A three-dimensional network aqueous gel and a manufacturing method thereof are disclosed. A water-soluble polymer is first added into a solvent and uniformly mixed, followed by hydrolysis to form a sol, and vacuum is applied to convert the sol into a gel, followed by a polycondensation reaction to form a three-dimensional network aqueous gel. The three-dimensional network aqueous gel is formed of the water-soluble polymer that includes a group including sodium alginate and sodium carboxymethyl cellulose. The water-soluble polymer is interconnected to form a three-dimensional network structure. The three-dimensional network aqueous gel is of a gel-enclosed form, which uses the three-dimensional network structure formed of a high-molecule polymer to enclose medicine, so as to more effectively protect the active ingredient and provide an effect of controlled released to thereby extend therapeutic period and reduce side effects of irritating skin.

The present invention discloses a partially crosslinked hydrogels blended composition with enhanced viscosity and yield stress, which is formed by the polymerization of one or more colloid monomers through crosslinking. The polymerization is initiated by a photoinitiator under irradiation of the light of a specific wavelength, which promotes crosslinking of the one or more colloid monomers. The hydrogels blended composition can be further crosslinked with one or more other colloid monomers through repeated excitation of the photoinitiator. The hydrogels blended composition can be polymerized into a gel upon re-irradiation, and can also be used as a biomaterial for wound repair, three-dimensional cell culture, personal nursing care, health care, medical and pharmaceutical applications.

The present disclosure provides a coacervate composition containing a protein drug, gelatin A, sodium alginate and an acid and a wound-healing agent including the same. The coacervate composition according to the present disclosure can be useful as a wound-healing material delivery system for effectively delivering a protein drug, particularly epidermal growth factor, to a wound site in the wound-healing field.

The present technology generally relates to a biomaterial that includes a thiolated biopolymer and one or more agents that include growth factors, peptides, or combinations thereof, where the one or more agents are conjugated to the thiolated biopolymer. Also disclosed herein are wound dressings that include the biomaterial of the present technology, methods of treating a wound upon application of the wound dressing, and kits including the wound dressing and instructions for use.

The present disclosure provides an anti-infective and anti-adhesive wound dressing based on nonspecific adhesion to bacteria, which includes a micron-sized porous membrane with polyolefin contained in its surface and does not contain any bactericide. According to the disclosure, through targeted selection of a material and surface structure of the porous membrane, nonspecific adhesion to the bacteria on the wound surface can be formed by good adaptability of its own surface energy and the structure of the porous membrane to surface energy of the bacteria, preventing the bacteria from penetrating into wound tissues and thus realizing the anti-infection for the bacteria and the anti-adhesion to the wound. Furthermore, no bactericide is required to be added, which not only reduces infection of the wound, but also weakens factors which are not conducive to wound healing, such as aggravation of inflammation caused by bacterial toxin released after bacterial rupture in traditional sterilization mechanisms.

The present invention provides a modified collagen comprising S-nitroso groups and a method of manufacture of such a modified collagen. Also provided is a wound dressing comprising such a modified collagen, particularly a wound dressing comprising a formulated composition comprising such a modified collagen.

Devices for delivering a flowable tissue dressing material for treating a tissue site are described. The devices include a first zone including a first reactant, such as a polyol, and a second zone including a second reactant, such as a multi-isocyanate, which can be mixed together to form a flowable tissue dressing material. The device can also include a flowable tissue dressing material including a reacted polymer present in a carrier. Kits and methods including and/or using the devices are also described.

Interpenetrating network hydrogels with independently tunable stiffness enhance tissue regeneration and wound healing.

The present invention provides a method of producing a modified collagen, including the steps of: providing a collagen comprising a S—S bond; introducing a —SH group in said collagen comprising a S—S bond by reduction of the S—S bond to provide a collagen thiol comprising a —SH group; and nitrosating the —SH group of the collagen thiol to provide a modified collagen, said modified collagen comprising S-nitroso groups.

A device and method for forming fibrin foam, preferably utilizing a single container, comprising a base structured to be rotationally driven and including a separation chamber disposed and structured to receive a blood sample therein. The base includes a reaction chamber disposed in fluid communication with said separation chamber. The blood sample is separated into a plasma segment and a packed cell segment when subjected to sufficient centrifugation concurrent to the driven rotation of the base. According to structural features, and in some instances concurrent and continuous centrifugation, the plasma segment is directed from said separation chamber into said reaction chamber which includes sufficient quantities of gas and reactant composition to facilitate formation of fibrin foam therein concurrent to centrifugation. Further centrifugation of the fibrin foam and the inclusion of additional features such as a pressurized reaction chamber facilitate the formation of fibrin foam exhibiting varying chemical and/or physical properties.