Mechanisms of absorption enhancement and tight junction regulation

Novel approaches for oral delivery of macromolecules

Traditional forms of administrations of nonabsorbable drugs and peptides often rely on their parenteral injection, since the intestinal epithelium is poorly permeable to these therapeutical agents. A number of innovative drug delivery approaches have been recently developed, including the drug entrapment within small vesicles or their passage through the intestinal paracellular pathway. Zonula occludens toxin, a recently discovered protein elaborated by Vibrio cholerae, provided tools to gain more insights on the pathophysiology of the regulation of intestinal permeability through the paracellular pathway and to develop alternative approaches for the oral delivery of drugs and macromolecules normally not absorbed through the intestine.

Effects of beta-lactoglobulin on the tight-junctional stability of Caco-2-SF monolayer

The mechanisms for tight-junction (TJ) stabilization by beta-lactoglobulin (beta-Lg) were studied. Treatment of Caco-2-SF cells with inhibitors for some enzymes in the intracellular signal transduction pathways and a cytoskeleton-disturbing agent (cytochalasin D) reduced the TJ-stabilizing activity of beta-Lg. So beta-Lg is suggested to modulate the cytoskeletal structure through the activation of phospholipase C and protein kinase C, resulting in the TJ stabilization.

Absorption enhancers as tools to determine the route of nasal absorption of peptides

The nasal absorption of a series of peptides was studied in order to examine the relationship between extent of absorption and lipophilicity and absorption enhancers were used to probe the mechanism of peptide absorption. An in situ rat nasal perfusion technique was employed to assess the nasal absorption of a series of peptides, D-FGGGGG (D-FG5), D-FD-FGGGG (D-F2G4) and D-FD-FD-FGGG (D-F3G3), [D-ala2, D-leu5]enkephalin (YD-AGFD-L) and thyrotrophin releasing hormone (TRH). The enhancers sodium tauro-24,25 dihydrofusidate (STDHF), ethylene diamine tetraacetic acid (EDTA and dimethyl-beta-cyclodextrin (DMbetaCD) were utilized to improve and elucidate the mechanisms of peptide absorption. There was no significant relationship between extent of peptide absorption and lipophilicity as determined by C log P values. STDHF was a potent absorption enhancer but demonstrated overt toxicity. Conversely, EDTA did not demonstrate extensive toxicity but was found to be a poor absorption enhancer. DMbetaCD displayed some toxicity and was also found to inhibit the absorption of D-FG5,D-F2G4 and D-F3G3. This reduction is likely to be a result of the peptide/DMbetaCD complex formation. The peptides studied appear to be predominantly absorbed by a passive paracellular mechanism.

Modulation of intestinal permeability: an innovative method of oral drug delivery for the treatment of inherited and acquired human diseases

Conventional forms of administrations of nonabsorbable drugs and peptides rely on their parenteral injection. The intestinal epithelium represents the major barrier to the oral absorption of these therapeutical agents into the systemic circulation. Recently, a number of innovative drug delivery approaches have been developed, including the drug entrapment within small vesicles or their passage through the intestinal paracellular pathway. Zonula occludens toxin, a recently discovered protein elaborated by Vibrio cholerae, provided tools for gaining more insights on the pathophysiology of the regulation of intestinal permeability and to developing alternative approaches for the oral delivery of drugs and macromolecules normally not absorbed through the intestine.

An improved everted gut sac as a simple and accurate technique to measure paracellular transport across the small intestine

An improved everted gut sac system has been developed in which the sacs were carefully prepared from rat small intestine and incubated in tissue culture medium. Under these conditions, the tissue showed good morphology at the electron microscope level, and was metabolically active for up to 2 h at 37 degrees C. Mannitol, an established probe of paracellular transport, was transported from the mucosal to the serosal side of the sac tissue. Excellent kinetic data showed that transport was linear up to 75 min and over a wide range of concentrations (0.025 - (10 mM). Mannitol was not detected in the tissue and transport was enhanced by EGTA, confirming the paracellular route of passage. Sacs prepared from colon also showed mannitol transport, but at a slower rate. Comparisons with Caco-2 cell monolayers showed that the everted sacs exhibited higher levels of paracellular transport than the cultured cell line. The improved everted gut sac system is an inexpensive and relatively simple technique with considerable potential as an in vitro tool to study the mechanisms, kinetics and enhancement of drug absorption across the small intestine at different sites and in the colon.

