Kinetics of d-tubocurarine disposition and pharmacologic response in rats

After bolus intravenous dosing of d-tubocurarine (d-TC) to rats, the twitch heights of the tibialis anterior muscle indirectly stimulated were followed, and its decrease was defined as pharmacologic response of d-TC. The relation between dose and response intensity was found to be well described with Hill's equation. According to a theory proposed by Smolen, Hill's equation was also applicable to the biophase d-TC concentration-response relation; the time courses of the relative biophase d-TC concentration indicated linear kinetics with dose levels 0.15 mg/kg and the occurrence of dose-dependent disposition with 0.30 mg/kg. After bolus i.v. dosing of³H-d-TC, plasma d-TC concentration obeyed a dose-independent two compartment model with doses 0.15mg/kg, but not with 0.30 mg/kg. This finding matched the above estimated with pharmacologic data. The active metabolite was not found in plasma and urine. The extent of d-TC plasma protein binding was independent of the wide range of plasma levels and its mean (±SD) value was 30.5 (±3.8). Plasma d-TC levels and pharmacologie response intensity were well correlated by Hill's equation and a three compartment model (the general two and the biophase compartments) in the dose range 0.15 mg/kg.This work was presented at the First Japanese-American Symposium on Pharmacokinetics and Biopharmaceutics, Tokyo, July 1981, which was held in memory of Dr. Sidney Riegelman.     

Bioavailability assessment of disopyramide using pharmacokinetic-pharmacodynamic (PK-PD) modeling in the rat

The relationship between the serum concentration and the pharmacological effect of disopyramide was investigated quantitatively to estimate the extent of its oral bioavailability (EBA(p.o.) and to evaluate the drug interaction with miconazole, a CYP3A4 inhibitor. An integrated pharmacokinetic-pharmacodynamic (PK-PD) model was used to describe the relationship between the serum concentrations and changes in QT interval (pharmacological data) of disopyramide after intra-vascular infusion for 15 min (i.v. short-term infusion) to rats. A two-compartment model was applied to the pharmacokinetics of disopyramide. The pharmacological data after short-term infusion were well explained using a PK-PD link model. To validate the present PK-PD model. disopyramide was administered intra-vascularly in separate experiments, and the doses were predicted only from the pharmacological data. The model predicted doses were identical to the actual doses, regardless of the dosing rates. This result indicates that the PK-PD model used in the present study is appropriate, and that the relationship between the serum concentrations and changes in QT intervals is independent of the dosing (input) rate. When miconazole was co-administered orally 1 h before disopyramide infusion, the serum disopyramide concentrations were significantly higher than that following disopyramide alone. The raised serum concentrations under miconazole co-administration were well explained by nonlinear elimination clearance. The pharmacological effects of disopyramide under miconazole co-administration, were also greater than those following disopyramide alone. The results of the PK-PD analysis indicated that the enhanced pharmacological response under miconazole co-administration was simply caused by a pharmacokinetic change. The EBA(p.o.) values estimated from the pharmacological effects predicted the observed values reasonably well. In conclusion, we demonstrated following: (1) the pharmacological effect after intra-vascular administration of disopyramide is related quantitatively to the serum concentrations using a PK-PD model; (2) miconazole affects only the elimination clearance of disopyramide to enhance the pharmacological effect; (3) the EBA of disopyramide can estimated reasonably only well from the pharmacological data using the PK-PD model; (4) there is no dosing-rate-dependent or dosing-route-dependent pharmacological effect of disopyramide.     

Effects of sodium glycocholate and protease inhibitors on permeability of TRH and insulin across rabbit trachea

The permeabilities of thyrotropin-releasing hormone (TRH) and insulin as model peptides were examined to characterize the tracheal epithelial barrier in in vitro experiments using excised rabbit trachea. TRH was not metabolized during 150 min duration of tracheal permeation and the apparent permeability coefficient (Papp) for TRH was about 3 x 10(-7) cm/s. The tracheal permeability of TRH was increased about three times by 10 mM glycocholate as a permeation enhancer. Insulin showed a slight degradation during 150 min duration of tracheal permeation, the Papp for insulin was 7 x 10(-9) cm/s. The tracheal permeability of insulin was significantly increased by 10 mM glycocholate, 1 mM bestatin (aminopeptidase B and leucine aminopeptidase inhibitor), and 10,000 KIU/ml aprotinin (trypsin and chymotrypsin inhibitor). The peptidase activities of rabbit tracheal epithelium were found to be the following; di-peptidyl-aminopeptidase IV (DPP IV) > Leu-aminopeptidase > cathepsin-B > trypsin. These activities were significantly lower than those of jejunal mucosal tissues. These results suggest that the tracheal absorption of peptide drugs through the respiratory tract may contribute to the systemic delivery of these drugs following the pulmonary administration of these drugs by intratracheal insufflation and instillation.     

