Influence of physically crosslinked gelatins on the vasculature in the avian chorioallantoic membrane.

Gelatins functionalized with desaminotyrosine (DAT) or desaminotyrosyl tyrosine (DATT) form physically crosslinked hydrogels, due to the interactions between the introduced aromatic moieties and gelatin triple helices, whose extent depends on the thermal treatment of the material. The G-modulus of these hydrogels can be tailored to the range of the natural extracellular matrix by adjusting the degree of crosslinking. While these gelatin-based materials have been shown to be not angiogenic, the aim of the study was to evaluate whether these biomaterials influence the regulation of blood vessels when positioned on the chorionallantoic membrane (CAM) of fertilized eggs. The results clearly indicate that the DAT-functionalized gelatin led to an increase of the diameter of the blood vessels in the CAM, which at the same time is probably associated with an increased blood flow in these CAM vessels. The vessel diameters of the four groups (DAT-functionalized gelatin, DATT-functionalized gelatin, plain gelatin, control group without gelatin, each n = 10) differed significantly (p < 0.0001). Vessels in the CAM exposed to the DAT-functionalized gelatin showed with 36.4 µm ± 3.4 µm the largest mean diameters compared to the mean diameters of the samples exposed to DATT gelatin (16.0 µm ± 0.8 µm; p < 0.05) and the plain gelatin (21.2 µm ± 1.0 µm; p < 0.05), which both did not differ significantly from the vessels of the control group. The biocompatibility of the materials in vitro motivates the exploration of their application as matrix in local drug-release systems with short half-life times (one hour up to several days).

Physically crosslinked gelatins functionalized with tyrosine moieties do not induce angiogenesis or thrombus formation in the developing vasculature in the avian chorioallantoic membrane.

Gelatins functionalized with desaminotyrosine or desaminotyrosyl tyrosine form physically crosslinked polymer networks due to the interactions between the introduced aromatic moeties. In the swollen state, their mechanical properties can be tailored in a range similar to the elasticity of soft tissues. The aim of this study was to evaluate their potential as biomaterials by determining whether these materials - in comparison to plain gelatin - induce bleedings, thrombotic processes, or angiogenesis. These investigations were performed using the hen's egg chorioallantoic membrane (HETCAM) assay. These results indicate that the gelatin-based hydrogels did not possess angiogenic effects and also did not induce bleedings, thrombotic processes or vessel destruction (avascular zones). The biocompatibility of the materials in vitro motivates the exploration of their application as matrix in local drug-release systems with short half-life times (1 hour up to several days).

Multi-scale analysis of the toraymyxin adsorption cartridge. Part I: molecular interaction of polymyxin B with endotoxins.

Endotoxins or lipopolysaccharides are the main constituents of the outer leaflet of Gram-negative bacteria membrane and play a central role in the pathogenesis of the septic shock. Polymyxin B has both antibacterial and antiendotoxin capability; indeed it is able to destroy the bacterial outer membrane and bind endotoxin neutralizing its toxic effects. Cartridges containing polymyxin B-immobilized fibers (Toraymyxin PMX-F, Toray Industries, Japan) are used in extracorporeal hemoperfusion to remove circulating endotoxin. The aim of this study is the characterization of the polymyxin B-endotoxin system at the molecular level, thus providing quantitative evaluation of the binding forces exerted in the molecular complex. Polymyxin B was interfaced with five molecular models of lipopolysaccharides differing in their structure and molecular mechanics simulations were performed at different intermolecular distances aimed at calculating the interaction energies of the complex. Binding forces were calculated by fitting interaction energies data. Results show that in the short range the polymyxin B-endotoxin complex is mediated by hydrophobic forces and in the long range the complex is driven by ionic forces only. From a mechanical standpoint, polymyxin B-endotoxin complex is characterized by maximum binding forces ranging between 1.39 nN to 3.79 nN. The knowledge of the binding force behavior at different intermolecular distances allows further investigations at higher scale level (Part II).