Innovative strategies for the oral delivery of drugs and peptides

Conventional forms of administration for nonabsorbable drugs and peptides often rely on parenteral injection, because the intestinal epithelium represents a major barrier to the oral absorption of these therapeutic agents. Recently, a number of innovative drug-delivery approaches have been developed, including entrapment within small vesicles and passage through the space between adjacent intestinal cells. This article reviews some of the most promising techniques currently available for oral delivery and their possible practical applications for the delivery of vaccines and drugs for the treatment of clinical conditions that require frequent, chronic parenteral administration.

The influence of penetration enhancers on the volume instilled of eye drops

The influence of the physicochemical properties of various penetration enhancers on the weight of drops dispensed from flexible plastic dropper bottles was examined. Two dropper tips with a different design were compared and the dropper bottle was held in the upright position (90 degrees angle) or at a 45 degrees angle. These two angles were chosen to simulate the manipulation of an eye dropper bottle by the patient. The surface tension of the penetration enhancer solutions was determined using the dynamic drop volume method. The dynamic surface tension values ranged from 65 to 30 mN/m. The lower the surface tension of the solution, the lower the weight of the drop delivered. Both the design of the dropper tip and the manipulation technique of the dropper bottle had a moderate to important influence on the drop weight. The relationship between the surface tension of the penetration enhancer solution instilled and the comfort of the patient was evaluated by an acceptability test based on answering a questionnaire. Penetration enhancers can be used to reduce the drop size of conventional ophthalmic solutions on condition that they do not elicit local irritation.

Comparison of the effect of different chitosan salts and N-trimethyl chitosan chloride on the permeability of intestinal epithelial cells (Caco-2)

A partially quaternized chitosan derivative, N-trimethyl chitosan chloride (TMC) (degree of quaternization 12.28%), was synthesized and the effects of this novel polymer on the permeability of intestinal epithelial cells, using Caco-2 cell monolayers, were investigated and compared with those of chitosan hydrochloride and chitosan glutamate. Transepithelial electrical resistance (TEER) measurements at pH 6.20 revealed that all these polymers (0.25-1.5% w/v) caused an immediate and pronounced lowering in TEER values in the order chitosan hydrochloride (84% reduction after 2 h incubation) > chitosan glutamate (60% reduction) > TMC (24% reduction) at 0.25% w/v concentrations. At higher concentrations (up to 2.5% w/v), TMC was able to decrease the TEER further. Similar results were obtained in transport studies, using the hydrophilic radioactive markers, [14C]-mannitol (MW 182.2) and [14C]-polyethylene glycol 4000 (PEG-4000, MW 4000). Large increases in the permeation of these markers were found. The transport of [14C]-mannitol was increased 34-fold (chitosan hydrochloride), 25-fold (chitosan glutamate) and 11-fold (TMC) at 0.25% w/v concentrations. Further increases in the permeation of both markers were found at higher concentrations of TMC. Due to its quaternary structure, TMC is better soluble than the other chitosan salts, and its higher solubility may compensate for its lesser effectivity at similar concentrations. It is also soluble at pH 7.40, where the chitosan salts are insoluble and therefore ineffective. No deleterious effects to the cells could be demonstrated with trypan blue exclusion studies and confocal laser scanning microscopy (CLSM). CLSM confirmed that these polymers increase the transport of large hydrophilic compounds (using the fluorescent markers FD-4, MW 4400 and FD-20, MW 19,600) through opening of tight junctions to allow for paracellular transport. It is concluded from this study that the charge, charge density and the structural features of chitosans and chitosan derivatives are important factors determining their potential use as absorption enhancers.

