In at least one embodiment there is a wound application comprising at least one film applied over a wound comprising at least 1% green tea, and at least 0.01% sugar, wherein said film comprises a polymeric film comprising united chains and monomeric glucose points. In at least one other embodiment there is a wound application comprising a solution comprising at least trace amounts of colloidal silver, at least trace amounts of sodium chloride, at least trace amounts of dextrose; and water, wherein the colloidal silver, the sodium chloride and the dextrose are dissolved in water. In at least one other embodiment there is an application for treating a wound comprising both a solution comprising at least trace amounts of colloidal silver and a film comprising at least trace amounts of green tea applied over the solution on top of a wound.

The present disclosure is generally directed to an embolic material which, in some embodiments, may be in the form of a microsphere or a plurality of microspheres. The embolic material generally comprises carboxymethyl chitosan (CCN) crosslinked with carboxymethyl cellulose (CMC). In some embodiments, the embolic material may further comprise a therapeutic agent, such as doxorubicin.

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 invention relates to a method for preparation of a functionalized surface comprising the steps: a) coating of a carrier with a least one polymer selected from a polyanionic or polycationic polymer, b) addition of at least one compound to the coated carrier of step a), c) exposing the at least one polyanionic or polycationic polymer on the coated carrier of step b) to an organic solvent, resulting in compaction of the at least one polyanionic or polycationic polymer and thereby encapsulating the at least one compound, d) reversible cross-linking of the at least one polyanionic or polycationic polymer of step c) with at least one cross-linker; e) removal of the organic solvent. Furthermore, the invention relates to a functionalized surface, a functionalized surface for use in medicine and a method for releasing a compound ex vivo.

The invention is directed to a biological bandage derived from fish skin (e.g. tilapia skin) that can be used with healing of wounds such as burn wounds. The edible property of the fish skin biological bandage according to various embodiments makes it suitable for both human and veterinary medicine.

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

Disclosed herein are citrate-based mussel-inspired bioadhesives and methods of making and using the same. Also disclosed herein are methods of treating wounds.

Methods for applying a coating to a surface of a substrate for inhibition and prevention of implant-associated complications (including implant-associated infections), methods for inhibiting and preventing implant-associated complications (including implant-associated infections), implant-associated infection inhibiting coatings, and coated devices are provided. Coating processes include a) providing a saturated or supersaturated solution of an antibiotic in a fast-evaporating or medium-evaporating organic solvent; b) coating the surface of the substrate with at least one application of solution, each application followed directly by a solvent evaporation period.

Compositions or an assembly of a series of biomimetic compounds include chemical structures that mimic or structurally resemble a nucleic acid base pair. Complexes of nanotubes and agents are useful to deliver agents into the cells or bodily tissues of individuals for therapeutic and diagnostic purposes. Exemplary compounds include those of Formula (I), (III), (V) or (VII), or of Formula (II), (IV), (VI) or (VIII). ##STR00001##

A polymeric medical device/implant coating is disclosed for the delivery of drugs or therapeutic compounds such as antibiotics over an extended period of time and at levels or concentrations that exceed the MIC. In one embodiment, an antibiotic such as vancomycin is encapsulated in a photo-crosslinked poly(lactide-co-glycolide) (PLGA)-dimethacrylate coating. The drug release profile of this coating was studied and the initial burst was reduced by photo-crosslinking. Due to photo-crosslinking, an additional diffusional resistance was created, which prevented easy diffusion of the drug into the release medium. Moreover, the time required for this coating process is very quick (e.g., around 5 minutes) and makes it compatible for this coating to be applied in the operating room.