Joachim M. Mayer

Structure and interactions in covalently and ionically crosslinked chitosan hydrogels for biomedical applications.

This review presents a critical analysis of covalently and ionically crosslinked chitosan hydrogels and related networks for medical or pharmaceutical applications. The structural basis of these hydrogels is discussed with reference to the specific chemical interactions, which dictate gel formation. The synthesis and chemistry of these hydrogels is discussed using specific pharmaceutical examples. Covalent crosslinking leads to formation of hydrogels with a permanent network structure, since irreversible chemical links are formed. This type of linkage allows absorption of water and/or bioactive compounds without dissolution and permits drug release by diffusion. pH-controlled drug delivery is made possible by the addition of another polymer. Ionically crosslinked hydrogels are generally considered as biocompatible and well-tolerated. Their non-permanent network is formed by reversible links. Ionically crosslinked chitosan hydrogels exhibit a higher swelling sensitivity to pH changes compared to covalently crosslinked chitosan hydrogels. This extends their potential application, since dissolution can occur in extreme acidic or basic pH conditions.

Structure and interactions in chitosan hydrogels formed by complexation or aggregation for biomedical applications

The aim of this review was to provide a detailed overview of physical chitosan hydrogels and related networks formed by aggregation or complexation, which are intended for biomedical applications. The structural basis of these systems is discussed with particular emphasis on the network-forming interactions, the principles governing their formation and their physicochemical properties. An earlier review discussing crosslinked chitosan hydrogels highlighted the potential negative influence on biocompatibility of covalent crosslinkers and emphasised the need for alternative hydrogel systems. A possible means to avoid the use of covalent crosslinkers is to prepare physical chitosan hydrogels by direct interactions between polymeric chains, i.e. by complexation, e.g. polyelectrolyte complexes (PEC) and chitosan/poly (vinyl alcohol) (PVA) complexes, or by aggregation, e.g. grafted chitosan hydrogels. PEC exhibit a higher swelling sensitivity towards pH changes compared to covalently crosslinked chitosan hydrogels, which extends their potential application. Certain complexed polymers, such as glycosaminoglycans, can exhibit interesting intrinsic properties. Since PEC are formed by non-permanent networks, dissolution can occur. Chitosan/PVA complexes represent an interesting alternative for preparing biocompatible drug delivery systems if pH-controlled release is n/ot required. Grafted chitosan hydrogels are more complex to prepare and do not always improve biocompatibility compared to covalently crosslinked hydrogels, but can enhance certain intrinsic properties of chitosan such as bacteriostatic and wound-healing activity.

Topical use of chitosan in ophthalmology : tolerance assessment and evaluation of precorneal retention

The mucoadhesive polysaccharide chitosan was evaluated as a potential component in ophthalmic gels for enabling increased precorneal drug residence times. This cationic vehicle was expected to slow down drug elimination by the lacrymal flow both by increasing solution viscosity and by interacting with the negative charges of the mucus. The molecular weight (Mw) and concentration of polysaccharide were studied in four types of chitosan as parameters that might influence ocular tolerability and precorneal residence time of formulations containing tobramycin as therapeutic agent. An ocular irritation test, using confocal laser scanning ophthalmoscopy (CLSO) combined with corneal fluorescein staining, clearly demonstrated the excellent tolerance of chitosan after topical administration onto the corneal surface. Gamma scintigraphic data showed that the clearance of the formulations labelled with 99mTc-DTPA was significantly delayed in the presence of chitosan with respect to the commercial collyrium (Tobrex(R)), regardless of the concentration and of the molecular weight of chitosan in solution. At least a 3-fold increase of the corneal residence time was achieved in the presence of chitosan when compared to Tobrex(R).

Hydrolysis in drug and prodrug metabolism : chemistry, biochemistry, and enzymology

Chapter 1. Introduction: Metabolic Hydrolysis and Prodrug Design. Chapter 2. Classification, Localization, and Some Physiological Roles of Hydrolytic Enzymes. Chapter 3. Catalytic Mechanisms of Hydrolytic Enzymes. Chapter 4. The Hydrolysis of Amides. Chapter 5. The Hydrolysis of Lactams. Chapter 6. The Hydrolysis of Peptides. Chapter 7. The Hydrolysis of Carboxylic Acid Esters. Chapter 8. The Hydrolysis of Carboxylic Acid Ester Prodrugs. Chapter 9. The Cleavage of Esters of Inorganic Acids. Chapter 10. The Hydration of Epoxides. Chapter 11. Miscellaneous Reactions of Hydration and Dehydration. Chapter 12. Conclusion: The Biochemistry of Water. Index.

Ocular tolerance of preservatives and alternatives

Eye drops are multiple dosage forms protected against microbial contamination by means of preservatives. However, the ocular tolerance of these chemicals can vary and this may result in adverse toxic or allergic reactions. This overview presents the pharmacopoeial requirements for the preservation of eye drops, the factors affecting ocular tolerance as well as the adverse external ocular effects induced by preservatives. The alternatives to the use of preservatives are also discussed, including the recent progress in eye drops packaging.

