Your search keyword '"Pang, K S"' showing total 11 results

1. Uptake of enalapril and expression of organic anion transporting polypeptide 1 in zonal, isolated rat hepatocytes.

Author

Abu-Zahra TN, Wolkoff AW, Kim RB, and Pang KS

Subjects

Animals, Anion Transport Proteins, Humans, In Vitro Techniques, Liver cytology, Male, Rats, Rats, Sprague-Dawley, Angiotensin-Converting Enzyme Inhibitors pharmacokinetics, Carrier Proteins metabolism, Enalapril pharmacokinetics, Liver metabolism

Abstract

Sinusoidal entry is the first obligatory process preceding intracellular drug removal in liver. Transport of the angiotensin converting enzyme inhibitor enalapril (1-750 microM with [(3)H]enalapril), a substrate of Oatp1, the sodium-independent organic anion transporting polypeptide 1 cloned from rat liver, was studied in rat hepatocytes isolated from all zones of the liver (homogeneous) and from enriched periportal (PP) and perivenous (PV) hepatocytes prepared by collagenase perfusion and zone-selective destruction with digitonin, respectively. Uptake was linear over 1 min and was concentration-dependent. Transport by the homogeneous hepatocytes (in the presence and absence of Na(+)) and PP and PV cells was described by single saturable components of similar kinetic constants (K(m) values of 344-461 microM and V(max) values of 9.5-11.6 nmol/min/10(6) cells; P >.05, ANOVA). The K(m) value for enalapril uptake in hepatocytes was of the same order of magnitude compared with that for Oatp1 expressed in HeLa cells transfected with cDNA-Oatp1 and Western blot analysis revealed similar levels of immunoreactive Oatp1 expression in PP and PV hepatocytes. However, enalapril was not taken up by Oatp2 nor by the human OATP expressed in recombinant vaccinia systems.

Published

2000

2. Effect of zonal transport and metabolism on hepatic removal: enalapril hydrolysis in zonal, isolated rat hepatocytes in vitro and correlation with perfusion data.

Author

Abu-Zahra TN and Pang KS

Subjects

Animals, Biotransformation, In Vitro Techniques, Male, Perfusion, Rats, Rats, Sprague-Dawley, Angiotensin-Converting Enzyme Inhibitors pharmacokinetics, Enalapril pharmacokinetics, Liver metabolism

Abstract

Previous studies showed that the transport of enalapril occurred homogeneously among zonal rat hepatocytes. However, the metabolism of hepatic arterially delivered enalapril, swept into the rat liver by the portal or hepatic venous flow (HAPV and HAHV perfusion), was more abundant in the perivenous (PV) than the periportal (PP) region. Hence, metabolic activities toward enalapril in 9000g supernatant (S9) fractions of enriched rat PP and PV hepatocytes were examined. Although Michaelis-Menten kinetics were invariably observed, the metabolic activity toward enalapril (intrinsic clearance or V(max)(met)/K(m)(met) of 0.008 ml/min/mg of S9 protein, V(max)(met) of 21 +/- 6 nmol/min/mg of S9 protein, and K(m)(met) of 2612 +/- 236 microM) was greater in PV than in PP (V(max)(met) of 5.5 +/- 3.1 nmol/min/mg of S9 protein and K(m)(met) of 1049 +/- 335 microM; intrinsic clearance of 0.0052 ml/min/mg of S9 protein) hepatocytes. These metabolic intrinsic clearances were much lower than the sinusoidal influx clearances observed from previous transport studies, revealing metabolism as the rate-limiting step. Substitution of the scaled-up transport and metabolic intrinsic clearances into the "well stirred", "parallel-tube", and "dispersion" models predicted higher steady-state extraction ratios for HAHV perfusion. By contrast, integration of the scaled-up in vitro parameters on zonal metabolism and homogeneous transport into a "zonal-compartment" model of three zonal subcompartments (1, 2, and 3) provided an improved description of the extraction ratios during HAPV and HAHV. Zonal factors are important for the scale-up of data in vitro to the whole organ.

