Tracheal barrier and the permeability of hydrophilic drugs and dipeptides.

The permeability of model hydrophilic compounds with different molecular weights and model dipeptides were examined to characterize the tracheal epithelial barrier in in vitro experiments using excised rabbit trachea. 6-Carboxyfluorescein (6-CF; 376 Da) and fluorescein isothiocyanate (FITC)-dextrans (FDs) with varying molecular weights (4 to 70 kDa) were used as model hydrophilic and macromolecular compounds, and glycyl-D-phenylalanine (Gly-D-Phe) and glycyl-L-phenylalanine (Gly-L-Phe) were used as model dipeptides in this experiment. The apparent permeability coefficients (Papp) of 6-CF and FDs with Mw 376 Da to 70 kDa ranged from 2.35x10(-7) to 4.05x10(-10)cm/s and exhibited a good inverse correlation with their molecular weights. The tracheal permeability of 6-CF, FD-4 (4 kDa) and FD-10 (10 kDa) were increased over three fold by 10 mM glycocholate, which is an absorption enhancer. The Papp of Gly-D-Phe was 1.03x10(-6)cm/s and there was no metabolism during tracheal permeation. Gly-L-Phe was immediately degraded in the mucosal fluid and its intact form was not detected in serosal fluid during the 150 min experimental period. These results suggest that absorption of some peptide drugs via the respiratory tract may contribute to their systemic delivery following pulmonary administration by intratracheal insufflation and instillation.     

Evaluation of gelatin microspheres for nasal and intramuscular administrations of salmon calcitonin.

The suitability of gelatin microspheres for nasal and intramuscular delivery of salmon calcitonin (sCT) was examined. Negatively and positively charged gelatin microspheres were prepared using acidic gelatin [isoelectric point (IEP) value of 5.0] and basic gelatin (IEP=9.0), respectively. The average diameters of positively charged gelatin microspheres in their dried state were 3.4, 11.2, 22.5 and 71.5 microm, while that of negatively charged gelatin microspheres was 10.9 microm. Both types of gelatin microspheres were capable of adhering to the nasal mucosa. The mucoadhesion of positively charged gelatin microspheres was significantly higher than that of their negatively charged counterparts. The absorption of sCT after intranasal and intramuscular administration was evaluated by calculating the area above the hypocalcemic-time curve (AAC) in rats. The AAC values after nasal administration of sCT in positively and negatively charged gelatin microspheres were significantly greater than that in pH 7.0 PBS. Therefore, the nasal absorption of sCT was enhanced by both types of gelatin microspheres. The hypocalcemic effect after administration of sCT in positively charged gelatin microspheres of 11.2 microm was significantly greater than that of negatively charged gelatin microspheres of the same size. On the other hand, AAC values were not affected by their particle sizes. The AAC values after the intramuscular administration of sCT in positively and negatively charged gelatin microspheres were significantly increased compared to that in PBS. Furthermore, the time-courses of the plasma calcium levels differed between positively and negatively charged gelatin microspheres. The hypocalcemic effect of the negatively charged gelatin microspheres tended to appear more slowly and last longer compared to that of positively charged gelatin microspheres. The hypocalcemic effects after intramuscular administration of sCT in gelatin microspheres were not affected by their particle sizes as well as those after intranasal administration. In conclusion, the gelatin microspheres have been shown to be a useful vehicle for nasal or intramuscular delivery of sCT.     

Disposition of lipid-based formulation in the intestinal tract affects the absorption of poorly water-soluble drugs

Solvent Green 3 (SG), a model poorly water-soluble compound, was orally administered to rats with soybean oil emulsion or the Self-microemulsifying drug delivery system (SMEDDS) composed of Gelucire44/14. The bioavailability of SG after oral administration with SMEDDS was 1.7-fold higher than that with soybean oil emulsion. The intestinal absorption of lipid-based formulations themselves was evaluated by the in situ closed loop method. The effect of lipase and bile salt on their absorption was also evaluated. SMEDDS itself was rapidly absorbed in the intestine even in the absence of lipase and bile salt, and the absorption was increased by the addition of lipase and bile salt. On the other hand, no soybean oil emulsion was absorbed in the absence of lipase and bile salt. However, mixed micelle prepared from emulsion by incubating soybean oil emulsion with lipase and bile salt was rapidly absorbed through the intestine. Without lipase and bile salt, SG was not absorbed after administration with soybean oil emulsion. Therefore, we concluded that the degradation of soybean oil emulsion was needed for SG to be absorbed through the intestine. Furthermore, we investigated the intestinal absorption of SG after oral administration to rats whose chylomicron synthesis were inhibited by pretreatment with colchicine. Colchicine completely inhibited the intestinal absorption of SG after administration with each lipid-based formulation, suggesting that SG was absorbed from the intestine via a lymphatic route. Absorption of the dosage formulation should be paid attention when poorly water-soluble drugs are orally administered with lipid-based formulation.     

Kinetics of combined drug action

For the purpose of obtaining quantitative concentration-effect relationship for combined drugs, rationales of the Hill equation were inferred and five models, i.e., normal distribution (NRD), derivative of R (DRV), vacancy-dependent binding (VDB), equiresponse (EQR), and independence (IND), were proposed to estimate the intensity of the combined drug action. In conclusion, we could not come up to the unique concentration-effect relationship. Among the five models, the EQR, NRD, and VDB models gave almost identical response intensity. Discrimination of these three models is not of great importance. The DRV model gave a characteristic concave isobologram (overadditive), for a given ratio of Hill constants and independent of pharmacologic effect. In contrast, the IND model was able to cope with convex isobolograms (underadditive).This study was presented at The Second Jerusalem Conference on Pharmaceutical Sciences and Clinical Pharmacology, Jerusalem, May 1992.     

