Neomycin trisulfate

Glutaraldehyde (GLUT) crosslinked bioprosthetic heart valves (BHVs) might fail within ten years due to progressive degradation and calcification. GLUT cannot stabilize glycosaminoglycans (GAGs), one important component of BHVs. In this current study we developed a new BHVs preparation strategy named as 'HPA/NT/HRP' treatment that utilized 3,4-hydroxyphenylpropionic acid (HPA)/tyramine (TRA)/neomycin trisulfate (NT) conjugated pericardiums and horseradish peroxidase (HRP)/H2O2 enzyme-oxidative-polymerization method. HPA/TRA-pericardium and HPA-NT conjugation would provide extra phenol groups for enzymatic crosslinking. HPA/TRA conjugated pericardium could be crosslinked by HRP/H2O2 enzyme-oxidative-polymerization. The feeding ratio of HPA-NT was optimized. The GAGs content, collagenase and elastase degradation in vitro, the in vivo GAGs stability and anti-calcification potential of HPA/NT/HRP treated pericardiums were characterized. We demonstrated that HPA/NT/HRP treated pericardiums had sufficiently increased GAGs stabilization and decreased calcification. This new HPA/NT/HRP enzyme-oxidative-polymerization strategy would be a promising method to make BHVs with better GAGs stability and anti-calcification properties.

This paper reports new physical hydrogels obtained by the freezing/thawing method. They include pullulan (PULL) and poly(vinyl alcohol) (PVA) as polymers, bovine serum albumin (BSA) as protein, and a tripeptide, reduced glutathione (GSH). In addition, a sample containing PULL/PVA and lysozyme was obtained in similar conditions. SEM analysis evidenced the formation of networks with porous structure. The average pore size was found to be between 15.7 μm and 24.5 μm. All samples exhibited viscoelastic behavior typical to networks, the hydrogel strength being influenced by the protein content. Infrared spectroscopy analysis revealed the presence of intermolecular hydrogen bonds and hydrophobic interactions (more pronounced for BSA content between 30% and 70%). The swelling kinetics investigated in buffer solution (pH = 7.4) at 37 °C evidenced a quasi-Fickian diffusion for all samples. The hydrogels were loaded with neomycin trisulfate salt hydrate (taken as a model drug), and the optimum formulations (samples containing 10-30% BSA or 2% lysozyme) proved a sustained drug release over 480 min in simulated physiological conditions. The experimental data were analyzed using different kinetic models in order to investigate the drug release mechanism. Among them, the semi-empirical Korsmeyer-Peppas and Peppas-Sahlin models were suitable to describe in vitro drug release mechanism of neomycin sulfate from the investigated hybrid hydrogels. The structural, viscoelastic, and swelling properties of PULL/PVA/protein hybrid hydrogels are influenced by their composition and preparation conditions, and they represent important factors for in vitro drug release behavior.

The bioprosthetic heart valves (BHVs) are the best option for the treatment of valvular heart disease. Glutaraldehyde (Glut) is commonly used as the golden standard reagent for the crosslinking of BHVs. However, the obvious defects of Glut, including residual aldehyde toxicity, degradation and calcification, increase the probability of valve failure in vivo and motivated the exploration of alternatives. Thus, the aim of this study is to develop a non-glutaraldehyde hybrid cross-linking method composed of Neomycin Trisulfate, Polyethylene glycol diglycidyl ether and Tannic acid as a substitute for Glut, which was proven to reduce calcification, degradation, inflammation of the biomaterial. Evaluations of the crosslinked bovine pericardial included histological and ultrastructural characterization, biomechanical performance, biocompatibility and structural stability test, and in vivo anti-inflammation and anti-calcification assay by subcutaneous implantation in juvenile Sprague Dawley rats. The results revealed that the hybrid crosslinked bovine pericardial were superior to Glut crosslinked biomaterial in terms of better hydrophilicity, thermodynamics stability, hemocompatibility and cytocompatibility, higher Young's Modulus, better stability and resistance to enzymatic hydrolysis, and lower inflammation, degradation and calcification levels in subcutaneous implants. Considering all above performances, it indicates that the hybrid cross-linking method is appropriate to replace Glut as the method for BHV preparation, and particularly this hybrid crosslinked biomaterials may be a promising candidate for next-generation BHVs.