Published

2000

3. Inhibition of esterolysis of enalapril by paraoxon increases the urinary clearance in isolated perfused rat kidney.

Author

Sirianni GL and Pang KS

Subjects

Algorithms, Angiotensin-Converting Enzyme Inhibitors urine, Animals, Cell Survival drug effects, Chromatography, Thin Layer, Enalapril urine, Enalaprilat metabolism, Enalaprilat urine, In Vitro Techniques, Kidney drug effects, Kidney enzymology, Male, Rats, Rats, Sprague-Dawley, Subcellular Fractions drug effects, Subcellular Fractions metabolism, Angiotensin-Converting Enzyme Inhibitors metabolism, Cholinesterase Inhibitors pharmacology, Enalapril metabolism, Kidney metabolism, Paraoxon pharmacology

Abstract

The effect of competing elimination pathways on the metabolic and excretory clearance estimates was examined with tracer concentrations of [(3)H]enalapril, which was both metabolized and excreted by the rat kidney. Perturbation was achieved with use of the carboxylesterase inhibitor paraoxon, which inhibited [(3)H]enalapril metabolism to [(3)H]enalaprilat in rat renal S9 fraction. At 0.1, 0.5, 1, and 10 microM paraoxon, esterolysis of enalapril was inhibited by 76 +/- 7, 93 +/- 5, 96 +/- 5, and 93 +/- 6%, respectively. The lowest concentration (0.1 microM) of paraoxon was chosen for single-pass isolated perfused kidney (IPK) studies because viability was least compromised, and the sodium and glucose reabsorptive functions of the IPK remained constant. After an equilibration period (15-20 min at constant pressure, 90-100 mm Hg), perfusion of the rat kidney with [(3)H]enalapril was carried out under constant flow (8 ml/min) for 30 min in the absence and presence of paraoxon (0.1 microM). The metabolic (from 1.83 +/- 0.52 to 1.48 +/- 0.47 ml/min/g) and total renal (from 1.87 +/- 0.46 to 1. 57 +/- 0.41 ml/min/g) clearances of [(3)H]enalapril in the IPKs were decreased significantly (p <.05) in the presence of paraoxon when compared with controls. Concomitantly, the urinary clearance (from 0. 04 +/- 0.07 to 0.09 +/- 0.09 ml/min/g) and the fractional excretion (from 0.23 +/- 0.18 to 0.52 +/- 0.25) of [(3)H]enalapril doubled (p <.05). The study illustrates that a reduction in cellular metabolism of the kidney brings forth a rise in the estimate of clearance of its complimentary pathway, estimate of the excretory (urinary) clearance.

Published

1999

4. The modified dipeptide, enalapril, an angiotensin-converting enzyme inhibitor, is transported by the rat liver organic anion transport protein.

Author

Pang KS, Wang PJ, Chung AY, and Wolkoff AW

Subjects

Animals, Anion Transport Proteins, Anions, Biological Transport drug effects, Carbon Radioisotopes, Carrier Proteins genetics, Estrone analogs & derivatives, Estrone metabolism, Gene Expression drug effects, Glutathione metabolism, HeLa Cells, Humans, Promoter Regions, Genetic, Rats, Sulfobromophthalein metabolism, Sulfobromophthalein pharmacology, Taurocholic Acid pharmacology, Taurolithocholic Acid metabolism, Transfection, Tritium, Zinc pharmacology, Angiotensin-Converting Enzyme Inhibitors metabolism, Carrier Proteins metabolism, Enalapril metabolism

Abstract

Oatp1, the organic anion transport polypeptide, is an integral membrane protein cloned from rat liver that mediates the uptake of various organic anions such as bromosulfophthalein (BSP) and taurocholate (TCA). Recent studies by others revealed that the thrombin inhibitor, CRC 220, a modified dipeptide, was transported by oatp1. The present study was designed to examine whether another modified peptide, enalapril, an angiotensin-converting enzyme inhibitor, was also a substrate. Transport was studied with enalapril (1 to 800 micromol/L, with [3H]enalapril) in a HeLa cell line stably transfected with oatp1-cDNA under the regulation of a Zn2+-inducible promoter. Noninduced transfected cells (without zinc) that did not express oatp1 failed to take up enalapril. In contrast, cells expressing oatp1 transported enalapril, estrone sulfate (E1S), taurolithocholic acid sulfate (TLCAS), and the glutathione conjugate of BSP (BSPGSH). Uptake of enalapril by oatp1 at 37 degreesC was substantially higher than that at 4 degreesC. The rate at 37 degreesC (uptake rates for induced - noninduced, transfected cells) was linear over 5 minutes and was concentration-dependent, characterized by a Km of 214 +/- 67 micromol/L and a Vmax of 0.51 +/- 0.15 nmol/min/mg protein. Enalapril uptake was inhibited competitively by BSP (at 1, 5, 10, and 50 micromol/L) and TCA (at 5, 25, and 100 micromol/L) with inhibition constants (Ki) of 2 and 32 micromol/L, respectively. The metabolite enalaprilat was, however, not transported by oatp1. That oatp1 is not a general transporter of anionic compounds was further shown by the lack of transport of harmol sulfate, benzoate, and hippurate. These observations attest to the role of oatp1 as a specific transporter for at least two classes of pharmacologically important peptides.

