P-glycoprotein modulates aldosterone plasma disposition and tissue uptake

Aldosterone plays an important role in the pathophysiology of numerous cardiovascular disorders including heart failure and hypertension. Because aldosterone's actions are primarily mediated by its interaction with an intracellular mineralocorticoid receptor, factors affecting the cellular uptake and distribution of aldosterone may be important determinants of the hormone's activity. P-glycoprotein (P-gp) is an ATP-binding cassette efflux transporter encoded by the ABCB1 (also known as MDR1) gene in humans. P-gp is expressed on the luminal membrane of the capillary endothelial cells of tissues that are targets for aldosterone, including the brain and heart, where it attenuates cellular uptake of substrates. Recent in vitro evidence indicates P-gp transports aldosterone. Therefore, in this study we tested the hypothesis that P-gp modulates the uptake of aldosterone into the brain and heart by comparing the plasma and tissue distribution of [3H]-aldosterone in wild-type and P-gp-deficient [mdr1a/1b (-/-)] mice. Compared with wild-type mice, [3H]-aldosterone activity in the plasma, brain, and heart was significantly (P < 0.05) higher in the mdr1a/1b (-/-) animals. The area under the plasma or tissue concentration-time curves in the mdr1a/1b (-/-) mice was 2.0, 1.6, and 1.6-fold higher in the brain, heart, and plasma, respectively, than in wild-type controls. Our results demonstrate that P-gp plays an important role in aldosterone plasma disposition and modestly limits its uptake into the brain. The increased exposure of the brain and heart to aldosterone in the absence of P-gp suggests P-gp may play a key role in modulating aldosterone's effects in these organs.     

A lung dosimetry model of vapor uptake and tissue disposition

Inhaled vapors may be absorbed at the alveolar-capillary membrane and enter arterial blood flow to be carried to other organs of the body. Thus, the biological effects of inhaled vapors depend on vapor uptake in the lung and distribution to the rest of the body. A mechanistic model of vapor uptake in the human lung and surrounding tissues was developed for soluble and reactive vapors during a single breath. Lung uptake and tissue disposition of inhaled formaldehyde, acrolein, and acetaldehyde were simulated for different solubilities and reactivities. Formaldehyde, a highly reactive and soluble vapor, was estimated to be taken up by the tissues in the upper tracheobronchial airways with shallow penetration into the lung. Vapors with moderate solubility such as acrolein and acetaldehyde were estimated to penetrate deeper into the lung, reaching the alveolar region where absorbed vapors had a much higher probability of passing through the thin alveolar-capillary membrane to reach the blood. For all vapors, tissue concentration reached its maximum at the end of inhalation at the air-tissue interface. The depth of peak concentration moved within the tissue layer due to vapor desorption during exhalation. The proposed vapor uptake model offers a mechanistic approach for calculations of lung vapor uptake, air:tissue flux, and tissue concentration profiles within the respiratory tract that can be correlated to local biological response in the lung. In addition, the uptake model provides the necessary input for pharmacokinetic models of inhaled chemicals in the body, thus reducing the need for estimating requisite parameters.     

Stimulation of protein and RNA synthesis by methylmercury chloride in the liver of intact and adrenalectomized rats

(1) A single injection of methylmercury chloride in the rat (10–50 mg/kg) increased both in vivo and in vitro rates of ¹⁴C-leucine incorporation into the protein of the post-mitochondrial supernatant fraction of the liver. In contrast, no stimulation of protein synthesis was observed in the brain of the methylmercury-treated rats. (2) Methylmercury administration also stimulated RNA polymerase activities in isolated hepatic nuclei, stimulation of Mg-dependent activity being higher than that of Mn-dependent activity. (3) In experiments with adrenalectomized rats, it was found that the stimulatory effect of methylmercury on protein and RNA synthesis in the liver was mediated partly through the adrenal gland. (4) Analysis of serum by starch-block electrophoresis revealed that synthesis of all serum proteins, including albumin and - globulin fractions, was stimulated by methylmercury treatment. (5) These results suggest that the observed effects of methylmercury on the liver depend on mechanisms other than enhancement of the synthesis of acute-phase proteins.This work was supported in part by a grant from the Japanese Environmental Agency and by the Grand-in-Aid for Scientific Research from the Ministry of Education of Japan     

