SAAM II, estimated apparent tissue partition coefficients, urinary and fecal excretion rates, and parameters characterizing hepatic nonlinear uptake of bound chlordecone. The model reasonably predicted tissue chlordecone content at higher doses, when decreased absorption was accounted for.

Ultrastructural, protein, and lipid changes in liver associated with chlordecone treatment of mice.

Pretreatment of mice with chlordecone (CD) reduced hepatic accumulation of a subsequent dose of [14C]CD without significantly changing [14C]CD biotransformation. To determine if CD-induced changes in hepatic [14C]CD accumulation were coincident with altered cell composition, we examined the effects of CD on hepatic protein and lipid content, on fatty acid profiles of liver and kidney, and on the ultrastructure of hepatocytes. SDS-polyacrylamide gel electrophoresis detected an apparent CD dose-related increase in a microsomal protein with a molecular weight of about 23 kDa. Total liver or kidney lipid contents were not altered by CD but relative amounts of several hepatic fatty acids were changed. CD caused marked hepatic mitochondrial swelling, increased amounts of endoplasmic reticulum, apparently increased numbers of peroxisome-like structures, and decreased numbers of lipid droplets in cytoplasm of hepatocytes. Numbers of lipid droplets were not decreased in perisinusoidal fat storage cells. In addition, the numbers of cytoplasmic lipoprotein vesicles were apparently increased in some hepatocytes. Overall these changes indicated an increased hepatocyte secretory activity and suggested that CD changed hepatocellular lipid transport, storage, and metabolism pathways.

Physiologically based pharmacokinetic/pharmacodynamic modeling of the toxicologic interaction between carbon tetrachloride and Kepone.

Carbon tetrachloride (CCl4) lethality in Sprague-Dawley rats is greatly amplified by pretreatment of Kepone (decachlorooctahydro-1,3,2-metheno-2H-cyclobuta[cd] pentalen-2-one). The increase in lethality was attributed to the obstruction of liver regenerative processes. These processes are essential for restoring the liver to its full functional capacity following injury by CCl4. Based on the available mechanistic information on Kepone/CCl4 interaction, a physiologically based pharmacokinetic/pharmacodynamic (PBPK/PD) model was constructed where the following effects of Kepone on CCl4 toxicity are incorporated: (1) inhibition of mitosis; (2) reduction of repair mechanism of hepatocellular injury; (3) suppression of phagocytosis. The PBPK/PD model provided computer simulation consistent with previously published time-course results of hepatotoxicity (i.e., pyknotic, injured and mitotic cells) of CCl4 with or without Kepone. As a further verification of this model, the computer simulations were also consistent with exhalation kinetic data for rats injected with different intraperitoneal (i.p.) doses of CCl4 in our laboratory. Subsequently, the PBPK/PD model, coupled with Monte Carlo simulation, was used to predict lethalities of rats treated with CCl4 alone and CCl4 in combination with Kepone. The experimental lethality studies performed in our laboratories were as follows: Sprague-Dawley rats were given either control diet or diet containing 10 ppm Kepone for 15 days. On day 16, rats in the Kepone treated group were given i.p. doses of 0, 10, 50, and 100 microliters/kg CCl4 (n = 9) while control rats were exposed to 0, 100, 1000, 3000, and 6000 microliters/kg CCl4 (n = 9). Lethality was observed at the 1000 (1/9), 3000 (4/9), and 6000 (8/9) microliters/kg doses for the control group and at the 50 (4/9) and 100 (8/9) microliters/kg for the treated group. Based on Monte Carlo simulation, which was used to run electronically 1000 lethality experiments for each dosing situation, the LD50 estimates for CCl4 toxicity with and without Kepone pretreatment were 47 and 2890 microliters/kg, respectively. Monte Carlo simulation coupled with the PBPK/PD model produced lethality rates which were not significantly different from the observed mortality, with the exception of CCl4 at very high doses (e.g., 6000 microliters/kg, p = 0.014). Deviation at very high doses of the predicted mortality from the observed may be attributed to extrahepatic systemic toxicities of CCl4, or solvent effects on tissues at high concentrations, which were not presently included in the model. Our modeling and experimental results verified the earlier findings of Mehendale (1990) for the 67-fold amplification of CCl4 lethality in the presence of Kepone. However, much of this amplification of CCl4 lethality with Kepone pretreatment was probably due to pharmacokinetic factors, because when target tissue dose (i.e., model estimated amount of CCl4 metabolites) was used to evaluate lethality, this amplification was reduced to 4-fold.

Physiologically based pharmacokinetic/pharmacodynamic modeling of chemical mixtures and possible applications in risk assessment.