Application of in vivo confocal microscopy to the objective evaluation of ocular irritation induced by surfactants

An ocular irritation test using confocal laser scanning ophthalmoscopy has been developed in which corneal lesions subsequent to instillation of surfactants are specifically marked by fluorescein and assessed by digital image processing. The sum of the observed fluorescent corneal areas is taken into account as an endpoint of ocular irritation. Eight currently used nonionic, cationic and anionic surfactants were applied onto the cornea of rabbits and mice, four times per day during 3 days at various concentrations. Benzalkonium chloride, a cationic surfactant, at a concentration range of 0.01-0.5%, was tested in the same manner. The cornea was evaluated in vivo for ocular tolerance by confocal microscopy. In both rabbits and mice, the test revealed following irritation rankings: cationic>anionic>nonionic surfactants. Furthermore, in both animal models, the ocular damage increased with the concentration of benzalkonium. The test was sensitive enough to detect ocular microlesions at concentrations of surfactants as low as 0.01% for benzalkonium. These findings demonstrate the usefulness of confocal microscopy for the non-invasive, in situ evaluation of ocular tolerance.

Lipophilicity measurement of nicotinates by reversed-phase high-performance liquid chromatography : Differences in retention behaviour, but similarities of log kw values, in methanol-water and acetonitrile-water eluents

Abstract The lipophilicity of 22 nicotinate esters was examined by reversed-phase high-performance liquid chromatography using methanol-water and acetonitrile-water as eluents. In the former system, a linear relationship exists between the log of the capacity factor (log k ) and the fraction of modifier in the eluent. In contrast, the relationship is parabolic in the acetonitrile-water system. This behaviour is interpreted in terms of parabolic in the acetonitrile-water system. This behaviour is interpreted in terms of a dual retention mechanism, namely hydrophobic expulsion and polar (presumably silanophilic) interactions. Linear (methanol-water) and parabolic (acetonitrile-water) extrapolations to 0% modifier yielded practically identical log k w values ( r 2 = 0.980), indicating that for a given stationary phase, log k w is an index of hydrophobic effects independent of specific solute-modifier interactions. The log k w values correlate well with calculated log P oct values ( r 2 = 0.962 and 0.948).

Metabolic chiral inversion of anti-inflammatory 2-arylpropionates: lack of reaction in liver homogenates, and study of methine proton acidity

1. Enrichment in the (S)-enantiomers for (R)-flurbiprofen, (R)-naproxen, (R)-suprofen and (R;S)-ibuprofen was investigated in various subcellular hepatic preparations containing coenzyme A. While such preparations were able to form hippuric acid from benzoic acid, the chiral inversion was never seen. 2. Using 2-dimethylaminoethanethiol 2-phenylpropionate (DEPP) as a model acyl thioester, the acidity of the methine proton was investigated by monitoring the proton/deuterium exchange occurring in deuterated solvents using high-resolution n.m.r. The compound was inert up to 22 h in D2O at 37 degrees C and pD 7.4. In pure methanol or a methanol-water mixture, only solvolysis was seen. In contrast, competitive hydrolysis (k = 0.005 h-1) and proton/deuterium exchange (k = 0.09 h-1) were seen in a CD3CN/D2O (50:50) mixture at 37 degrees C. 3. It is speculated that the failure to characterize chiral inversion of 2-arylpropionates in subcellular preparations may be due to the absence of a microenvironment of adequately moderate polarity.

Stereoselective drug metabolism and its significance in drug research

Far from being a curiosity, chirality is a ubiquitous phenomenon in nature, ranging from the level of quanta and the parity violation in all weak interactions (e.g. the intrinsic left-handedness of the electron and its neutrino, and the right-handedness of the positron and its antineutrino) to an apparent excess of left-handed galaxies [1–5]. At the levels of material organisation explored by chemists, biochemists and biologists, namely the levels of molecules, biomolecules and living systems, chirality is of common occurrence and has since long been the object of intense interest.

Ocular tolerance of preservatives on the murine cornea.

We investigated the effects of instilling 13 commonly used preservatives on the murine cornea in vivo. Due to the instillation of preservatives, micro-lesions are formed on the cornea and can be selectively marked by fluorescein. The sum of the resulting fluorescent areas was measured using an episcopic microscope coupled to an image processing system. All the tested preservatives proved to be well-tolerated by the eye at commonly used concentrations. However, in some cases, increased concentrations of preservatives or combinations resulted in significant increase of the amount of corneal damage. With increasing the concentration, corneal lesion increased the most in the case of cetylpyridinium. While a combination of chlorobutanol 0.5% and phenylethylalcohol 0.5% did not result in an increase in corneal damage (when compared to the use of each separately), the associations of thiomersal 0.02% and phenylethylalcohol 0.4% on one hand and of edetate disodium (EDTA) 0.1% and benzalkonium 0.01% on the other, resulted in significant increases in the amount of corneal damage. However, in none of the tested combinations, the increase in the observed damage exceed the limit of ocular intolerance we had defined beforehand: thus, they were all deemed relatively well-tolerated. In the last part of the study, we investigated the effects of combining several preservatives, at usual concentrations, with an anesthetic solution of oxybuprocaine and found no notable increase in ocular damage.