An antimicrobial coating is formed from a biocompatible flexible polymer having incorporated therein an active material having a reducible form of silver, where at least a portion of the active material is exposed at the surface of the polymer. The coating can be applied to the surface of a catheter to inhibit bacterial growth and biofilm formation.

Liquid dressing compositions liquid for use in the treatment or prevention of infection and/or wounds are described that comprise shellac, an anti-infective metal active and a solvent. The compositions are capable of forming a barrier when topically applied to a subject, providing an easily applied barrier for protecting lesions and other wounds from external infective agents.

Magnesium-infused and menthol-infused kinesiology tape is disclosed. The tape comprises an absorbent fabric substrate with adhesive on one side of the substrate to be applied to a person's skin and includes magnesium salt and menthol for promoting pain relief while the tape adheres to the person's skin.

The present invention relates to: a composition for wound healing, containing a metal-organic framework (MOF)as an active ingredient; and a wound dressing material comprising a hydrophilic superabsorbent polymer and the MOF, and the composition and the wound dressing material have a wound healing ability, specifically, the excellent effect of healing a wound by promoting fibroblast movement, do not significantly differ from a control group with respect to cytotoxicity, thereby exhibiting excellent safety when applied to a wound site, and have the excellent effect of having a wound recovery rate high enough to be checked with the naked eye over time.

The invention relates to antimicrobial and/or antiviral fabric compositions comprising ascorbic acid, citric acid, sodium hypophosphite, or a mixture thereof. The ascorbic acid may be covalently attached to at least one cellulosic portion of the fabric composition. The invention also relates to methods for preparing such fabric compositions.

An intraoral device, comprising an antiviral and/or antibacterial and/or antifungal ion releasing agent material(s) which, when said device is exposed to the oral cavity and to any gases, liquids and solids passing through the oral cavity, and is capable of inactivating viruses and/or bacteria and/or fungi penetrating into the oral cavity.

Embodiments include formulations and methods for topical administration of sugar alcohol to treat a skin condition such as acne. A formulation can include a moisturizer, an emollient, a sugar alcohol and zinc. The sugar alcohol can be erythritol. The erythritol can be administered with zinc chloride. The erythritol and zinc chloride can be formulated at a molar ratio of about 3:1. The methods can also include administration of a therapeutic amount of a second agent such as benzoyl peroxide or a retinoid. Embodiments also include antimicrobial coatings that contain erythritol and zinc to reduce, negate, and prevent the proliferation and propagation of accumulating biofilm. The formulation can be used to clean and/or provide an antimicrobial coating on a medical device such as a catheter.

The present disclosure is directed to a medical device for inhibiting the activity of bacterial collagenase and/or a matrix metalloproteinase (MMP). In some embodiments, the medical device comprises a polymer that includes a transition metal or a salt thereof. In some embodiments, the medical device comprises an alloy that has at least one of a transition metal or a transition metal salt.

A medical device includes a substrate structure with a surface. The surface is laser treated to define at least one protrusion and/or at least one void extending relative to the surface. A coating having antibacterial, antimicrobial and/or drug eluding properties is applied to the substrate structure such that the coating engages within or along a surface portion of one or more of the protrusions and/or voids.

A nano-zinc oxide-supported bacterial cellulose microfiber-alginate fiber composite is described. The composite is obtained by absorbing nano-zinc oxide-supported bacterial cellulose microfibers on an alginate fiber spunlace non-woven fabric; the nano-zinc oxide is uniformly distributed on the surface of the bacterial cellulose microfibers. This composite has good biocompatibility, mechanical properties and water absorption properties, and has a great application prospect in biomedical fields, such as wound dressings, human body repair materials, tissue engineering materials, etc.