Biodegradable three-dimensional networks of poly(dimethylamino ethyl methacrylate). Synthesis, characterization and in vitro studies of structural degradation and cytotoxicity.

In ophthalmology, there is a need for novel degradable biomaterials for e.g. controlled drug release in the vitreous body. These degradable materials should feature both excellent biocompatibility, and well-defined kinetics of degradation. In most cases, poly(D,L-lactic acid), or poly(lactic-co-glycolic acid) are used. These materials, however, suffer from some serious drawbacks, since the degradation kinetics are difficult to control, especially since the so-called 'burst-degradation' occurs. Here, we describe a set of novel polymeric networks which largely consist of poly(dimethylamino ethyl methacrylate) (poly(DMAEMA)); these materials are crosslinked via a dimethacrylate molecule that contains two carbonate groups. This system is susceptible to hydrolytic scission. The degradation products do not exert a catalytic effect on the ongoing degradation reaction (i.e. there is no burst effect). We describe the synthesis of three of these materials, which differ merely with regard to the crosslinker content. These materials were characterized through DMTA, 1H NMR and FT-IR spectroscopy, and scanning electron microscopy. The reaction DMAEMA + 2-hydroxyethyl methacrylate (HEMA) was studied in detail, using 1H NMR spectroscopy, and these experiments revealed that the reaction of DMAEMA and HEMA produces a random (Bernouillian-type) copolymer. From this, we contend that the new materials have more or less uniform distribution of the crosslinks throughout their volume. Structural degradation of the three materials was studied in vitro, at pH 7.4, 9.1 and 12.0. It is found that the materials exhibit smooth hydrolysis, which can be controlled via the crosslink density and the pH, as was expected a priori. It should be noted that degradation of these materials produces non-hydrolysable, but water-soluble, oligo(DMAEMA) and poly(DMAEMA) molecules. We subsequently performed in vitro studies on the biocompatibility of these materials. The MTT cytotoxicity assay revealed that the materials were cytotoxic to chondrosarcoma cells. This is most probably due to local increase of the pH due to the basic character of the pending dimethylamino groups. Cytotoxicity remained virtually unchanged after extended washing with water. This indicates that the cytotoxicity is an intrinsic property of the material and was not caused by remnants of free monomer. Cytotoxicity was also seen in cell cultures (human fibroblasts isolated from donor corneas) which were grown in contact with the materials. It is concluded that the new materials have attractive degradation characteristics, but their cytotoxicity makes them unsuitable for applications in ophthalmology.

Tailoring of new polymeric biomaterials for the repair of medium-sized corneal perforations.

The aim of this study was to investigate whether polymeric biomaterials can be designed such that they become suitable for surgical closure of medium-sized perforations in the cornea, the transparent tissue in the front of the eye. Such a biomaterial must meet stringent requirements in terms of hydrophilicity, strength, transparency, flexibility, and biocompatibility. Four different copolymers of n-butyl methacrylate (BMA) and hexa(ethylene glycol) methacrylate (HEGMA) were prepared and characterized. Poly(BMA) was made as a reference material. Physicochemical properties were measured (contact angles, glass-transition temperatures, thermal degradation, water uptake and swelling), and cytotoxicity in vitro was assessed with a MTT test. Moreover, the interaction between the materials and cultured human corneal epithelial cells was studied. The copolymers may be useful for temporary closure of corneal perforations.

New biodegradable networks of poly(N-vinylpyrrolidinone) designed for controlled nonburst degradation in the vitreous body.

Polymers of N-vinylpyrrolidinone (NVP) are known to have excellent biocompatibility when implanted in the vitreous body or used as a vitreous substitute. Although poly(NVP) is capable of absorbing relatively large amounts of water, it is not prone to hydrolysis. Yet intraocular degradation of several crosslinked poly(NVP) hydrogels has been reported recently, but some ambiguity remains about the exact mechanism of degradation of these materials. To date there is no biomaterial that combines the excellent intraocular biocompatibility on the one hand and controlled kinetics of degradation on the other hand. We attempted to design and prepare such materials through the chemical synthesis of a novel dimethacrylate crosslinker molecule. The essential feature of this molecule is that its core contains two carbonate groups, which are evidently susceptible to hydrolytic scission. We studied a series of 3-dimensional networks of poly(NVP), which were crosslinked by this molecule. This approach offers several advantages: the hydrolysis of the carbonate groups in the crosslinks leads to liberation of poly(NVP) and/or oligo(NVP) chains that can probably be cleared from the eye via phagocytosis; hydrolysis generates two alcohols and CO(2) (i.e., there is no catalytic burst effect); when these materials are implanted in dry form, swelling and degradation will progress from the exterior of the material toward its interior. Therefore, these materials can be designed such that surface degradation rather than bulk degradation occurs; the hydrolysis rate can be controlled via the crosslink density or through synthesis of other crosslink molecules with either more (>2) or less (1) carbonate groups or alternatively with one or more other labile groups. We report on the chemical synthesis of the crosslinker molecule, as well as the preparation and degradation of a series of poly(NVP)-based hydrogels in vitro and in vivo (rabbit eyes). We found that these materials indeed displayed excellent biocompatibility in the rabbit eye. Further, the experiments confirmed that degradation occurs without the burst effect. The results are in line with the idea that the rate of intraocular swelling and degradation depends on the crosslink density, but this is only a preliminary conclusion that must be strengthened by much more experimental work. Nonetheless, we foresee several applications of these or related materials in ophthalmology, for example, as biodegradable matrix materials for controlled drug delivery of ganciclovir in the vitreous body.