Toxicokinetics in rats and modeling to support the interpretation of biomonitoring data for rare-earth elements.

Toxicokinetic models are useful tools to better understand the fate of contaminants in the human body and to establish biological guidance values to interpret biomonitoring data in human populations. This research aimed to develop a biologically-based toxicokinetic model for four rare earth elements (REEs), cerium (Ce), praseodymium (Pr), neodymium (Nd) and yttrium (Y), and to establish biomonitoring equivalents (BE) serving as biological guidance values. The model was constructed using physiological data taken from the literature as well as new experimental kinetic data. These new data indicated that REEs readily disappeared from blood and accumulated mostly in the liver; excretion occurred mainly through feces although a small fraction was eliminated in urine. To properly reproduce the observed kinetics, the model was represented as 19 compartments, which include main tissues and their components (such as retention by macrophages) supplied by blood, as well as routes of excretion. The transfer coefficients between compartments were determined numerically by adjustments to experimental data. Simulations gave good fits to available experimental kinetic data and confirmed that the same model structure is applicable to the four elements. BEs of 0.3 µg/L of Pr and Nd were derived from the provisional RfD of 0.5 mg/kg bw/day established by the U.S. EPA. These BEs can be updated according to new reference dose values (RfD). Overall, the model can contribute to a better understanding of the significance of biological measurements and to the inference of exposure levels; it can also be used for the modeling of other REEs. The BEs will further allow rapid screening of different populations using biological measurements in order to guide risk assessments.

Effect of the dose on the toxicokinetics of a quaternary mixture of rare earth elements administered to rats.

Large human biomonitoring studies are starting to assess exposure to rare earth elements (REEs). Yet, there is a paucity of data on the toxicokinetics of these substances to help interpret biomonitoring data. The objective of the study was to document the effect of the administered dose on the toxicokinetics of REEs. Male Sprague-Dawley rats were injected intravenously with 0.3, 1 or 10 mg/kg body weight (bw) of praseodynium chloride (PrCl3), cerium chloride (CeCl3), neodymium chloride (NdCl3) and yttrium chloride (YCl3) administered together as a mixture. Serial blood samples were withdrawn up to 72 h following injection, and urine and feces were collected at predefined time intervals up to 7 days post-dosing. The REEs were measured by Inductively Coupled Plasma Mass Spectrometry (ICP-MS). For a given REE dose, the time courses in blood, urine and feces were similar for all four REEs. However, the REE dose administered significantly impacted their kinetics, as lower cumulative excretion in urine and feces was associated with higher REE doses. The fraction of REE remaining in rat tissues at the terminal necropsy on post-dosing day 7 also increased with the dose administered, most notably in the lungs and spleen at the 10 mg/kg bw dose. The toxicokinetic parameters calculated from the blood concentration-time profiles further showed significant increases in the mean residence time (MRTIV) for all four REEs at the 10 mg/kg bw dose. The shift in the REE kinetics at high dose may be explained by a higher retention in lysosomes, the main organelle responsible for accumulation of these REEs in different tissues.