The invention relates to a bio-conjugate comprising a chitosan derivative coupled to antimicrobial peptides (AMPs) for use in the treatment or prevention of microbial infections such as wound healing. The invention also provides a nanoparticles formulation or a gel/hydrogel formulation or a lyophilized foam formulation comprising the bio-conjugate of the invention.

A system for treating open wounds includes a foam material configured for pouring, spraying, injecting or spreading on a wound bed. The foam material can comprise a base component and a curing component, which can be pre-mixed before application, or mixed in situ as the components are being applied to the wound site. A third component can comprise a sacrificial porogen. Foam can be placed in the wound bed as a wound liner on the wound surfaces. An additional foam insulation can provide a foam filler partially contained by the wound liner and generally flush with a patient's epidermis. A method of treating open wounds includes the steps of applying the wound liner and filler components. An optional step comprises covering the wound liner with a semi-permeable (breathable) membrane and mounting inlet and outlet ports thereon for introducing healing compositions as input, and extracting wound exudates as output.

The invention relates to a gel comprising a first gelatin component and a second gelatin component in an aqueous medium, wherein the first gelatin component comprises gelatin particles comprising chemical cross-links and dehydrothermal cross-links; and the second gelatin component comprises a dissolved gelatin comprising chemical cross-links and at least one polysaccharide.

The present invention relates to a hemostatic composition including collagen, a stabilizer, and thrombin, and a container holding this hemostatic composition. The hemostatic composition and the container holding this hemostatic composition can be applied to an urgent bleeding patient by a simple method of use, and the hemostatic composition is less toxic, does not have a problem of blood infection, has a fast rate of biodegradation, has an excellent hemostatic effect, and can be usefully used as a hemostat.

The present disclosure provides a method for freeze-drying cells in a hydrogel comprising nanofibrillar cellulose, the method comprising providing a hydrogel comprising nanofibrillar cellulose, providing cells, combining the cells and the hydrogel comprising nanofibrillar cellulose to form a cell system, and freeze drying the cell system to obtain dried cells in a hydrogel comprising nanofibrillar cellulose. The present disclosure also provides a freeze-dried hydrogel comprising nanofibrillar cellulose and cells.

Described herein are biocompatible materials that include a nitric oxide (NO) donor embedded in silk fibroin nanoparticles. In one aspect, the nitric oxide donor is present in the hydrophobic core of the silk fibroin nanoparticles such that the nitric oxide donor is encapsulated. The biocompatible materials described herein serve as a biocompatible and inexpensive nitric oxide delivery platform that provide sustained release of nitric oxide. The biocompatible materials are non-toxic and can be used in biomedical applications such as wound healing, where a combination of therapeutic and antibacterial properties of silk and nitric oxide are desired. Additionally, described herein are methods of making the biocompatible materials.

The present disclosure discloses a starch-based fluffy particle, a preparation method and use thereof. The preparation method of the starch-based fluffy particle comprises the following steps of: (1) adding water into starch or modified starch for gelatinization to obtain a starch paste; (2) adding the starch paste into a polar organic solvent, stirring, standing and centrifuging to collecting a precipitate; and (3) freeze-drying, crushing and sieving the precipitate in sequence to prepare the starch-based fluffy particle. The starch-based fluffy particles are porous and fluffy with a large pore size, have excellent water absorption speed, water absorption rate and degradation rate, and can achieve the purpose of rapid and efficient hemostasis. Moreover, the starch-based fluffy particles are free of dispersing agent, emulsifying agent or cross-linking agent, have the characteristics of safety and reliability, and can meet the hemostatic requirement of in-vivo environment.

An example female fluid collection assembly includes a fluid impermeable barrier. The fluid impermeable barrier at least defines a chamber and an opening. The female fluid collection assembly also includes at least one porous material disposed in the chamber. The porous material extends across the opening. In an embodiment, the portion of the porous material that extends across the opening include a protrusion that extends outwardly from the opening. In an embodiment, the porous material includes at least one expandable material that is configured to expand (e.g., increase in volume) when the expandable material exposed to one or more bodily fluids (e.g., urine).

Dressings which may be useful in disrupting and/or preventing biofilm formation in a wound upon application are described, where the dressings of the present technology include a co-polymer of polyvinylpyrrolidone (PVP) and citric acid. Also disclosed herein methods employing such dressings as well as kits including such dressings.

The present invention relates, in part, to hydrophobically-modified polymers and foams and their use in the control of bleeding.