Published

1998

5. Intracellular and not intraluminal esterolysis of enalapril in kidney. Studies with the single pass perfused nonfiltering rat kidney.

Author

Sirianni GL and Pang KS

Subjects

Animals, Hydrolysis, In Vitro Techniques, Male, Models, Biological, Perfusion, Rats, Rats, Sprague-Dawley, Angiotensin-Converting Enzyme Inhibitors metabolism, Enalapril metabolism, Kidney metabolism

Abstract

Two possible sites of renal metabolism exist: intracellular, by enzymes within the peritubular cells, and intraluminal, by ecto-enzymes embedded on the brush border membrane. The esterolysis of enalapril to its dicarboxylate metabolite, enalaprilat, was studied in the isolated perfused, nonfiltering rat kidney preparation (NFK) and compared with that observed for the isolated perfused rat kidney (IPK) to ascertain the site of metabolic conversion. For the NFK, filtration was obliterated with the high oncotic pressure (8% bovine serum albumin in plasma) and ligation of the ureter, thus preventing enalapril from reaching intraluminal sites by filtration. The steady-state renal plasma clearance of enalapril in the NFK was 2.0 ml/min/g, a value similar to that (2.1 ml/min/g) observed previously for the IPK. The rate of appearance of enalaprilat, the metabolite, in venous plasma for the NFK (30 +/- 3% of the input rate of enalapril) was also comparable with that for the IPK (27 +/- 4%). Further, identification of the site of enalapril metabolism (cellular or luminal) was aided by simulations based on physiological models and parameters obtained previously on the renal handling of enalapril and enalaprilat. These parameters were optimized to match closely the experimental observations. The predicted total and metabolic renal clearances for the IPK or for the NFK were similar for both the "cellular model" and "luminal model": in both instances, values for the NFK were 59-65% of those for the IPK. By contrast, predictions for the venous output rate of enalaprilat (as a percent of the input rate of enalapril) were different: the "cellular model" predicted no change in value between the NFK and the IPK, whereas metabolite appearance was greatly magnified for the NFK (289% that of the IPK) with luminal metabolism. The lack of difference in venous outflow of enalaprilat for the NFK and IPK was more congruent with the notion of intracellular and not intraluminal esterolysis of enalapril.

Published

1998

6. Formed and preformed metabolite excretion clearances in liver, a metabolite formation organ: studies on enalapril and enalaprilat in the single-pass and recirculating perfused rat liver.

Author

de Lannoy IA, Barker F 3rd, and Pang KS

Subjects

Animals, Bile metabolism, Computer Simulation, Male, Metabolic Clearance Rate, Models, Biological, Oxygen Consumption, Rats, Rats, Sprague-Dawley, Enalapril metabolism, Enalapril pharmacokinetics, Enalaprilat metabolism, Liver metabolism

