Relevance. The creation of porous three-dimensional materials for bone defects compensation and its subsequent regeneration is an important direction of medical materials science. The key issue in the interaction of an implant and bone tissue is the surface properties of the implant.The purpose of the study is to evaluate the physicochemical properties and compatibility of tissues of a living organism and porous implants with calcium phosphate Zn- and Ag-containing formed by microarc oxidation.Materials and Methods. Implants with various types of porous structure were made by direct laser sintering of titanium alloy Ti-6Al-4V powders. The calcium phosphate coatings, including Zn- and Ag-containing, were formed on the implants surface by microarc oxidation.Results. Coatings, deposited in electrolytes of various compositions, were uniformly distributed over the implants mesh structure. The phase composition of Zn-containing coatings, deposited in the acidic electrolyte, was represented by amorphous calcium phosphates. Ag-containing coatings, deposited in the alkaline electrolyte, had an amorphous-crystalline structure, the crystalline phase of which was identified as tricalcium phosphate in the α and β modifications. The samples of extracts of calcium phosphate Zn and Ag-containing coatings were co-cultured with pFb line of the human postnatal fibroblasts for 48 hours at 37°C in 5% CO2 atmosphere. The MTT test revealed a high metabolic activity of the co-cultured fibroblasts in comparison with the fibroblasts of control.Conclusion. The pFb line of the human postnatal fibroblasts retained their viability for 48 hours of co-culturing with calcium-phosphate Zn- and Ag-containing coatings. The tested product and its components did not negatively affect the cellular respiration. However, further studies are needed to determine the rate of bioresorption and the degree of antibacterial activity of calcium-phosphate Zn- and Ag-containing coatings.
Aim: to review current scientific literature concerning the main advances and problems of magnesium (Mg) alloys for traumatology and orthopedics. Methodology of the study. Analytical review based the comprehensive investigation of public scientific and technological sources. Results of the study. Modern knowledge about classification, in vitro and in vivo biodegradation, biomechanics, local and general biocompatibilities, clinical efficacy, and hazards of infectious complications in conditions of osteosynthesis with implants made of Mg alloys with or without protective (anticorrosion and antimicrobial) coatings is presented. Conclusion. Fast degradation and a risk of periprosthetic infection strongly limit clinical application of implants made of Mg and its alloys. Development of novel Mg alloys and their modification by incorporating antimicrobial elements into their body or protective coating is a promising direction to control biomedical characteristics of Mg alloys.
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