The biocompatibility of a polyelectrolyte vitreous body substitute on a high resistance in vitro model of the blood-retinal barrier.

The vitreous body can be regarded as a fascinating simple but important tissue, since it represents the main compartment of the eye and plays a crucial role for proper vision. Several diseases require its removal with following substitution using a liquid artificial vitreous body replacement. We explore the biocompatibility of a poly(AMPS-Na(+))-graft-poly(NIPAAm) polyelectrolyte following the innovative concept of thermo-responsive behaviour, exhibiting enhanced shear viscosity at physiological temperatures. As a powerful model for the blood-retinal barrier, we use the well-established in vitro cell culture model based on highly differentiated porcine brain capillary endothelial cells. Via the quantification of the transendothelial electrical resistance and immunocytochemical staining of tight junction proteins, we are able to show that a barrier integrity affecting impact of the polyelectrolyte was only transient and nearly reversible. Furthermore, the polyelectrolyte hydrogel is characterized by the absence of any acute cell morphology, cell vitality or proliferation affecting impacts. It does not trigger acute apoptotic processes, as can be substantiated via caspase-3 activity and DNA fragmentation assays. In view of the results of this study, it is shown that the polyelectrolyte does not affect the vitality parameters of our porcine brain capillary endothelial cells. It can be suggested that the tested thermo-responsive polyelectrolyte does not affect the sensitive retinal barrier integrity. Thus from the cellular tolerance it might serve as a potential liquid artificial vitreous body replacement to overcome the most prominent difficulties of common vitreal endotamponades.