Kathleen P. Plotzke

In vitro and In vivo percutaneous absorption of 14C-octamethylcyclotetrasiloxane (14C-D4) and 14C-decamethylcyclopentasiloxane (14C-D5)

Octamethylcyclotetrasiloxane (D4) and decamethylcyclopentasiloxane (D5) are cyclic siloxanes used as chemical intermediates with some applications in consumer products. The in vitro percutaneous absorption of 14C-D4 and 14C-D5 was studied in flow-through diffusion cells. Single doses were applied neat and in antiperspirant formulations to dermatomed human skin for 24h. The majority of applied D4 and D5 ( approximately 90%) volatilized before being absorbed. Only 0.5% of applied D4 was absorbed while the absorption of D5 (0.04%) was one order of magnitude lower. The largest percentage (>90%) of the absorbed D4 and D5 was found in the skin. The fate of D4 and D5 absorbed in the skin was studied in rat in vivo. A single dose of 14C-D4 (10, 4.8 and 2mg/cm2) and 14C-D5 (10mg/cm2) was topically applied inside a dosing chamber attached to the dorsal area. Rats were housed in metabolism cages up to 24h to enable collection of urine, feces, expired/escaped volatiles. The majority of applied D4 or D5 had volatilized from the skin surface. Less than 1.0% of the applied D4 and only 0.2% of applied D5 was absorbed with approximately 60% of absorbed D4 and 30% of absorbed D5 reaching systemic compartments. The amount absorbed into the skin decreased with time showing that residual D4 and D5 diffused back to the skin surface and continued to evaporate. Overall, a low tendency to pass through the skin into systemic compartments was demonstrated for both D4 (< or = 0.5% of applied dose) and D5 (<0.1% of applied dose).

Use of In Vitro Absorption, Distribution, Metabolism, and Excretion (ADME) Data in Bioaccumulation Assessments for Fish

ABSTRACT A scientific workshop was held in 2006 to discuss the use of in vitro Absorption, Distribution, Metabolism, and Excretion (ADME) data in chemical bioaccumulation assessments for fish. Computer-based (in silico) modeling tools are widely used to estimate chemical bioaccumulation. These in silico methods have inherent limitations that result in inaccurate estimates for many compounds. Based on a review of the science, workshop participants concluded that two factors, absorption and metabolism, represent the greatest sources of uncertainty in current bioaccumulation models. Both factors can be investigated experimentally using in vitro test systems. A variety of abiotic and biotic systems have been used to predict chemical accumulation by invertebrates, and dietary absorption of drugs and xenobiotics by mammals. Research is needed to determine whether these or similar methods can be used to better predict chemical absorption across the gills and gut of fish. Scientists studying mammals have developed a stepwise approach to extrapolate in vitro hepatic metabolism data to the whole animal. A series of demonstration projects was proposed to investigate the utility of these in vitro–in vivo extrapolation procedures in bioaccumulation assessments for fish and delineate the applicability domain of different in vitro test systems. Anticipating research progress on these topics, participants developed a “decision tree” to show how in vitro information for individual compounds could be used in a tiered approach to improve bioaccumulation assessments for fish and inform the possible need for whole-animal testing.

Inhalation Dosimetry Modeling with Decamethylcyclopentasiloxane in Rats and Humans

Decamethylcyclopentasiloxane (D(5)), a volatile cyclic methyl siloxane (VCMS), is used in industrial and consumer products. Inhalation pharmacokinetics of another VCMS, octamethylcyclotetrasiloxane (D(4)), have been extensively investigated and successfully modeled with a multispecies physiologically based pharmacokinetic (PBPK) model. Here, we develop an inhalation PBPK description for D(5), using the D(4) model structure as a starting point, with the objective of understanding factors that regulate free blood and tissue concentrations of this highly lipophilic vapor after inhalation in rats and humans. Compared with D(4), the more lipophilic D(5) required deep compartments in lung, liver, and plasma to account for slow release from tissues after cessation of exposures. Simulations of the kinetics of a stable D(5) metabolite, HO-D(5), required diffusion-limited uptake in fat, a deep tissue store in lung, and its elimination by fecal excretion and metabolism to linear silanols. The combined D(5)/HO-D(5) model described blood and tissue concentrations of parent D(5) and elimination of total radioactivity in single and repeat exposures in male and female rats at 7 and 160 ppm. In humans, D(5) kinetic data are more sparse and the model structure though much simplified, still required free and bound blood D(5) to simulate exhaled air and blood time courses from 1 h inhalation exposures at 10 ppm in five human volunteers. This multispecies PBPK model for D(5) highlights complications in interpreting kinetic studies where chemical in blood and tissues represents various pools with only a portion free. The ability to simulate free concentrations is essential for dosimetry based risk assessments for these VCMS.