Loperamide modifies the tissue disposition kinetics of ivermectin in rats

Ivermectin (IVM) is a broad-spectrum antiparasitic drug extensively used in human and veterinary medicine that is largely excreted in bile and faeces. Loperamide (LPM) is an opioid derivative that reduces gastrointestinal secretions and motility. Both IVM and LPM have been reported to act as P-glycoprotein substrates (P-GP). The goal of the present work was to study the LPM-induced modifications to the pattern of tissue distribution for IVM. Thirty-six Wistar male rats were randomly allocated to two groups (n = 18) and treated subcutaneously with IVM alone or co-administered with LPM. Rats were killed at different times post-treatment and samples (blood and tissues) were collected and analyzed by HPLC. The presence of LPM induced a marked enhancement in the IVM plasma concentrations, resulting in a significantly higher area under concentration time curve (AUC) value (P < 0.01) than that obtained after the administration of IVM alone. Significantly higher IVM availabilities in the liver tissue and small intestine wall (P < 0.05) were obtained in the presence of LPM. There were no statistically significant differences in drug availability in the large intestinal wall after both treatments. However, LPM induced a marked decrease in the amount of IVM recovered in the large intestinal lumen content. The ratio between IVM concentrations in the large intestinal luminal content and plasma at day 1 post-treatment was 4.64-fold higher in the absence of LPM. The delayed intestinal transit time caused by LPM accounting for an extended plasma-intestine recycling time, and a potential competition between IVM and LPM for the P-GP-mediated bile-intestinal secretion processes, may account for the enhanced IVM systemic availability reported in the current study.     

Triethylphosphine gold: Cellular uptake and disposition after single and repeated oral doses in rats

The tissue and subcellular pharmacokinetics of gold following single and repeated oral doses of triethylphospine gold (auranofin) has been studied in rats. After a single dose, the tissue and subcellular gold levels were 5–10 times lower than those reached with injectable gold compounds. In the liver tissues, gold concentrations peaked within 24 h followed by a biphasic clearance, with an initial rapid phase (t1/2 32 h) and a slow terminal phase (t1/2 11 days). Renal gold concentrations continued to increase for 3 to 5 days and then decreased exponentially with a first order t1/2 of about 7 days. Intracellularly, between 60–80% of hepatic and 50–70% of renal gold was present in the cytosol. In rats given repeated doses of auranofin, the hepatic and renal gold concentrations were 3–5 times higher than those measured after a single dose. The proportion of cellular gold present in the cytosol was markedly lower, with 43% in the liver and 30% in kidney tissues. In both the liver and kidney, gold concentrations were dose-dependent, whereas in the gastrointestinal tissues the increases as a function of dose were minimal.     

Pharmacokinetic disposition and tissue distribution of bisphenol A in rats after intravenous administration

This study examined the dose-linearity pharmacokinetics of bisphenol A, a U.S. Environmental Protection Agency (EPA) classified endocrine disruptor, in rats following iv administration. Upon iv injection of 0.2, 0.5, 1, or 2 mg/kg, serum levels of bisphenol A declined biexponentially, with mean initial distribution and elimination half-life ranges of 4-8.2 min and 38.6-62.2 min, respectively. There were no significant alterations in the systemic clearance rate (mean range 90.1-123.6 ml/min/kg) and the steady-state volume of distribution (mean range 4.6-6.0 L/kg) as a function of the administered dose. In addition, the area under the serum concentration-time curve linearly rose as the dose was increased. In a second study, bisphenol A was given by simultaneous iv bolus injection plus infusion to steady state, and levels were measured in serum and various organs. When expressed in concentration terms (e.g., amount accumulated per gram organ weight), bisphenol A was found predominantly in the lung, followed by kidneys, thyroid, stomach, heart, spleen, testes, liver, and brain. Ratios of the organ to serum bisphenol A concentrations exceeded unity for all the organs examined (ratio range 2.0-5.8) except for brain (ratio 0.75). Given the high systemic clearance and short elimination half-life, bisphenol A is unlikely to accumulate significantly in the rat.     

