Ronald T. Borchardt

Characterization of the Human Colon Carcinoma Cell Line (Caco-2) as a Model System for Intestinal Epithelial Permeability

Caco-2 cells develop morphologic characteristics of normal enterocytes when grown on plastic dishes or nitrocellulose filters. The purpose of this study was to determine whether Caco-2 cells undergo similar differentiation when grown on Transwell polycarbonate membranes, and to study the suitability of Caco-2 monolayers as an intestinal epithelial transport model system. Transepithelial electrical resistance values after confluence were 173.5 omega.cm2 and remained unchanged through day 17. Permeabilities to the water-soluble fluid-phase markers that do not permeate the membrane, Lucifer yellow CH, [14C]inulin, [14C]polyethylene glycol, and [3H] dextran were less than 0.25% of the administered amount per hour after day 10. Qualitative evaluation of uptake and permeability to horseradish peroxidase confirmed the similarity in uptake and barrier properties between this cell system and the small intestinal epithelial layer. We conclude that Caco-2 cells grown on collagen-coated polycarbonate membranes should represent a valuable transport model system for the small intestinal epithelium.

Stability of protein pharmaceuticals

Recombinant DNA technology has now made it possible to produce proteins for pharmaceutical applications. Consequently, proteins produced via biotechnology now comprise a significant portion of the drugs currently under development. Isolation, purification, formulation, and delivery of proteins represent significant challenges to pharmaceutical scientists, as proteins possess unique chemical and physical properties. These properties pose difficult stability problems. A summary of both chemical and physical decomposition pathways for proteins is given. Chemical instability can include proteolysis, deamidation, oxidation, racemization, and β-elimination. Physical instability refers to processes such as aggregation, precipitation, denaturation, and adsorption to surfaces. Current methodology to stabilize proteins is presented, including additives, excipients, chemical modification, and the use of site-directed mutagenesis to produce a more stable protein species.

Directed Drug Delivery

Drug response triggered by receptor activation arises from a chain of events that are regulated by many factors. Molecular changes associated with drug sensitization or tolerance are currently being elucidated on the molecular level, e.g. for adenylate cyclase coupled systems. Despite the complexity of the drug-response mechanism, simple empirical pharmaco-dynamic models on the basis of the law of mass action are widely applicable to describe drug-effect relationships. In combination with a pharmacokinetic model and suitable delay functions, such models are capable of simulating the complete time course of drug action in vivo. The predictive potential of the pharmacokinetic-pharmacodynamic models should prove useful in evaluating pharmaceutical formulations with controlled drug delivery.

The Use of Surfactants to Enhance the Permeability of Peptides Through Caco-2 Cells by Inhibition of an Apically Polarized Efflux System

AbstractPurpose. It has recently been reported that the permeability of peptides across Caco-2 cells, an in vitro model of the intestinal mucosa, was limited by an apically polarized efflux mechanism. Since surfactants (e.g. Cremophor EL, Polysorbate 80) have been reported to inhibit similar efflux systems in tumor cells, we determined whether they could enhance the permeability of peptides across monolayers of Caco-2 cells. Methods. The transport studies of [3H]-mannitol and [14C]-model peptides were carried out across the Caco-2 cell monolayers. TEER values were determined using Voltohmmeter with STX-2 electrode and the equilibrium dialysis studies were conducted using side-by-side dialysis apparatus with cellulose ester membranes. Results. Initially, [3H]-mannitol flux studies were conducted to find concentrations of the surfactants that did not cause damage to the cell monolayer. Based on these studies, Polysorbate 80 and Cremophor EL were selected for further study. The fluxes of [l4C]-AcfNH2 (a nonsubstrate for this efflux system) and [14C]-Acf(N-Mef)2NH2 (a substrate for this efflux system) were then measured in the absence and presence of the two surfactants. The permeability of [14C]-AcfNH2 was not affected by the surfactants, while that of [14C]-Acf(N-Mef)2NH2 increased with increasing concentrations of surfactants and then decreased. For example, the Pe values for [14C]-Acf(N-Mef)2NH2 were 3.75 × 10−6, 8.58 × 10−6, 10.29 × 10−6, 7.48 × 10−6, and 1.46 × 10−6 cm/sec with Cremophor EL concentrations of 0, 0.01, 0.1, 1 and 10% w/v, respectively. This bimodal effect of surfactants on the Caco-2 cell permeability of this peptide was shown to be due to the interactions between the peptide and micelles at higher concentrations of surfactants, which were demonstrated by the equilibrium dialysis experiments. Conclusions. These results suggest that surfactants, which are commonly added to pharmaceutical formulations, may enhance the intestinal absorption of some drugs by inhibiting this apically polarized efflux system.

The Use of Cultured Epithelial and Endothelial Cells for Drug Transport and Metabolism Studies

In an effort to develop novel strategies for delivery of drug candidates arising from rational drug design and recombinant DNA technology, pharmaceutical scientists have begun to employ the techniques of cell culture to study drug transport and metabolism at specific biological barriers. This review describes some of the general factors that should be considered in developing a cell culture model for transport studies and metabolism studies. In addition, we review in detail the recent progress that has been made in establishing, validating, and using cell cultures of epithelial barriers (e.g., cells that constitute the intestinal, rectal, buccal, sublingual, nasal, and ophthalmic mucosa as well as the epidermis of the skin) and the endothelial barriers (e.g., brain microvessel endothelial cells).