Human exposure to chemicals, be it environmental or occupational, is rarely, if ever, limited to a single chemical. Therefore, it is essential that we consider multiple chemical effects and interactions in our risk assessment process. However, with the almost infinitely large number of chemical mixtures in the environment, systematic studies of the toxicology of these chemical mixtures with conventional methodologies and approaches are impossible because of the immense resources and unrealistically long durations required. Thus, the development of predictive and alternative toxicology method is imperative. In order to have a reasonable chance to deal with the complex issue of toxicology of chemical mixtures, we believe that the following concepts must be considered: (1) the exploitation of recent advances in computational technology; (2) the utilization of mathematical/statistical modeling; (3) coupling computer modeling with very focused, mechanistically based, and short-term toxicology studies. Our approach is, therefore, the utilization of physiologically based pharmacokinetic/pharmacodynamic (PB-PK/PD) modeling, coupled with very focused, model-directed toxicology experiments as well as other statistical/mathematical modeling such as isobolographic analysis and response surface methodology. Tissue dosimetry at the pharmacokinetic and pharmacodynamic levels is achievable with simple and complex, but chemically defined, mixtures. Our long-term goal is to formulate innovative risk assessment methodologies for chemical mixtures. In this presentation, one of our specific research projects is described: PB-PK/PD modeling of toxicologic interactions between Kepone and carbon tetrachloride (CCl4) and the coupling of Monte Carlo simulation for the prediction of acute toxicity.

ATSDR evaluation of health effects of chemicals. II. Mirex and chlordecone: health effects, toxicokinetics, human exposure, and environmental fate.

This document provides public health officials, physicians, toxicologists, and other interested individuals and groups with an overall perspective of the toxicology of mirex and chlordecone. It contains descriptions and evaluations of toxicological studies and epidemiological investigations and provides conclusions, where possible, on the relevance of toxicity and toxicokinetic data to public health. Additional substances will be profiled in a series of manuscripts to follow.

Chlordecone pretreatment alters [14C]chlordecone and [14C]cholesterol transport kinetics in the perfused rat liver.

Previous work demonstrated that pretreatment of mice with low doses of the organochlorine insecticide chlordecone (CD) altered the tissue disposition of a subsequent [14C]CD or [14C]cholesterol challenge dose. The profile of these changes was consistent with the induction of a protein integral to hepatic CD/cholesterol turnover. The present study was undertaken to confirm similar in vivo effects in the rat and to analyze potential CD-induced changes in hepatic transport kinetics in the perfused rat liver. For in vivo experiments, male, Sprague-Dawley rats were treated with CD (5, 15, or 40 mg/kg) and challenged 3 or 7 days later with a 5 mg/kg [14C]CD tracer dose. Rats challenged 3 days after treatment and evaluated 16 hr later showed a dose-dependent decrease in hepatic [14C]CD relative to controls. This decrease could not be attributed to alterations in liver mass or total liver lipid. For kinetics studies, rats received 15 mg/kg CD and livers were perfused 3 days later. Following a brief (5-7 min) single-pass perfusion, the perfusate was replaced with recirculating buffer containing albumin-bound [3H]oleic acid or high-density lipoprotein-bound [14C]CD or [14C]cholesterol. Livers from pretreated animals had significantly decreased rates of [14C]CD and [14C]cholesterol uptake. Efflux of [14C]CD and biliary excretion of [14C]cholesterol were increased. No changes were observed in uptake or biliary excretion of [3H]oleic acid. SDS-PAGE of hepatic cytosol revealed an enhanced band intensity corresponding to a M(r) of 25,600 in livers from pretreated rats.(ABSTRACT TRUNCATED AT 250 WORDS)

Distribution of chlordecone to liver plasma membranes and recovery from hepatobiliary dysfunction in rats.

Chlordecone (CD) impairs biliary excretion of organic anions (including phenolphthalein glucuronide (PG), imipramine polar metabolites, and taurocholate) without evidence of hepatocellular necrosis in rats. In this study we investigated the hypothesis that CD-induced hepatobiliary dysfunction is dependent on CD concentration in liver plasma membranes where it inhibits active transport in vitro. Rats were treated by gavage (0 or 60 mg CD/kg in corn oil) 24 or 72 h prior to bile duct cannulation. Biliary excretion of PG, a marker of hepatic organic anion transport, and [14C]mannitol, a marker of passive transcellular permeability, was determined. Biliary excretion of PG decreased approximately 25% in rats 24 h after CD treatment, however rats recovered control PG excretion rates 72 h after CD treatment. Recovery of PG excretion occurred despite higher liver homogenate [14C]CD concentrations at 72 h than at 24 h after [14C]CD treatment. Biliary clearance of [14C]mannitol decreased both 24 h and 72 h after treatment. Even though the amount of [14C]CD retained in the liver was greater at 72 h than at 24 h after treatment, the concentration of [14C]CD in isolated liver plasma membranes (LPM) was the same (3.5-3.9 nmol/mg protein) at both times. There was a significant reduction in 5'-nucleotidase activity of LPM at 24 h but not at 72 h after CD. This study demonstrated no correlation between recovery from CD-induced hepatobiliary dysfunction and whole liver accumulation. Altered subcellular [14C]CD distribution (reduced LPM-to-homogenate concentration ratio was coincident with recovery.

