Chemically modified chitosans as enzyme inhibitors.

Because of its permeation enhancing effect (I), mucoadhesive properties (II) and the capability to provide a controlled release of incorporated drugs (III), chitosan represents an advantageous excipient in non-invasive peptide delivery. The use of chitosan for such delivery systems, however, is limited by the lack of inhibitory properties towards secreted and membrane bound enzymes. Due to the covalent attachment of enzyme inhibitors and/or complexing agents at the 2-position of this poly(beta 1-4-D-glucosamine), chitosans can be transformed into polymers that exhibit inhibitory properties. The immobilization of inhibitors such as antipain, chymostatin, elastatinal and Bowman-Birk inhibitor provide a protective effect towards pancreatic serine proteases, whereas covalently attached complexing agents such as EDTA guarantee the inactivation of membrane bound Zn-dependent peptidases as well as carboxypeptidase A and B. As the inhibition of these enzymes strongly improves the bioavailability of non-invasively administered peptide drugs, chemically modified chitosans represent promising auxiliary polymers.

Thiolated polymers--thiomers: development and in vitro evaluation of chitosan-thioglycolic acid conjugates.

The aim of this study was to improve mucoadhesive properties of chitosan by the covalent attachment of thiol moieties to this cationic polymer. Mediated by a carbodiimide, thioglycolic acid (TGA) was covalently attached to chitosan. This was achieved by the formation of amide bonds between the primary amino groups of the polymer and the carboxylic acid group of TGA. Dependent on the pH-value and the weight ratio of polymer to TGA during the coupling reaction the resulting thiolated polymers, the so-called thiomers, displayed 6.58, 9.88, 27.44, and 38.23 micromole thiol groups per gram polymer. Tensile studies carried out with these chitosan-TGA conjugates on freshly excised porcine intestinal mucosa demonstrated a 6.3-, 8.6-, 8.9-, and 10.3-fold increase in the total work of adhesion (TWA) compared to the unmodified polymer, respectively. In contrast, the combination of chitosan and free unconjugated TGA showed almost no mucoadhesion. These data were in good correlation with further results obtained by another mucoadhesion test demonstrating a prolonged residence time of thiolated chitosan on porcine mucosa. The swelling behavior of all conjugates was thereby exactly in the same range as for an unmodified polymer pretreated in the same way. Furthermore, it could be shown that chitosan-TGA conjugates are still biodegradable by the glycosidase lysozyme. According to these results. chitosan-TGA conjugates represent a promising tool for the development of mucoadhesive drug delivery systems.

Permeation enhancing polymers in oral delivery of hydrophilic macromolecules: thiomer/GSH systems.

Thiolated polymers (= thiomers) in combination with reduced glutathione (GSH) were shown to improve the uptake of hydrophilic macromolecules from the GI tract. The mechanism responsible for this permeation enhancing effect seems to be based on the thiol groups of the polymer. These groups inhibit protein tyrosine phosphatase, being involved in the closing process of tight junctions, via a GSH-mediated mechanism. The strong permeation enhancing effect of various thiomer/GSH systems such as poly(acrylic acid)-cysteine/GSH or chitosan-4-thio-butylamidine (chitosan-TBA)/GSH could be shown via permeation studies on freshly excised intestinal mucosa in Ussing-type chambers. Furthermore, the efficacy of the system was also shown in vivo. By utilizing poly(acrylic acid)-cysteine/GSH as carrier matrix, an absolute oral bioavailability for low molecular weight heparin of 19.9 +/- 9.3% and a pharmacological efficacy--calculated on the basis of the areas under the reduction in serum glucose levels of the oral formulation versus subcutaneous (s.c.) injection-for orally given insulin of 7% could be achieved. The incorporation of salmon calcitonin in chitosan-TBA/GSH led on the other hand to a pharmacological efficacy based on the areas under the reduction in plasma calcium levels of the oral thiomer formulation versus intravenous (i.v.) injection of 1.3%. Because of this high efficacy (i), the possibility to combine thiomer/GSH systems with additional low molecular weight permeation enhancers acting in other ways (ii) and minimal toxicological risks as these polymers are not absorbed from the GI tract (iii), thiolated polymers represent a promising novel tool for the oral administration of hydrophilic macromolecules.

Improvement in the mucoadhesive properties of alginate by the covalent attachment of cysteine.

The purpose of the present study was to improve the mucoadhesive properties of alginate by the covalent attachment of cysteine. Mediated by a carbodiimide, L-cysteine was covalently linked to the polymer. The resulting thiolated alginate displayed 340.4+/-74.9 micromol thiol groups per g conjugate (means+/-S.D.; n=4). Within 2 h the viscosity of an aqueous mucus/alginate-cysteine conjugate mixture pH 7.0 increased at 37 degrees C by more than 50% compared to a mucus/alginate mixture, indicating enlarged interactions between the mucus and the thiolated polymer. Tensile studies carried out on freshly excised porcine intestinal mucosa demonstrated a total work of adhesion (TWA) of 25.8+/-0.6 and 101.6+/-36.1 microJ for alginate and the alginate-cysteine conjugate, respectively (means+/-S.D.; n=5). The maximum detachment force (MDF) was thereby in good correlation with the TWA. Due to the immobilization of cysteine, the swelling velocity of the polymer was significantly accelerated (P<0.05). In aqueous media the alginate-cysteine conjugate was capable of forming inter- and/or intramolecular disulfide bonds. Because of this crosslinking process within the polymeric network, the cohesive properties of the conjugate were also improved. Tablets comprising the unmodified polymer disintegrated within 49+/-14.5 min, whereas tablets of thiolated alginate remained stable for 148.8+/-39.1 min (means+/-S.D.; n=3). These features should render thiolated alginate useful as excipient for various drug delivery systems providing an improved stability and a prolonged residence time on certain mucosal epithelia.

Development and in vitro evaluation of a mucoadhesive vaginal delivery system for progesterone.

The purpose of the present study was to design a novel carrier system based on a mucoadhesive polymer exhibiting improved properties concerning drug delivery to the vaginal mucosa. This was reached by the covalent attachment of L-cysteine to commercially available polyacrylic acid (Carbopol 974P). Mediated by a carbodiimide, increasing amounts of L-cysteine were covalently linked to the polymer. The resulting thiolated polyacrylic acid conjugates (NaC974P-Cys) displayed between 24.8 and 45.8 micromol thiol groups per gram of polymer. Because of the formation of intra- and/or intermolecular disulfide bonds, the viscosity of an aqueous thiolated polymer gel (3%) increased about 50% at pH 7.0 within 1 h. In oscillatory rheological measurements, it was shown that this increase in viscosity is mainly due to the increase in elasticity. Tensile studies carried out on freshly excised cow vagina demonstrated a significant (P<0.05) increase in the total work of adhesion (TWA) compared to the unmodified polymer. An amount of 24.8 micromol thiol groups per gram of polymer resulted in a 1.45-fold increase in the TWA, whereas an amount of 45.8 micromol showed an even 2.28-fold increase. These improved mucoadhesive properties can be explained by the formation of disulfide bonds between the thiolated polymer and cysteine rich subdomaines of the mucus layer. The release rate of the model drug progesterone from tablets based on microcrystalline cellulose serving as the reference was approximately 1% per hour, whereas it was 0.58% per hour for the unmodified polymer (NaC974P) and 0.12% per hour for the thiolated polymer (NaC974P-Cys). Therefore, this thiolated polymer is a promising carrier for progesterone providing a prolonged residence time and a controlled drug release.