Characterization of an In Vitro Blood–Brain Barrier Model System for Studying Drug Transport and Metabolism

Bovine brain micro vessel endothelial cells have been isolated and grown in culture to monolayers. These endothelial cell monolayers have been characterized morphologically with electron microscopy, histochemically for brain endothelium enzyme markers, alkaline phosphatase and γ-glutamyl trans-peptidase, and by immunofluorescence to detect Factor VIII antigen, an exclusive endothelial antigen. Results of these studies indicate that the cells forming the monolayers are of endothelial origin and possess many features of the in vivo brain endothelium responsible for formation of the blood–brain barrier. This in vitro blood–brain barrier model system was used in experiments to determine the permeability of the cultured monolayer to sucrose, leucine, and propranolol. Leucine rapidly moved across the monolayers of this in vitro system and tended to plateau after approximately 10 min. In contrast, the rates of sucrose and propranolol movement were linear during a 1-hr observation period, with the rate of propranolol movement across the monolayer greater than that of sucrose. The ability to detect differences in the permeability of the monolayers to leucine, propranolol, and sucrose with radioactive tracers suggests that this in vitro model system will be an important tool for the investigation of the role of the blood–brain barrier in the delivery of centrally acting drugs and nutrients.

Chemical Pathways of Peptide Degradation. II. Kinetics of Deamidation of an Asparaginyl Residue in a Model Hexapeptide

Deamidation of Asn residues is a major chemical pathway of degradation of peptides and proteins. To understand better the external factors that influence deamidation, we studied the degradation of the hexapeptide Val–Tyr–Pro–Asn–Gly–Ala, a fragment of adrenocorticotropic hormone, by HPLC. The deamidation of this model peptide showed marked dependence on pH, temperature, and buffer composition. In the pH range 5 to 12, the peptide deamidated exclusively via a cyclic imide intermediate with the formation of both the Asp- and the isoAsp-hexapeptides. Buffer catalysis was also observed in the pH range of 7 to 11. However, at acidic pHs, the pathway of deamidation involved direct hydrolysis of the amide side chain of Asn residue to produce only the Asp-hexapeptide.

Bovine Brain Microvessel Endothelial Cell Monolayers as a Model System for the Blood‐Brain Barrier

Investigation of blood-brain barrier permeability and metabolic processes, and their regulation by endogenous or exogenous factors, will be important for development of efficient and selective delivery of therapeutic agents to the central nervous system. Primary cultures of brain microvessel endothelial cells offer a potentially powerful tool for studying at the cellular level the biochemical mechanisms regulating BBB function. Using this in vitro model, our studies are directed at characterization of the BBB processes that might be exploited as new schemes for drug delivery to the central nervous system.

Are MDCK Cells Transfected with the Human MRP2 Gene a Good Model of the Human Intestinal Mucosa

AbstractPurpose. To investigate whether Madin-Darby canine kidney cells transfected with the human MDR1 gene (MDCK-MDR1) are a good model of the human intestinal mucosa. Methods. P-glycoprotein (P-gp) expression in Caco-2 cells was compared with P-gp expression in MDCK wild- type (MDCK-WT) and MDCK-MDR1 cells using Western blotting methods. The polarized efflux activities of P-gp(s) in MDCK-MDR1 cells, MDCK-WT cells, and Caco-2 cells were compared using digoxin as a substrate. Apparent Michaelis-Menten constants (KM,Vmax) for the efflux of vinblastine in these three cell lines were determined. Apparent inhibition constants (KI) of known substrates/inhibitors of P-gp were determined by measuring their effects on the efflux of digoxin in Caco-2 or MDCK-MDR1 cell monolayers. Results. MDCK-MDR1 cells expressed higher levels of P-gp compared to Caco-2 and MDCK-WT cells, as estimated by Western blots. Two isoforms of P-gp were expressed in Caco-2 and MDCK cells migrating with molecular weights of 150 kDa and 170 kDa. In MDCK-MDR1 cells, the 150 kDa isoforms appeared to be overexpressed. The MDCK-MDR1 cells exhibited higher polarized efflux of [3H]-digoxin than did Caco-2 and MDCK-WT cells. KM values of vinblastine in Caco-2, MDCK-WT, and MDCK-MDR1 cells were 89.2 ± 26.1, 24.5 ± 1.1, and 252.8 ± 134.7 μM, respectively, whereas Vmax values were 1.77 ± 0.22, 0.42 ± 0.01, and 2.43 ± 0.86 pmolcm−2s−1, respectively. Known P-gp substrates/inhibitors showed, in general, lower KI values for inhibition of digoxin efflux in Caco-2 cells than in MDCK-MDR1 cells. Conclusions. These data suggest that the MDCK-MDR1 cells overexpress the 150 kDa isoform of P-gp. MDCK-MDR1 cells are a useful model for screening the P-gp substrate activity of drugs and drug candidates. However, the apparent kinetics constants and affinities of substrates determined in the MDCK-MDR1 cell model may be different than the values obtained in Caco-2 cells. These differences in substrate activity could result from differences in the relative expression levels of total P-gp in Caco-2 and MDCK-MDR1 cells and/or differences in the partitioning of substrates into these two cell membrane bilayers.

Improvement of oral peptide bioavailability : Peptidomimetics and prodrug strategies

Clinical development of orally active peptide drugs has been restricted by their unfavorable physicochemical properties, which limit their intestinal mucosal permeation and their lack of stability against enzymatic degradation. Successful oral delivery of peptides will depend, therefore, on strategies designed to alter the physicochemical characteristics of these potential drugs, without changing their biological activity, in order to overcome the physical and biochemical barrier properties of the intestinal cells. This manuscript will focus on the physiological limitations for oral peptide delivery and on various strategies using chemical modifications to improve oral bioavailability of peptide-based drugs.