In various embodiments, the present invention provides a functionalized thermoplastic polyurethane (TPU) containing bulk incorporated or surface-grafted quaternary ammonium compounds (QAC)s for contact-killing of a variety of microbes, where the QACs are on the surface of TPU to provide a sterile surface material that prevents bacteria commonly involved in device-associated infections (DAIs) from proliferating. The functionalized TPUs of the present invention can be formed into a wide variety of 3-dimensional shapes, such as catheters, medical tubing, laryngeal or tracheal stents, sutures, prosthetics, wound dressings, and/or a coating for medical devices and contains the residue of either a QAC containing diol monomer or an alkene functional diol monomer, which then allows the TPU to be functionalized with a QAC containing disulfide or free thiol compound, to form a quaternary ammonium functionalized thermoplastic polyurethane compound having antimicrobial properties for use in medical devices.

A composition for treating a wound includes graphene oxide (GO) and hyaluronic acid (HA) that are covalently linked, XAV939, and water. The composition can also include a surfactant, such as PEG. The composition can be topically administered to a subject to treat a wound of the subject. Methods of treating a wound using the composition are also provided.

Medical devices comprising an anti-connexin agent suitable for introduction into a subject.

Disclosed herein are surgical suture materials that facilitate the sustained delivery of releasable components. The suture materials are processed by the disclosed methods to create a layer of pores extending inward from the outer surface of the suture. Particularly, the surgical suture materials are swollen in a calcium-ion containing solution, then freeze-dried to create pores which can be filled with a releasable component for ultimate delivery to the tissue. In one particular embodiment, the suture has an outer sheath that defines a lumen. Elongated filaments extend through the lumen. This suture embodiment is processed by the disclosed methods to yield a surgical suture material with a porous outer sheath. The pores enable efficient loading of a releasable component into the lumen, facilitating sustained delivery of the releasable component from the suture. The suture maintains its mechanical integrity despite the introduction of pores due to coordination bonds formed between the calcium ions of the swelling solution and carbonyl oxygen atoms of the polymer chains of the surgical suture material.

A packaged antimicrobial suture. The packaged antimicrobial suture includes an inner package having a source of antimicrobial agent, the source of antimicrobial agent comprising a plurality of patches, each patch having a pair of antimicrobial material reservoirs; at least one suture positioned within the inner package, the at least one suture comprising one or more surfaces; and an outer package having an inner surface, the outer package having the inner package positioned within; wherein the at least one suture, the inner package and the inner surface of the outer package are subjected to time, temperature and pressure conditions sufficient to transfer an effective amount of the antimicrobial agent from the antimicrobial agent source to the at least one suture and the inner package, thereby substantially inhibiting bacterial colonization on the at least one suture and the inner package. A method of making a packaged antimicrobial suture having is also provided.

Absorbable composite medical devices such as surgical meshes and braided sutures, which display two or more absorption/biodegradation and breaking strength retention profiles and exhibit unique properties in different clinical settings, are made using combinations of at least two types of yarns having distinctly different physicochemical and biological properties and incorporate in the subject construct special designs to provide a range of unique properties as clinically useful implants.

Compositions are provided that have at least two of three active ingredients. The active ingredients maybe a salt having a cation N.sup.? C8-C16 alkanoyl-L di-basic amino acid C1-C4 alkyl ester, a glycerol monoester of a fatty acid and a sugar ester of a fatty acid. The compositions are useful in methods of killing or inhibiting planktonic bacteria or fungi and bacteria or fungi embedded in a biofilm and prevention of biofilm formation on surfaces. The composition may further comprise a hydrogel and a benefit agent such as an antibiotic that can be solubilized by the hydrogel and supplied to the biofilm matrix by the active ingredients of the composition. Devices such as chronic wound coverings coated with the composition are also provided. Methods of preserving products with the composition are also provided.

The present invention relates to new compositions for sclerotherapy. In particular, the invention relates to the use of light activated biocompatible glues and catheter for the application of said glue. The catheter of the present invention comprises a light source for the glue activation.

The subject invention provides materials methods for reducing infections in subjects. The materials methods utilize chlorhexidine, which has been found to be surprisingly non-toxic. The lack of toxicity facilitates the use of chlorhexidine in contexts that were not previously thought to be possible.

A system for forming twisted or aligned electrospun fibers has been developed. The collector for the electrospun fibers is capable of rotation. In some instances, fibers are formed between two collectors, at least one of which rotates to twist the fibers into a multifilament bundle with increased strength. In a second embodiment, a cylindrical collector rotates, and charged polymer jet uniformly coats the surface of the collector. When a drum collector rotates at a high speed, electrospun fibers align and form an array. Optionally, different active agents can be included in the electrospinning solutions to form fiber constructs with different strengths and controlled release profiles, providing a reproducible method to generate complexed structures based on electrospun fibers and controlled drug delivery profiles.