Quantitative Determination of Octamethylcyclotetrasiloxane (D4) in Extracts of Biological Matrices by Gas Chromatography-Mass Spectrometry

Abstract A method was developed and validated to measure octamethylcyclotetrasiloxane (D4)† quantitatively by gas chromatography-mass spectrometry (GC-MS) at low level in extracts of several biological matrices that include plasma, liver, lung, feces and fat from rats. The key to the successful determination lay in the use of extracts dried with anhydrous magnesium sulfate. This was necessary in view of the propensity of the methyl siloxane based GC-stationary phase to generate D4 by its reaction with water present in the extracts. To enable quantiiation of D4 at parts per billion (μg/L) levels, the base ion m/z 281 resulting from the loss of a methyl group from the parent molecule was selected for monitoring by SIM mode in GC-MS. The recovery of D4 from any of the biological matrices was determined to be greater than 90% in three extractions. The D4 response for the standards in GC-MS was linear (R2 > 0.9900) and reproducible at concentrations ranging from 1—16,000 ng D4/g solvent. Precision was less than 5%.

Are highly lipophilic volatile compounds expected to bioaccumulate with repeated exposures

With non-volatile compounds, high lipophilicity (i.e., fat:blood partition coefficients, Pf, in the range of several hundred to a thousand or higher) typically leads to concerns for bioaccumulation. To evaluate the extent to which highly cleared, lipophilic vapors are expected to accumulate in blood and tissues, we conducted pharmacokinetic (PK) analysis, using both a generic physiologically based (PBPK) model for inhalation of volatile compounds (VCs) and a more detailed PBPK model specifically developed for a highly lipophilic volatile (decamethylcyclopentasiloxane, D(5)). The generic PBPK model for inhalation of VCs in humans showed that highly metabolized, lipophilic compounds, with a low blood:air partition coefficient (Pb), do not accumulate in blood or systemic tissues with repeat exposures although a period of days to weeks may be required for fat to reach periodic steady state. VCs with higher Pb (in the hundreds) and lower hepatic extraction accumulate in blood on repeat exposures. The more detailed PBPK model for D(5) also showed that this lipophilc VC does not accumulate in blood and predictions of the increases in D(5) in fat with repeat exposures in rats agreed with experiments. In general, the major characteristic favoring accumulation of VCs in blood and systemic tissues is poor whole-body clearance, not lipophilicty. The term bioaccumulation should be used to refer to cases where repeat exposures lead to increases in VC blood (or central compartment) concentration. Based on this definition, highly cleared VCs, such as D(5), would not be considered to bioaccumulate on repeat exposures.

Disposition of Decamethylcyclopentasiloxane in Fischer 344 Rats Following Single or Repeated Inhalation Exposure to 14C-Decamethylcyclopentasiloxane (14C-D5)

The disposition of decamethylcyclopentasiloxane (D5) in male and female Fischer 344 rats following single or repeated inhalation exposures was evaluated. Animals were administered a single 6-h nose-only exposure to 7 or 160 ppm 14C-D5 or fourteen 6-h nose-only exposures to unlabeled D5 followed on day 15 by a 6-h exposure to 14C-D5. Subgroups of exposed animals were used to evaluate body burden, distribution, elimination, and deposition on the fur. Retention of radioactivity following single and repeated exposures was relatively low (approximately 1–2% of inhaled D5). Radioactivity and parent D5 were widely distributed to tissues of both male and female rats, with the maximum concentration of radioactivity observed in most tissues by 3 h postexposure. Fat was a depot for D5, with elimination occurring much slower than observed for plasma and other tissues. In all groups, the primary route for elimination of radioactivity was through expired air. Analyses for parent D5 indicated that essentially all the radioactivity in the expired volatiles was unchanged D5. Repeated exposure gave rise to higher levels of parent D5 in the lung and fat of both sexes and in female liver relative to the single exposure. In fat, immediately after sacrifice approximately 50% of the radioactivity was attributed to parent. Five polar metabolites of D5 were identified in urine, with no parent D5 detected. Radiochromatograms demonstrated two peaks in feces. One corresponded to the retention time for D5. The second has been putatively identified as hydroxylated D5.