Pulmonary disposition of serotonin in the intact animal

Trace doses of [³H]serotonin ([³H]5-HT) administered intravenously to mice accumulated rapidly in the lungs and were subsequently retained unchanged for long periods of time. Although maximal [³H]5-HT levels achieved in animals killed by stunning were approximately three times higher than after decapitation, the plasma decay curves, beginning 12 hr after administration, showed a similar first-order monophasic decay with half-lives ($\text{T}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}$) of 108–120 hr). Examination of lung extracts obtained from mice sacrificed at time points ranging from 15 min to 1 week after [³H]5-HT injection revealed the presence of small quantities of a single metabolite, 5-hydroxyindole-3-acetic acid. No difference in [³H]5-HT levels was observed in platelet “rich” and platelet “poor” plasma fractions when the number of platelets in the two fractions varied from 7.5 to 1, respectively. Reserpine was shown to markedly deplete pulmonary [³H]5-HT levels, while guanethidine was without effect.     

Comparison of distributed and compartmental models of drug disposition: assessment of tissue uptake kinetics

The utility of a circulatory three-compartment model for the assessment of tissue uptake kinetics is tested by comparison with the respective distributed models using pharmacokinetic data of rocuronium in patients These minimal physiologically based models have a common structure consisting of two subsystems representing the lung and the lumped systemic circulation, with two regions, the vascular and tissue space. The distributed models are based on either diffusion-limited tissue distribution, permeability-limited tissue uptake or the assumption of an empirical transit time density function. With a deviation in the estimate of the permeability-surface area product (PS) of about 18 %, the compartmental approach appears as a useful alternative on condition that a priori knowledge of cardiac output is included. It is also shown that the distribution clearance calculated from the parameters of a mammillary compartment model changes proportional to PS and can be used as an indirect measure of permeability-limited tissue uptake of drugs.     

Dose-dependent pharmacokinetics of prednisolone in normal and adrenalectomized rats

The pharmacokinetics of prednisolone after 5- and 50-mg/kg doses given as the sodium succinate salt was examined in normal and adrenalectomized rats. Prednisolone, prednisone, and corticosterone concentrations in plasma were determined by HPLC and free prednisolone measured by equilibrium dialysis. Prednisolone sodium succinate was rapidly and completely hydrolyzed to prednisolone as indicated by the absence of the ester from plasma within 5 min after intravenous injection. Prednisolone was rapidly metabolized to prednisone, while corticosterone concentrations in normal rats declined rapidly and were undetectable by 1 hr. Adrenalectomy had no effect on the disposition and protein binding of prednisolone. Dose, however, had a marked effect on prednisolone pharmacokinetics, with mean plasma clearance decreasing from 6.18 to 3.07 L/h per kg and mean steady-state volume of distribution decreasing from 2.14 to 1.05 L/kg from the lower to higher steroid dose. Half-life (0.50 hr) and mean residence time (0.35 hr) were unaffected by dose. Prednisolone plasma protein binding was nonlinear due to saturation of transcortin binding. Changes in pharmacokinetic parameters were not related to the nonlinear plasma binding, but were more likely caused by saturation of elimination pathways and tissue binding sites.     

Dose-dependent pharmacokinetics of prednisolone in normal and adrenalectomized rats

The pharmacokinetics of prednisolone after 5- and 50-mg/kg doses given as the sodium succinate salt was examined in normal and adrenalectomized rats. Prednisolone, prednisone, and corticosterone concentrations in plasma were determined by HPCL and free prednisolone measured by equilibrium dialysis. Prednisolone sodium succinate was rapidly and completely hydrolyzed to prednisolone as indicated by the absence of the ester from plasma within 5 min after intravenous injection. Prednisolone was rapidly metabolized to prednisone, while corticosterone concentrations in normal rats declined rapidly and were undetectable by 1 hr. Adrenalectomy had no effect on the disposition and protein binding of prednisolone. Dose, however, had a marked effect on prednisolone pharmacokinetics, with mean plasma clearance decreasing from 6.18 to 3.07 L/h per kg and mean steady-state volume of distribution decreasing from 2.14 to 1.05 L/kg from the lower to higher steroid dose. Half-life (0.50 hr) and mean residence time (0.35 hr) were unaffected by dose. Prednisolone plasma protein binding was nonlinear due to saturation of transcortin binding. Changes in pharmacokinetic parameters were not related to the nonlinear plasma binding, but were more likely caused by saturation of elimination pathways and tissue binding sites.Supported in part by grant GM-24211 from the National Institutes of General Medical Sciences, NIH.     