Abstract

Single-pass and recirculating rat liver perfusion studies were conducted with [14C]enalapril and [3H]enalaprilat, a precursor-product pair, and the data were modeled according to a physiological model to compare the different biliary clearances for the solely formed metabolite, [14C]enalaprilat, with that of preformed [3H]enalaprilat. With single-pass perfusion, the apparent extraction ratio (or biliary clearance) of formed [14C]enalaprilat was 15-fold the extraction ratio of preformed [3H]enalaprilat, an observation attributed to the presence of a barrier for cellular entry of the metabolite. Upon recirculation of bolus doses of [14C]enalapril and [3H]enalaprilat, the biliary clearance, estimated conventionally as metabolite excretion rate/midtime metabolite concentration, for formed [14C]enalaprilat was again 10- to 15-fold higher than the biliary clearance for preformed [3H]enalaprilat, but this decayed with perfusion time and gradually approached values for preformed [3H]enalaprilat. The decreasing biliary clearance of formed enalaprilat with recirculation was explained by the dual contribution of the circulating and intrahepatic metabolite (formed from circulating drug) to excretion. Physiological modeling predicted (i) an influx barrier (from blood to cell) at the sinusoidal membrane as the rate-limiting process in the overall removal of enalaprilat, (ii) a 15-fold greater extraction ratio or biliary clearance for formed [14C]enalaprilat over [3H]enalaprilat during single-pass perfusion, and (iii) the time-dependent and declining behaviour of the biliary clearance for formed [14C]enalaprilat during recirculation of the medium. In the absence of a direct knowledge of eliminating organs in vivo, this variable pattern for excretory clearance of the formed metabolite within the organ is indicative of a metabolite formation organ.

Published

1993

7. Combined recirculation of the rat liver and kidney: studies with enalapril and enalaprilat.

Author

de Lannoy IA and Pang KS

Subjects

Animals, Computer Simulation, Glomerular Filtration Rate, Male, Metabolic Clearance Rate, Models, Biological, Perfusion, Rats, Rats, Sprague-Dawley, Enalapril metabolism, Enalapril pharmacokinetics, Enalaprilat metabolism, Enalaprilat pharmacokinetics, Kidney metabolism, Liver metabolism

Abstract

Combined recirculation of the rat liver (L) and kidney (IPK) at 10 ml min-1 per organ (LK) was developed to examine the hepatorenal handling of the precursor-metabolite pair: [14C]-enalapril and [3H]enalaprilat. Loading doses followed by constant infusion of [14C]enalapril and preformed [3H]enalaprilat to the reservoirs of the IPK or the LK preparation was used to achieve steady state conditions. In both organs, enalapril was mostly metabolized to its dicarboxylic acid metabolite, enalaprilat, which was excreted unchanged. At steady state, the fractional excretion for [14C]enalapril (FE = 0.45 to 0.48) and preformed [3H]enalaprilat (FE[pmi] = 1.1) were constant and similar for both the IPK and LK. The additivity of clearance was demonstrated in the LK preparation, namely, the total clearance of enalapril was the sum of its hepatic and renal clearances. However, the apparent fractional excretion for formed [14C]enalaprilat, FE(mi) and the apparent urinary clearance were time-dependent and higher than the corresponding values for preformed [3H]enalaprilat in both the IPK and LK. The FE(mi) and urinary clearance values further differed between the IPK and LK. Biliary clearance of formed vs. preformed enalaprilat displayed the same discrepant trends as observed for FE(mi) vs. FE(pmi) for the LK. These observations on the time-dependent and variable excretory clearance (urinary or biliary) of the formed metabolite vs. the constant, and much reduced, excretory clearance of the preformed metabolite are due to dual contributions to formed metabolite excretion: the nascently formed, intracellular metabolite which immediately underwent excretion and the formed metabolite which reentered the circulation, behaved as a preformed species. When data for the IPK and LK preparations were modeled with a physiological model with parameters previously reported for the L and IPK, all data, including metabolite excretory clearances, were well predicted. Model simulations revealed that the apparent FE(mi) differed between the LK and IPK preparations when the liver was present as an additional metabolite formation organ; the apparent excretory (urinary or biliary) clearance of the formed metabolite was further modulated by the volume of distribution of the metabolite, which altered levels of the formed, circulating metabolite.