Paracellular diffusion in Caco-2 cell monolayers: effect of perturbation on the transport of hydrophilic compounds that vary in charge and size

We applied the principles of molecular-size-restricted diffusion within a negative electrostatic field of force to follow the changes in the aqueous pore radius of tight junctions (TJs) induced by perturbants and the accompanying influence on the permeation of neutral (urea and mannitol), cationic (methylamine and atenolol), and anionic (formate and lactate) compounds that vary in size. The perturbants included palmitoyl-DL-carnitine (PC), which opens TJs by an unknown Ca++-independent mechanism, and ethyleneglycol-bis-(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid (EGTA), a Ca++ chelator. Mass transfer resistances of the collagen-coated filter support and the aqueous boundary layers were factored out to yield paracellular permeability coefficients (P[P]). As viewed from the P(P) values of urea and mannitol, EGTA exhibited insignificant effects on pore size at low concentrations compared with control, and then caused a dramatic opening of the TJs over a narrow concentration range (1.35-1.4 mM). The P(P) values for urea and mannitol remained constant at >1.4 mM EGTA. However, PC produced dose-dependent responses from O to 0.15 mM that plateaued at >0.15 mM. In general, cations permeated the cellular TJs faster and anions slower than their neutral images. The effects of changes in pore size (4.6 to 14.6 A in effective radius) on the ability of these solutes to permeate the TJs were analyzed by the Renkin molecular sieving function. These studies established an experimental, theoretical, and quantitative template to assess perturbants of the TJ and define the limits, short of detrimental effects, at which the TJs may be sufficiently perturbed for maximal enhancement of permeation of solutes varying in size and charge.

The effect of monomers and of micellar and vesicular forms of non-ionic surfactants (Solulan C24 and Solulan 16) on Caco-2 cell monolayers

Measurements of transepithelial electrical resistance (TEER), the MTT (3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl-2H-tetrazolium bromide) test and monitoring of poly(ethylene glycol) (PEG) transport have been used to study the effects of the non-ionic surfactants Solulan C24 and Solulan 16, either free in solution or as an integral part of niosome bi-layers, on intestinal epithelial cells from man (Caco-2 cell monolayers). The effects on epithelial integrity and on the transport of the hydrophilic drug metformin depend on the concentration of the surfactants. At concentrations above 1% the effect on TEER of the surfactant in niosomal form and free in solution were equivalent whereas cell viability was preserved to a higher concentration of Solulans when the Solulans were present in the niosomal form. It was concluded that the toxic effect of niosomes arises from free surfactant present in the niosome suspension.

Ocular permeability of FITC-dextran with absorption promoter for ocular delivery of peptide drug

The purpose of this study is to characterize an ocular permeability of FITC-dextran, as a model of peptide drug, and to evaluate the effects of absorption promoters on the ocular permeability of FITC-dextran. The in vitro penetrations of FITC-dextrans (average molecular weight 4400 and 9400: FD-4 and FD-10) were measured across the isolated corneal and conjunctival membranes of albino rabbits using a two-chamber glass diffusion cell. The corneal permeabilities of FD-4 and FD-10 were much lower than the conjunctival permeabilities. Scraping of corneal epithelium extremely increased the corneal permeabilities. The penetration parameters were estimated according to Fick's equation. Absorption promoters such as EDTA, taurocholic acid, benzalkonium chloride and saponin significantly increased corneal permeabilities of FD-4 and FD-10. Saponin showed the highest promoting activity. Conjunctival permeabilities of FD-4 and FD-10 were also enhanced by absorption promoters although the improvements of conjunctival permeabilities by absorption promoters were smaller than those of corneal permeabilities. Ratios of corneal to conjunctival permeabilities were enhanced by absorption promoters. These results indicate that an ocular delivery of instilled hydrophilic macromolecule is markedly low and a selective use of absorption promoter can improve the extent and pathway of its ocular absorption.