The clinical toxicology of chlordecone as an example of toxicological risk assessment for man.

Safety assessment procedures still rely heavily if not exclusively on the results of tests carried out in laboratory animals, then extrapolated to man. There are few examples of environmental compounds examined extensively enough in both man and animals to permit a critical comparison of the accuracy of such risk assessment procedures. Chlordecone (Kepone) is a lipophilic, rodent liver carcinogen which now stands among the most extensively studied environmental agents in humans. More than five years of clinical investigations of workers heavily exposed to organochlorine pesticide have established the spectrum of human toxicity of Chlordecone, its dose-response relationships, tissue distribution, metabolic pathways, half-time for elimination, and the concentration at which its major toxic manifestations involving the central nervous system, the liver, and the testes are not observed (no observable effect level, NOEL). Taking advantage of this unique opportunity to proximately compare humans with experimental animals for a single compound administered at comparable doses, we find that none of the toxic effects produced in humans were unrepresented in animal testing. However, the animal testing produced numerous "false positive" results. Hence, accurately predicting the qualitative toxicity of chlordecone in man based on studies in rats would have been impossible. Indeed, proteinuria observed in rats fed small amounts of chlordecone for two years was chosen as a sensitive endpoint by the United States Environmental Protection Agency as the basis for establishing acceptable levels of human exposure. However, we never observed proteinuria even in humans whose dose of chlordecone was hundreds of times higher than that given to the rats. We conclude that greater emphasis should be placed on clinical investigation of humans exposed to environmental agents. A better understanding of the strength and also of the limitations of animal toxicity testing will improve the reliability of extrapolating results of animal testing to human exposure conditions.

A characterization of chlordecone pretreatment-altered pharmacokinetics in mice.

Lipophilic chlorinated hydrocarbons pose a potential health hazard to humans and animals and the toxicity of a number of these compounds has been well documented. Despite the low environmental concentrations of most of these chemicals, much of the research conducted to date has used maximally tolerated doses. Our research, conducted with low, apparently nontoxic, doses of the insecticide chlordecone (CD), showed that the administration of CD (5 mg/kg ip) to mice (C57BL/6N and DBA/2N strains) caused a time-dependent alteration in the pattern of distribution of a subsequently administered dose of [14C]CD. Livers of CD-pretreated animals contained less label than did those from controls and CD pretreatment increased amounts of label in kidney, lung, fat, and muscle. Changes did not appear to be due to an altered rate of metaboLism and analysis of total CD in tissues (unlabeled plus [14C]CD) indicated that these responses were not due to a simple redistribution phenomenon. We have termed this preexposure effect a pretreatment disposition response (PDR) and feel it may reflect an important cellular response to lipophilic compounds. CD-induced PDR is dose related, exhibits a threshold, and is saturable at a given level of induction. In addition, PDR exhibits some specificity, inasmuch as pretreating mice with CD (5 mg/kg) does not alter the distribution of subsequently administered [14C]dieldrin. The characteristics of threshold, saturability, and specificity are consistent with the premise that CD-induced PDR is a protein-mediated phenomenon.

Biotransformation of chlordecone by Pseudomonas species.

1. Six-month chlordecone enrichment cultures with added chlordecone yielded several Gram-negative micro-organisms that were resistant to and/or degraded chlordecone. 2. Three Pseudomonas spp. were further characterized for their chlordecone degrading ability. 3. Chlordecone and two derivatives, Mirex and Kelevan, supported growth of these strains. 4. All three Pseudomonas spp. decreased the concentration of chlordecone in the medium after 14 days incubation, as determined by h.p.l.c. analysis when it was added either as sole carbon source or in the presence of medium supplements.

Chloroform interaction with chlordecone and mirex: correlation between biochemical and histological indices of toxicity and quantitative tissue levels.

The purpose of this study was to investigate whether the tissue distribution of chlordecone (CD) and mirex (M) might explain the difference in the potentiation of CHCl3 liver injury. Male Sprague-Dawley rats received either a single oral dose of CD or M (1, 2.5, 5, 10, 25, or 50 mg/kg) or three single daily doses of CD or M (0.5, 2, or 10 mg/kg). Eighteen hours following the last treatment, the animals were divided into two groups. The first group was killed and residues of CD or M in plasma, kidney, liver, and adipose tissue were measured by gas-liquid chromatography. The other group received CHCl3 (0.5 ml/kg, po) and was killed 24 hr later. Biochemical and histological indices of liver injury were evaluated. CD administered either singly or repetitively is more effective than M in potentiating the CHCl3-induced liver injury. This was exhibited by a higher increase in the plasma activities of the enzymes alanine aminotransferase and ornithine carbamoyl transferase and a greater alteration of the morphological pattern. There was a very good correlation between biochemical and histological indices. However, the severity of the liver injury did not parallel tissue concentrations. With M, a relatively poor potentiation of the liver damage was observed although adequate hepatic concentrations were present.