Closed-Chamber Inhalation Pharmacokinetic Studies with Hexamethyldisiloxane in the Rat

Gas uptake methods together with physiologically based pharmacokinetic (PBPK) modeling have been used to assess metabolic parameters and oral absorption rates for a wide variety of volatile organic compounds. We applied these techniques to study the in vivo metabolism of hexamethyldisiloxane (HMDS), a volatile siloxane with low blood/air (partition coefficient PB ≈ 1.00) and high fat/blood partitioning (partition coefficient PF ≈ 300). In contrast to other classes of metabolized volatiles, metabolic parameters could only be estimated from closed-chamber results with confidence by evaluating both closed-chamber disappearance curves and constant concentration inhalation studies. The constant-concentration inhalation results refine the estimate of the blood/air partition coefficient and constrain model structure for storage of the lipophilic compound in blood and tissues. The gas uptake results, from Fischer 344 rats (male, 8-9 wk old) exposed to initial HMDS air concentrations from 500 to 5000 ppm, were modeled with a 5-tissue PBPK model. Excellent fits were obtained with diffusion-limited uptake of HMDS in fat and a lipid storage pool in the blood. Metabolism, restricted to the liver, was described as a single saturable process (V max = 113.6 µmol/h/kg; K m = 42.6 µmol/L) and was affected by inhibitors (diethyldithiocarbamate) or inducers (phenobarbital) of cytochrome P-450s. Exhalation kinetics of HMDS after oral/intraperitoneal administration showed low bioavailability and significant lag times, also quite different from results of other classes of volatile hydrocarbons. In general, estimates of metabolic clearance by gas uptake studies were improved by simultaneous examination of time-course results from constant concentration inhalation studies. This conclusion is likely to hold for any volatile lipophilic compound with low blood/air partitioning.

Chronic toxicity and oncogenicity of octamethylcyclotetrasiloxane (D4) in the Fischer 344 rat

Octamethylcyclotetrasiloxane (D4) is a cyclic volatile methylsiloxane primarily used in the synthesis of silicon-based materials used in a variety of consumer products. This paper details the chronic toxicity and oncogenicity evaluation of D4 in the Fischer 344 rat. Animals were exposed to 0, 10, 30, 150, or 700ppm D4 vapor for 6h/day, 5days/week for up to 104 weeks in whole-body inhalation chambers. Effects of two year chronic exposure included increased liver, kidney, testes, and uterine weight with correlating microscopic findings of hepatocellular hypertrophy (males only), chronic nephropathy (both sexes), interstitial cell hyperplasia, and cystic endometrial hyperplasia and endometrial adenoma, respectively. Upper respiratory tract irritation and lymphocytic leukocytosis were evident in both sexes. Increased neoplasia was demonstrated only in the uterus. Uterine endometrial adenomas were present in four of sixty animals exposed to 700ppm D4 for 24 months. None were present in the other treatment groups. In contrast, in 700ppm D4 group males the incidence of pituitary and pancreatic neoplasia was reduced as was thyroid c-cell adenoma/carcinoma in 700ppm females. This study has identified that D4 is a mild respiratory irritant and increases liver and kidney weight without inducing neoplasia in these tissues. The increased incidence of uterine adenoma was the only treatment-related neoplastic finding associated with chronic exposure to D4.

Assessing Kinetic Determinants for Metabolism and Oral Uptake of Octamethylcyclotetrasiloxane (D4) from Inhalation Chamber Studies