Published

1993

8. Esterases for enalapril hydrolysis are concentrated in the perihepatic venous region of the rat liver.

Author

Pang KS, Barker F 3rd, Cherry WF, and Goresky CA

Subjects

Animals, Cobalt metabolism, Edetic Acid metabolism, Enalaprilat metabolism, Hepatic Artery, Hepatic Veins, Hydrolysis, Male, Perfusion, Portal Vein, Rats, Rats, Inbred Strains, Tissue Distribution, Carboxylic Ester Hydrolases analysis, Enalapril metabolism, Liver enzymology

Abstract

Perfusion of substrate via only the hepatic artery with simultaneous substrate-free perfusion of portal vein or hepatic vein [hepatic artery portal vein-hepatic artery hepatic vein] was used to examine the enzymic distribution of carboxylesterases towards the hydrolysis of enalapril to enalaprilat in the perfused rat liver preparation. In this single-pass method, [14C]enalapril was delivered by the hepatic artery at 2 ml/min into the liver, whereas drug-free perfusate entered the portal vein or hepatic vein at 10 ml/min for HAPV and HAHV perfusions, respectively. During steady state, a multiple indicator dose of 51Cr-labeled red blood cells (vascular marker), [58Co]EDTA (interstitial space marker, which behaves similarly to labeled tracer sucrose), and 3H2O was given into the hepatic artery. Labeled enalapril and the reference indicators entering via the hepatic artery will reach virtually all sinusoidal spaces during HAPV, and will be confined to the peripheral region during HAHV. By defining the steady-state extraction ratios of enalapril (Etot) and segregating the components of biliary excretion and metabolism, and by assessing the intracellular water spaces and the corresponding transit times during HPAV and HAHV, the metabolic sequestration rate constant (metabolic intrinsic clearance per unit accessible cell water space) for the periportal region/whole liver (HAHV/HAPV) was 0.344. The data suggest that the carboxylesterase activity for enalapril conversion to enalaprilat is primarily localized in the perihepatic venous region of the rat liver.

Published

1991

9. A physiological model for renal drug metabolism: enalapril esterolysis to enalaprilat in the isolated perfused rat kidney.

Author

de Lannoy IA, Hirayama H, and Pang KS

Subjects

Animals, Computer Simulation, Enalapril blood, Enalapril pharmacokinetics, Esters metabolism, Glomerular Filtration Rate, In Vitro Techniques, Models, Biological, Perfusion, Rats, Enalapril metabolism, Enalaprilat metabolism, Kidney metabolism

Abstract

A physiologically based kidney model was developed to describe the metabolism of enalapril and explain the observed discrepancies between generated and preformed enalaprilat (metabolite) elimination in the constant flow single-pass and recirculating isolated perfused rat kidney preparations (IPKs) as a result of the differing points of origin of the metabolite within the kidney, subsequent to the simultaneous delivery of 14C-enalapril and 3H-enalaprilat. The model incorporated clearances for diffusion/transport of drug and metabolite across the basolateral and luminal membranes of the renal cells, an intrinsic clearance for renal drug metabolism, in addition to physiological variables such as perfusate flow rate, glomerular filtration rate, and urine flow rate. Nonlinear curve fitting of single-pass and recirculating data was performed to estimate the rate-limiting step in the renal elimination of enalaprilat. Through fitting and simulation procedures, we were able to predict metabolic and excretory events for enalapril (renal extraction ratio approximately equal to 0.25-0.3; fractional excretion, FE, was less than unity) and the relatively constant pattern of urinary excretion of preformed enalaprilat (extraction ratio approximately equal to 0.07; FE approximately equal to 1). The extraction ratio of the intrarenally formed enalaprilat in single-pass IPK was about twofold that for the preformed metabolite, whereas the FEs of generated enalaprilat in recirculating IPKs were greater than 1, and tended to increase, then decrease with perfusion time. These observations were explained by the optimized parameters which indicated that efflux from cell to lumen was rate-controlling in the excretion of enalaprilat, and another small transport barrier also existed at the basolateral membrane; the lower extraction ratio of preformed enalaprilat was due to its poor transmembrane clearance at the basolateral membrane. The variable FEs for generated enalaprilat vs. the relatively constant FE for preformed metabolite in the recirculating IPK was explained by the changing contributions of both circulating and intrarenal metabolite to metabolite excretion.