Ethosuximide disposition kinetics in rats

1. Single and multiple dose disposition kinetics of ethosuximide were studied in male Sprague-Dawley rats following intravenous administration. 2. The plasma disappearance of a single 35 mg/kg dose followed for 75 h was not linear. A dose-ranging study suggested that the apparent non-linearity of ethosuximide's plasma disappearance might be due to enzyme induction over time with the drug exhibiting a faster elimination from 24 h onward. 3. Ethosuximide, after only two daily doses of 35 mg/kg/day, shortened pentobarbital-induced sleep in rats. The clearance of ethosuximide was also significantly faster after four daily 35 mg/kg doses than after a single 35 mg/kg dose. 4. Single sample clearance estimates calculated from ethosuximide concentrations prior to enzyme induction, viz. up to 24 h post-dose, were practically identical to multiple sample clearance values. Both single and multiple sample clearances were calculated assuming linear rather than non-linear elimination.     

Pharmacokinetics and tissue disposition of danofloxacin in sheep

The plasma pharmacokinetics of danofloxacin administered at 1.25 mg kg⁻¹ body weight by the intravenous and intramuscular routes were determined in sheep. Tissue distribution was also determined following administration by the intramuscular route at 1.25 mg kg⁻¹ body weight. Danofloxacin had a large volume of distribution at steady state (V_ss) of 2.76±0.16 h (mean±S.E.M.) L kg⁻¹, an elimination half-life (t_1/2β) of 3.35±0.23 h, and a body clearance (C1) of 0.63±0.04 L kg⁻¹ h⁻¹. Following intramuscular administration it achieved a maximum concentration (C_max) of 0.32±0.02 μg mL⁻¹ at 1.23±0.34 h (t_max) and had a mean residence time (MRT) of 5.45±0.19 h. Danofloxacin had an absolute bioavailability (F) of 95.71±4.41% and a mean absorption time (MAT) of 0.81±0.20 h following intramuscular administration. Mean plasma concentrations of >0.06 μg mL⁻¹ were maintained for more than 8 h following intravenous and intramuscular administration. Following intramuscular administration highest concentrations were measured in plasma (0.43±0.04 μg mL⁻¹), lung (1.51±0.18 μg g⁻¹), and interdigital skin (0.64±0.18 μg g⁻¹) at 1 h, duodenal contents (0.81±0.40 μg mL⁻¹), lymph nodes (4.61±0.35 μg g⁻¹), and brain (0.06±0.00 μg mL⁻¹) at 2 h, jejunal (10.50±4.31 μg mL⁻¹) and ileal (5.25±1.67 μg mL⁻¹) contents at 4 h, and colonic contents (8.94±0.65 μg mL⁻¹) at 8 h. © 1998 John Wiley & Sons, Ltd.     

Prolonged hypothermia after phenobarbital-induced anesthesia in adrenalectomized rats

Adrenalectomized rats are hypersensitive to the hypothermic as well as hypnotic effects of phenobarbital. The exaggerated hypnotic response is more pronounced in the chronic (10 day) than the acute (1 day) adrenalectomized rat and is reversed by glucocorticoid replacement. The prolonged hypothermia to a hypnotic dose of phenobarbital occurs in adrenalectomized but not adrenodemedullated rats. This hypersensitivity is characterized by an impaired ability to regain normal body temperatures for as long as 24 hours after regaining the righting reflex. The prolonged hypothermia is prevented by prior treatment with glucocorticoids but not mineralocorticoids. There appears to be no gross alteration in disposition of phenobarbital following adrenalectomy suggesting that the prolonged duration of hypothermia is not a consequence of accumulation of the drug.