Morphological study of burn wound healing with the use of collagen-chitosan wound dressing.

Experiments on the model of thermal skin burn in rats showed that the use of wound dressing based on collagen-chitosan complex Kollakhit-Bol in local treatment of grade IIIb skin burns increased healing rate by accelerating the formation of granulation and fibrous connective tissues and reducing crust thickness in comparison with Kollakhit coating. Kollakhit-Bol provided targeted stimulation of reparative processes in the treatment of grade IIIb burns by creating favorable conditions for grafting full thickness skin transplant or dermal-epidermal skin equivalent. In the topical treatment of thermal burn, Kollakhit-Bol application shortened the phases of alteration and exudation and accelerated transition to the productive phase of the inflammatory process with phagocytosis and neoangiogenesis activation.

Synthesis, Chemical and Biomedical Aspects of the Use of Sulfated Chitosan.

This work is devoted to the chemical synthesis of sulfated chitosan and its experimental verification in an animal model of early atherosclerosis. The method of chitosan quaternization with sulfate-containing ingredients resulted in a product with a high content of sulfate groups. Implantation of this product into the fascial-muscular sheath of the main limb artery along the leg and thigh in rabbits led to the extraction of cholesterol from the subintimal region. Simplified methods for the chemical synthesis of quaternized sulfated chitosan and the use of these products in a model of experimental atherosclerosis made it possible to perform a comparative morphological analysis of the vascular walls of the experimental and control limbs under conditions of a long-term high-cholesterol diet. The sulfated chitosan samples after implantation were shown to change the morphological pattern of the intimal and middle membranes of the experimental limb artery. The implantation led to the degradation of soft plaques within 30 days after surgical intervention, which significantly increased collateral blood flow. The implantation of sulfated chitosan into the local area of the atherosclerotic lesions in the artery can regulate the cholesterol content in the vascular wall and destroy soft plaques in the subintimal region.

Mouse hepatocytes retain the expression of the main differentiation markers during culturing on collagen-chitosan matrices.

Mouse hepatocytes cultured on artificial 3D collagen-chitosan biopolymer matrices retained the expression of hepatocyte markers for 14 days.