The pharmacokinetics of octamethylcyclotetrasiloxane (D4), a highly lipophilic and well-metabolized volatile cyclic siloxane, are more complex than those of other volatile hydrocarbons. The purpose of the present study was to evaluate rate constants for saturable metabolism in the body, to estimate possible presystemic D4 clearance by respiratory-tract tissues, and to assess rate constants for uptake of D4 after oral dosing. These experiments provided the opportunity to refine current physiologically based pharmacokinetic (PBPK) models for D4 and to independently estimate key model parameters by sensitive inhalation methods. The PBPK model could only be fitted to gas uptake results when metabolic capacity was included in the respiratory-tract epithelium. The model simulations were highly sensitive to the parameter for total percent of whole-body metabolism allocated to the respiratory tract, with optimal fits observed with this value equal to 5%. Oral uptake of D4 was evaluated using both closed and open chamber concentration time-course studies after intubation of D4 in corn oil. Conclusions from the oral uptake studies were also verified by comparison with independent data sets for blood concentrations of D4 after oral dosing. The pharmacokinetic (PK) analysis of uptake from the gut and release from blood into chamber air results for oral doses from 10 to 300 mg D4/kg body weight were consistent with a combination of prolonged and slow uptake of D4 from the gastrointestinal tract and of reduced absorption at higher doses, as well as the extrahepatic clearance of D4 in pulmonary tissues. These closed chamber gas uptake studies provide a valuable confirmation of the conclusions reached in other pharmacokinetic studies and have uncovered a situation where closed chamber loss is highly sensitive to respiratory-tract clearance. This sensitivity largely arises from the unusual characteristics of D4: high-affinity metabolic clearance and low blood:air partitioning.

Effects of chronic exposure to octamethylcyclotetrasiloxane and decamethylcyclopentasiloxane in the aging female Fischer 344 rat

Octamethylcyclotetrasiloxane (D4) and decamethylcyclopentasiloxane (D5) are used as intermediates or monomers in the synthesis of silicon-based polymers for industrial or consumer applications. D4 and D5 may remain as residual monomer in these polymers at less than 1000ppm and may therefore be present as a minor impurity in consumer products. For D5, in addition to the manufacture of polymers, its uses include intentional addition to consumer products, personal care products and some dry- cleaning solvents. Two-year rodent chronic bioassays were conducted with both substances and borderline increases in the incidence of uterine tumors were observed, specifically, benign uterine adenoma with D4 and adenocarcinoma with D5. The effects profile and induction of uterine tumors share some similarity with that seen with chronic exposure to dopamine agonists. The current study investigated the potential for D4 and D5 to elicit dopamine agonist-like effects on estrous cyclicity. Separate groups of reproductively senescent female Fischer 344 rats (F344) were exposed via vapor inhalation to D4 (700ppm, 9.3mg/L) or D5 (160ppm, 2.1mg/L) or to a diet containing 0.0045, 0.045, or 4.5ppm pergolide mesylate (PM), a potent dopamine agonist used here as a reference substance, from 11 through 24 months of age. The primary focus was to characterize the effects of D4 and D5 exposure on estrous cyclicity relative to that observed with PM. As a monitoring effort, circulating endogenous estradiol, progesterone, prolactin and corticosterone levels were evaluated monthly. A blood sample from each rat was obtained via tail vein in the afternoon after the daily inhalation exposure period once every 4 weeks. Histomorphologic examination of the major organs including the reproductive tract was conducted on all animals at study termination. This study has shown that chronic exposure to D4 and D5 can affect cyclicity in the reproductively senescent F344 rat. For each substance the effect on cyclicity involved reduction in the incidence of pseudopregnancy with a shift toward cycles more typical of younger animals. D4 and D5 induced an increase in estrous cycle repetition whereas D4 also increased the incidence of extended estrus. These shifts resulted in animals entering proestrus/estrus significantly more times over the duration of the study than seen in the control group. Similar effects were observed with the reference substance, PM. However, distinct differences in the timing and magnitude of the effects on the estrous cycle and impact on prolactin, progesterone, estradiol, and corticosterone suggest that D4 and D5 are not classical dopamine agonists even though a similar increased incidence of proestrus/estrus was also observed with PM. These results may prove important with respect to understanding D4- and D5-induced uterine tumor response in the F344 rat, given the relationship between increased incidence of uterine endometrium stimulation by endogenous estrogen as a consequence of extended or more frequent proestrus/estrus, uterine tumor risk, and questions of relevance to humans. Recent publications have summarized the existing data on D4 and D5, with emphasis on exploring the biological relevance of the uterine tumors (Klaunig et al., 2016a,b; Franzen et al., 2017; Dekant and Klaunig, 2016; Dekant et al., 2017). The authors concluded that although the mode of action has not yet been fully established, the data, including the findings from this study, indicate that the D4- and D5-induced uterine tumors observed in the rodent chronic bioassays have no relevance for human risk characterization based not only on the distinct species differences in regulation of the reproductive systems, but also the high exposure levels and duration required for expression in rats.