PHYSICO-CHEMICAL PROPERTIES OF A NANOCOMPOSITE HYDROGEL COATING ON A TEXTILE CARRIER FOR THE WOUND TREATMENT

Нанотехнологии с использованием биополимеров находят широкое применение в биомедицинских приложениях. В данной работе разработаны нанокомпозитные гидрогели на основе природных (хитозан, карбоксиметилцеллюлоза) и синтетических (поливиниловый спирт) полимеров с наночастицами серебра для нанесения на текстильный носитель. В качестве сшивающих реагентов при создании гидрогелей использовали диальдегид карбоксиметилцеллюлозы и борную кислоту. Были определены физико-химические свойства (сорбционная способность при одностороннем контакте с модельной средой, степень набухания, паропроницаемость, капиллярность) гидрогелевых покрытий на текстильном носителе, и кинетика выхода лекарственных веществ (лидокаин, диоксидин), включенных в состав гидрогелей. Показано, что материалы с двухслойным покрытием характеризуются более высокими сорбционными свойствами по отношению к физиологическому раствору и более длительным выходом лекарственных средств, чем материалы с однослойным покрытием. Выход лекарственных веществ из двухслойных покрытий происходит в два этапа с максимальным высвобождением в течение двух суток. Полученные текстильные материалы с пленочным нанокомпозитным гидрогелевым покрытием могут найти применение в качестве перевязочных средств при лечении ран. Nanotechnologies using biopolymers are widely used in biomedical applications. In this work, nanocomposite hydrogels based on natural (chitosan, carboxymethylcellulose) and synthetic (polyvinyl alcohol) polymers with silver nanoparticles for application to a textile carrier have been developed. Carboxymethylcellulose dialdehyde and boric acid were used as crosslinking reagents in the creation of hydrogels. Physicochemical properties (sorption capacity in unilateral contact with the model medium, degree of swelling, vapor permeability, capillarity) of hydrogel coatings on a textile carrier, and the kinetics of the drugs release (lidocaine, dioxidine) included in the hydrogels were determined. It is shown that materials with a two-layer coating are characterized by higher sorption properties relative to saline and a longer release of drugs than materials with a single-layer coating. The release of drugs from the two-layer coatings occurs in two stages with a maximum release within two days. The obtained textile materials with a film nanocomposite hydrogel coating can be used as dressings in the treatment of wounds.

Results of application composite hydrogel coatings based on polyvinyl alcohol in the experiment

The results of the use in the experiment of composite hydrogel coatings of prolonged action based on polyvinyl alcohol are investigated.Objective. The aim of the study is a comparative clinical assessment of the effectiveness of the developed composite hydrogel coatings of prolonged action in an experiment in laboratory rats.Materials and research methods. After modeling alloxan diabetes mellitus and neuroischemic form of diabetic foot in laboratory white Wistar rats, the developed wound dressings were applied. A clinical analysis of their effectiveness was carried out and the optimal composition was determined. The animals were divided into three groups, 10 animals in each group, as follows: the first — control with self-healing of the wound, the second — with samples No. 1 (polyvinyl alcohol + chitosan + pectin + L-aspartic acid + gentamicin), the third — with samples No. 2 (polyvinyl alcohol + chitosan + pectin + L-aspartic acid + gentamicin + methyluracil). The first dressing change was carried out on the third day with the taking of histological material, then - every other day. When changing the dressing, such parameters as the nature and amount of wound discharge, the size of the ulcer, the presence of granulations and epithelialization were assessed. Dynamic assessment was performed on the 3rd, 7th, 14th and 21st days. The measurement of the area of the ulcer was carried out by transferring the contour of the ulcer to graph paper with manual counting.Research results. The healing rate of ulcers in the experimental groups was higher than in the control group. When comparing second and third groups, a significant increase in speed was noted by the seventh day in third group (p < 0.05), which reduced the overall healing time of ulcers by 7 days.Conclusion. The study showed that the healing time of ulcers in laboratory animals with the use of the developed wound dressings is significantly reduced in comparison with the control group. The proposed method of local treatment can be considered effective in the treatment of vascular etiology trophic ulcers against the background of diabetes mellitus.

Renatured hydrogel painting

Hydrogel coatings pave an avenue for improving the lubricity, biocompatibility, and flexibility of solid surfaces. From the viewpoint of practical applications, this work establishes a scalable method to firmly adhere hydrogel layers to diverse solid surfaces. The strategy, termed as renatured hydrogel painting (RHP), refers to adhering dehydrated xerogel to a surface with appropriate glues, followed by the formation of a hydrogel layer after rehydration of the xerogel. With the benefits of simplicity and generality, this strategy can be readily applied to different hydrogel systems, no matter what the substrate is. Hydrogel adhesion is demonstrated by its tolerance against mechanical impact with hydrodynamic shearing at 14 m/s. This method affords powerful supplements to renew the surface chemistry and physical properties of solid substrates. In addition, we show that the RHP technique can be applied to living tissue, with potential for clinical applications such as the protection of bone tissue.

Localized Enzyme-Assisted Self-Assembly in the Presence of Hyaluronic Acid for Hybrid Supramolecular Hydrogel Coating

Hydrogel coating is highly suitable in biomaterial design. It provides biocompatibility and avoids protein adsorption leading to inflammation and rejection of implants. Moreover, hydrogels can be loaded with biologically active compounds. In this field, hyaluronic acid has been largely studied as an additional component since this polysaccharide is naturally present in extracellular matrix. Strategies to direct hydrogelation processes exclusively from the surface using a fully biocompatible approach are rare. Herein we have applied the concept of localized enzyme-assisted self-assembly to direct supramolecular hydrogels in the presence of HA. Based on electronic and fluorescent confocal microscopy, rheological measurements and cell culture investigations, this work highlights the following aspects: (i) the possibility to control the thickness of peptide-based hydrogels at the micrometer scale (18–41 µm) through the proportion of HA (2, 5 or 10 mg/mL); (ii) the structure of the self-assembled peptide nanofibrous network is affected by the growing amount of HA which induces the collapse of nanofibers leading to large assembled microstructures underpinning the supramolecular hydrogel matrix; (iii) this changing internal architecture induces a decrease of the elastic modulus from 2 to 0.2 kPa when concentration of HA is increasing; (iv) concomitantly, the presence of HA in supramolecular hydrogel coatings is suitable for cell viability and adhesion of NIH 3T3 fibroblasts.