Estimation of bioavailability of salmon calcitonin from the hypocalcemic effect in rats (II): effect of protease inhibitor on the pharmacokinetic-pharmacodynamic relationship after intranasal administration

Assessment of the extent of bioavailability (EBA) of salmon calcitonin (sCT) from hypocalcemic effects after intranasal administration was presented in rats. An integrated pharmacokinetic-pharmacodynamic (PK-PD) model with the endogenous Ca regulation system was applied. The influence of camostat mesilate, a protease inhibitor, on absorption of sCT was also estimated. Camostat, coadministered intravascularly, delayed the elimination of sCT. Although the hypocalcemic effect of sCT after i.v. administration was accelerated when camostat was coadministered intravenously, the enhanced effect could not be expressed only by pharmacokinetic change of sCT, and then the pharmacological data in the presence of camostat were analyzed to obtain optimal PD parameters. For the absorption of sCT after i.n. administration, a saturable absorptive process and a zero-order kinetic clearance from the nasal cavity were introduced to the model. The regression curves fitted the observed data, and camostat caused both an increase in maximum absorption rate and a decrease in the clearance parameter compared with the control. According to this modified PK-PD relationship, plasma sCT concentrations following i.n. administration of sCT with camostat were predicted well using its pharmacological effects. The EBA of sCT calculated from the simulated concentrations increased more than 4-folds compared with the control study. These results indicate the potential for prediction of plasma sCT concentration from the hypocalcemic effect.     

Enhanced percutaneous absorption of formoterol furmarate via pulsed iontophoresis. I. Effect of constant current and constant voltage

The effect of iontophoresis on percutaneous absorption of formoterol fumarate (FF) was investigated in vitro with abdominal skin excised from guinea pig. By passive diffusion, the flux at steady state for stripped skin was about 230 times greater than that for intact skin. Therefore, it is suggested that stratum corneum is a barrier for the percutaneous absorption of FF. Penetrated amount of FF increased significantly with an increase in donor concentration from 0.035% to 0.07%. Under the constant current iontophoresis the large flux accompanied with the high applied voltage was shown at the beginning of iontophoresis. Thereafter the flux decreased with a decrease in applied voltage. Under the constant voltage iontophoresis a linear relationship between penetrated amount of FF and time was observed.     

Controlled release of plasmid DNA from hydrogels prepared from gelatin cationized by different amine compounds.

This paper is an investigation to compare the in vivo controlled release of a plasmid DNA from biodegradable hydrogels prepared from gelatin cationized by different amine compounds, ethylenediamine, putrescine, spermidine, and spermine and the consequent profile of gene expression. Cationized gelatin prepared through the chemical introduction of each amine compound was crosslinked by various concentrations of glutaraldehyde to obtain cationized gelatin hydrogels for the carrier of plasmid DNA release. When the cationized gelatin hydrogels incorporating 125I-labeled plasmid DNA were implanted into the femoral muscle of mice, the radioactivity remaining decreased with time and the retention period of radioactivity prolonged with a decrease in the water content of hydrogels. When 125I-labeled cationized gelatin hydrogels with the higher water content was implanted, the radioactivity remaining was decreased faster with time. The remaining time profile of plasmid DNA radioactivity was in good accordance with that of hydrogel radioactivity, irrespective of the type of cationized gelatin. Following intramuscular implantation, any cationized gelatin hydrogel incorporating plasmid DNA enhanced the expression level of plasmid DNA to a significantly higher extent than the free plasmid DNA injection. In addition, prolonged time period of gene expression was observed although there was no significant difference in the expressed period between the cationized gelatin hydrogels. It was concluded that plasmid DNA of biological activity was released from every cationized gelatin hydrogel accompanied with the in vivo degradation, resulting in enhanced and prolonged gene expression.     

In vivo release and gene expression of plasmid DNA by hydrogels of gelatin with different cationization extents.

The objective of this paper is to investigate the in vivo release and gene expression of lacZ plasmid DNA (pSV-lacZ) by the hydrogels of cationized gelatin. Gelatin with different cationization extents was prepared by changing the amount of ethylenediamine added to aminize the carboxyl groups of gelatin with a water-soluble carbodiimide. The cationized gelatin prepared was crosslinked by various concentrations of glutaraldehyde (GA) to obtain cationized gelatin hydrogels with different cationization extents as the release carrier of plasmid DNA. When the cationized gelatin hydrogels incorporating 125I-labeled pSV-lacZ were implanted into the femoral muscle of mice, the radioactivity remaining decreased with time and the retention period was prolonged with an increase in the concentration of GA used for hydrogel preparation. In vivo experiments with 125I-labeled cationized gelatin hydrogels revealed that the higher the GA concentration, the longer the in vivo retention period of radioactivity remaining for every cationized gelatin hydrogel. Only for the hydrogels prepared from gelatin with the aminized percentages of 29.7, 41.6, and 47.8 mol.%, the time profile of pSV-lacZ retention correlated well with that of hydrogel retention. The gene expression by the cationized gelatin hydrogels incorporating pSV-lacZ depended on the aminized percentage of gelatin and was significant at the percentage of 41.6 mol.% or higher. It is possible that the pSV-lacZ was complexed with the degraded fragments of cationized gelatin and released with a positive charge, resulting in enhanced gene expression. We conclude that gelatin with a cationization extent of at least 41.6 mol.% is needed for the enhanced in vivo gene expression of plasmid DNA by the hydrogel release system.