Published

1990

10. Presence of a diffusional barrier on metabolite kinetics: enalaprilat as a generated versus preformed metabolite.

Author

de Lannoy IA and Pang KS

Subjects

Animals, Computer Simulation, Diffusion, Enalapril metabolism, Enalaprilat, Kinetics, Metabolic Clearance Rate, Models, Biological, Perfusion, Rats, Bile metabolism, Enalapril analogs & derivatives, Liver metabolism

Abstract

Studies in the once-through perfused rat liver with the simultaneous delivery of 14 C-enalapril and its polar diacid metabolite, 3H-enalaprilat, revealed different extents of elimination (exclusively by biliary excretion) for the generated (14C-enalaprilat) and preformed (3H-enalaprilat) metabolite (18 and 5% dose) [Pang, Cherry, Terrell, and Ulm: Drug Metab. Dispos. 12, 309-313 (1984)]. The present re-examination of data provided an explanation for these discrepant observations: enalaprilat, being a polar dicarboxylic acid, encounters more of a diffusional barrier than its precursor, enalapril, an ethyl ester of enalaprilat. Programs written in Fortran 77 on mass balance relationships were employed to simulate data upon varying the diffusional clearances for drug (CLd) and metabolite [CLd(mi)] from 1 to 5000 ml/min. The metabolic and biliary intrinsic clearances for drug and metabolite were found by trial and error such that the combinations of all clearance parameters yielded data similar to enalaprilat, and 3H-enalaprilat. Our finding indicated that the diffusional clearance for enalaprilat was low (2 ml/min) compared to that of enalapril (75 ml/min). The presence of a diffusional barrier for enalaprilat retards entry of the preformed metabolite into hepatocytes but prevents efflux of the intracellularly formed generated metabolite into sinusoidal blood, thereby enhancing generated metabolite elimination.

Published

1986

11. Renal handling of enalapril and enalaprilat: studies in the isolated red blood cell-perfused rat kidney.

Author

de Lannoy IA, Nespeca R, and Pang KS

Subjects

Animals, Blood Proteins metabolism, Dose-Response Relationship, Drug, Erythrocytes, Male, Metabolic Clearance Rate, Perfusion, Protein Binding, Rats, Rats, Inbred Strains, p-Aminohippuric Acid pharmacokinetics, Enalapril pharmacokinetics, Enalaprilat pharmacokinetics, Kidney metabolism

Abstract

An isolated recirculating or single pass red cell-perfused rat kidney preparation (IPK) was used to examine the differential handling of renal metabolites. In single pass experiments, enalapril was primarily metabolized to its polar, dicarboxylic acid metabolite, enalaprilat, and its fractional excretion (FE) was less than unity, suggesting net reabsorption. Its steady-state extraction ratio decreased from 0.3 to 0.2 at concentrations of 1.06 to 12.7 microM, due to a saturation of enzymes for esterolysis. Enalaprilat administered to the IPK was excreted into urine in a concentration-independent (0.41-35.3 microM) fashion, with FE values approximating unity, suggesting net filtration. Differences in handling were observed for enalaprilat, as a metabolite formed from enalapril and as an administered (preformed) species in the single pass IPK, when tracer concentrations of [14C]enalapril and [3H]enalaprilat were given simultaneously. A comparison made between steady-state extraction ratio Ess[mi] [generated metabolite]/glomerular filtration rate (GFR) and Ess[pmi] [preformed metabolite]/GFR, respectively, revealed a 2-fold difference. The finding suggests the presence of a barrier for entry of enalaprilat into the kidney. Or else, in absence of the barrier, the opposite would be observed, that is, Ess [pmi]/GFR greater than Ess [mi]/GFR because preformed enalaprilat, in contrast to generated enalaprilat, undergoes filtration and utilizes facilitative transport carriers at the basolateral membrane. In recirculating IPKs which received simultaneously a tracer bolus dose of [14C]enalapril and [3H]enalaprilat, the FE values for generated [14C]enalaprilat were high and variable, decreasing with perfusion time and exceeding those for preformed [3H]enalaprilat, which approached unity with perfusion time. The variable FE values for [14C]enalaprilat are due to time-dependent contributions of circulating enalaprilat (which behaves identically to preformed enalaprilat) and the intrarenally generated enalaprilat. Hence, with renal drug metabolism, the conventional method of estimating urinary clearance (or Fe[mi]) for the metabolite [(total) excretion rate/midpoint plasma FE[mi] metabolite concentration] results in a greater metabolite clearance than that predicted from the administration of preformed metabolite.

Published

1989