Chronopharmacological assessment identified GLUT4 as a factor responsible for the circadian variation of the hypoglycemic effect of tolbutamide in rats

The circadian relationship between the pharmacokinetics and pharmacodynamics of tolbutamide in rats was analyzed using a compartment model. The basal concentration of plasma glucose had a circadian rhythm with the acrophase at 15:19 h. After intravenous administration of tolbutamide at 06:00, 14:00, or 18:00 h, the hypoglycemic effect showed a circadian variation, with the greatest effect at 18:00 h and the lowest effect at 06:00 h. The time courses of unbound tolbutamide concentration in plasma after intravenous administration were predicted using the model-estimated total concentration of tolbutamide and the albumin concentration and resulted in profiles that did not vary with the time of administration. Significant low insulin resistance was observed at 18:00 h to i.v. glucose and insulin loads. There was no obvious time dependency in the expression of glucose transporter 4 (GLUT4) in epididymal adipocytes. The hypoglycemic rate estimated from the plasma glucose concentration was described by the conventional pharmacokinetic-pharmacodynamic model with an effect compartment. The time courses of theoretical signals in the effect compartment described the observed circadian changes in the increased expression profile of GLUT4 normalized by the increased plasma insulin (IRI) concentration (ΔGLUT4/ΔIRI) after dosing. Thus, the time dependency in glucose uptake is responsible for the circadian variation of the hypoglycemic effect of tolbutamide.     

Gelatin microspheres as a pulmonary delivery system: evaluation of salmon calcitonin absorption

The use of negatively and positively charged gelatin microspheres for pulmonary delivery of salmon calcitonin was examined in rats. The microspheres were prepared using acidic gelatin (isoelectric point (IEP):, 5.0) and basic gelatin (IEP, 9.0) for the negatively and positively charged microspheres, respectively. The average diameters of positively charged gelatin microspheres in the dry state were 3.4, 11.2, 22.5 and 71.5 microm, and that of negatively charged gelatin microspheres was 10.9 microm. Neither positively nor negatively charged gelatin microspheres underwent any degradation in pH 7.0 PBS and there was less than 8% degradation in bronchoalveolar lavage fluid (BALF) after 8 h. In in-vitro release studies in pH 7.0 PBS, salmon calcitonin was rapidly released from positively charged gelatin microspheres within 2 h, and its cumulative release was approximately 85%. In addition, the release profiles were not influenced by particle sizes. The release rates of salmon calcitonin from negatively charged gelatin microspheres were lower than that from positively charged gelatin microspheres. The cumulative release was approximately 40% after 2 h, but there was no evidence of any sustained release. The pulmonary absorption of salmon calcitonin from gelatin microspheres was estimated by measuring its hypocalcaemic effect in rats. The pharmacological availability after administration of salmon calcitonin in positively and negatively charged gelatin microspheres was significantly higher than that in pH 7.0 PBS. The pharmacological availability after administration of salmon calcitonin in positively charged gelatin microspheres was significantly higher than that in negatively charged gelatin microspheres. Administration of salmon calcitonin in positively charged gelatin microspheres with smaller particle sizes led to a higher pharmacological availability. The pharmacological availability after pulmonary administration of salmon calcitonin in positively charged gelatin microspheres with particle sizes of 3.4 and 11.2 microm was approximately 50%. In conclusion, the gelatin microspheres have been shown to be a useful vehicle for pulmonary delivery of salmon calcitonin.     

Hemodynamic effects of carvedilol infusion and the contribution of the sympathetic nervous system in rats with heart failure

We investigated the contribution of the sympathetic nervous system (SNS) in maintaining the blood pressure and in regulating the cardiac function during and after carvedilol administration in rats with heart failure (group F). Left ventricular end-diastolic pressure, percent functional shortening, and rates of intraventricular pressure rise were significantly changed by carvedilol infusion as compared with the basal values in group N (normal rats), but not in group F. The left ventricular end-diastolic pressure was elevated, corresponding to the enhancement of the plasma norepinephrine (NE) concentration caused by carvedilol infusion, in group N. The enhancement of the plasma NE concentration induced by carvedilol administration in group F was higher than that in group N. The value for the maximal hypertensive effect of NE intravenous infusion (Emax) was decreased, and the plasma NE concentration at half-maximal effect (EC50) was increased in group F as compared with the values in group N. These results indicate that the SNS (presynaptic) activity is increased and that the SNS receptor sensitivity in the cardiovascular regulation system is decreased in heart failure.