Formulation and evaluation of novel collagen/ carboxymethylcellulose blend film wound dressing.

Films are thin, flexible, and transparent wound dressings. They can be prepared from both synthetic and natural materials. In practice, synthetic polyurethane dominates, but research is mainly focused on substances of natural origin. An endogenous substance with excellent filmforming properties, which is involved in the wound healing process, is collagen. However, collagen films themselves have weak mechanical properties, which can be improved by, among other things, combining collagen with other materials. Such material could be carboxymethylcellulose, which has been shown to affect wound healing positively. Films consisting only of CMC also have weak mechanical properties, so combining both materials seems to be a suitable solution to the given problems, and a wound dressing with many beneficial properties for wound healing could be created. Therefore, our experiment aimed to prepare composite films for wound therapy consisting of a combination of collagen and CMC. The films were prepared by the solvent evaporation method, and their properties were compared with those formed only by CMC. In both cases, films with suitable organoleptic, physicochemical, and application properties for wound therapy were produced. The composite films showed lower absorption capacity and better mechanical resistance compared to those formed only by CMC. The combination of collagen and CMC in composite films intended for wound therapy has thus resulted in improved properties of the resulting dressing and holds potential for further research.

Formulation and Evaluation of Novel Film Wound Dressing Based on Collagen/Microfibrillated Carboxymethylcellulose Blend.

Collagen is essential as a physiological material in wound healing, so it is often used in wound management, mainly as a lyophilisate. Collagen also has excellent film-forming properties; unfortunately, however, its utilisation as a film wound dressing is limited because of its weak mechanical properties, especially in its wet state. For this reason, modifications or combinations with different materials are investigated. The combination of collagen with partially modified microfibrillar carboxymethylcellulose (CMC), which has not previously been described, provided a new possibility for strengthening collagen films and was the aim of this work. The collagen-CMC films based on three types of collagens, two plasticizers and two collagen. Plasticiser ratios were prepared using the solvent casting method; partially modified CMC served here as both a film-forming agent and a filler, without compromising the transparency of the films. The presence of microfibrils was confirmed microscopically by SEM. Organoleptic and physicochemical evaluation, especially in terms of practical application on wounds, demonstrated that all the samples had satisfactory properties for this purpose even after wetting. All the films retained acidic pH values even after 24 h, with a maximum of 6.27 ± 0.17, and showed a mild degree of swelling, with a maximum of about 6 after 24 h.

Films from poly-γ-glutamic acid and poly-ε-lysine as the potential wound dressings ­ formulation, preparation and evaluation

Film wound dressings represent one of the options in wound therapy. Various polymers can be used for their production. Currently, research focuses on materials of natural origin, more friendly to the human body, which are in many cases able to participate actively in the wound healing process. These include polyamino acids of bacterial origin, substances that are biodegradable, non-toxic, and have a great potential for an application not only in the medical field. From the point of view of film wound dressing formulation, poly-γ-glutamic acid (PGA), as a film-forming agent, and poly-ε-lysine (PL), characterized by antimicrobial activity, are of interest from this group. Therefore, the aim of our experiment was to prepare films consisting of PGA or a combination of PGA and PL with the addition of different plasticizers. The films were prepared by solvent evaporation method and then evaluated for their organoleptic (appearance, colour, transparency, ease of handling), physicochemical (thickness, density, opacity, surface pH), and mechanical properties (tensile strength and tear resistance). As a result, films showing mutual compatibility between the two polymers were obtained, with satisfactory properties for wound application.

Collagen in combination with the acid form of carboxymethylcellulose in the form of a nonwoven textile as a modern wound dressing - formulation, preparation and evaluation.

The acid form of carboxymethylcellulose (HCMC) is less known than its sodium salt (NaCMC). However, it is commonly used as a sorbent for chromatographic columns and has a number of valuable properties for its use in wound care. As a wound dressing in the form of hydrofibers, it is already commercially available on our market. Collagen, the most abundant protein in the human body, fulfils both a building and a physiological function in the body, also has an irreplaceable place in the treatment of wounds. It is important in the process of wound healing and is used in wound therapy in various forms. It exhibits very good film-forming properties as well, but the collagen-based films themselves have weaker mechanical resistance, which limits their successful application to a wound. Therefore, the effort is to combine collagen with other materials in order to ensure better mechanical and application properties even in the wet state. The aim of this experiment was to create a wound dressing by combining a collagen film with HCMC in the form of a nonwoven textile. The resulting dressing had satisfactory organoleptic, physicochemical (pH, absorbency) and application properties for its use in wound therapy. The textile HCMC formed a mechanical support for collagen, which enabled its saving during the dressing preparation and partly served as an absorbent layer.

Film wound dressing containing dexpanthenol - preparation and evaluation.

Currently, a wide variety of wound dressings of varying composition and effects is used to treat wounds. These include also film dressings where one of the promising materials for its preparation is sodium carboxymethylcellulose (NaCMC) as a material of natural origin with excellent film-forming properties. Its application is particularly in the field of absorbent dressings, films for wounds from this material are not used in practice yet. Hidden potential offers also dexpanthenol, a substance widely used in dermatological practice. Therefore, the aim of this research was to prepare films from textile NaCMC with dexpanthenol by the solvent evaporation method and their subsequent physicochemical evaluation. The presence of microfibrillar fibers of partially substituted carboxymethylcellulose together with HCMC has ensured optimal parameters for wound application such as pH, swelling and mechanical properties. The films showed satisfactory mass content uniformity and those with dexpanthenol also drug content uniformity.

Preparation and evaluation of bilayer films based on collagen and carboxymethylcellulose for wound therapy.

Collagen is the most abundant protein of the human body and a widely used biomaterial across sectors due to its favourable properties resulting from its physiological proximity. It plays a key role in the process of wound healing and tissue repair and is therefore used in modern wound dressings in various forms, either alone or in combination with other materials. Collagen films also offer potential applications for these purposes, because collagen has good film-forming properties and is commonly used in the food industry. The collagen films themselves, without further treatment, have weak mechanical properties, which is unsatisfactory when applied to a wound. For this reason, there is an effort to modify or to combine collagen with other materials. Therefore, the aim of our experiment was the preparation of bilayer films from collagen in combination with carboxymethylcellulose (CMC). The CMC in the bottom layer had a goal to strengthen the films, reduce the consumption of used collagen and to ensure suitable application properties. Organoleptic evaluation, pH determination, swelling properties evaluation and testing of the mechanical properties of the prepared films confirmed that the prepared films exhibited satisfactory application parameters for the wound.