A method of corneal implantation with cross-linking is disclosed herein. In one or more embodiments, the method includes the steps of: (i) prior to implantation, treating an implant formed from donor corneal tissue or a tissue culture grown corneal stroma with a solution of sodium dodecyl sulfate (SDS), Triton X-100, benzalkonium chloride (BAK), Igepal, genipin, 100% glycerol, or alcohol for making the implant acellular, and for killing any bacteria, viruses, or parasites prior to implantation; (ii) implanting the implant into a recipient cornea; (iii) applying laser energy to the implant so as to modify the refractive power of the implant while being monitored using a Shack-Hartmann wavefront system so as to achieve a desired refractive power for the implant; and (iv) applying a cross-linking solution and irradiating the implant to cross-link the implant to prevent an immune response to the implant and/or rejection of the implant by a patient.

Provided herein are compounds that can exhibit activity as biofilm modulating agents (e.g., activity as biofilm inhibitors and/or activity as biofilm dispersal agents). The compounds can exhibit potent activity against Gram positive biofilms. The compounds can also exhibit activity against Gram negative biofilms. In some cases, the compounds can exhibit both biofilm modulation properties and antimicrobial activity. Compositions comprising these compounds, as well as methods of using thereof, are also described. For example, the compounds described herein can be used in human and animal health (e.g., for the treatment of infection), agriculture, marine coatings, and other coating applications related to prevention of biofilm (e.g., dental, medical, etc.).

The present invention relates to inhibiting or preventing infection and protecting against patency complications after a blood catheter has been inserted in a patient comprising administering to the device a pharmaceutically effective amount of a composition comprising: (A) at least one taurinamide derivative, (B) at least one compound selected from the group consisting of biologically acceptable acids and biologically acceptable salts thereof; and (C) heparin at a low concentration.

The disclosure provides hyaluronic acid (HA) gel formulations and methods for treating the appearance of the skin. The formulations contain hyaluronic acid and at least one additional ingredient. Methods for treating lines, wrinkles, fibroblast depletions, and scars with the disclosed composition are provided as well.

Described are polymers and methods of forming and using same.

Compositions and methods for the surface appearance of the skin a subject are provided. An injectable composition comprising at least hyaluronic acid or a salt thereof; and an effective amount of at least mepivacaine or a salt thereof are provided. The hyaluronic acid optionally has an average molecular weight ranging from 50,000 to 10,000,000 Daltons, and may be crosslinked hyaluronic acids, non-crosslinked hyaluronic acids, or a combination, in some embodiments. The compositions and methods of the present invention are useful for treating and preventing the cutaneous signs of chronological aging and/or induced by external factors such as stress, air pollution, tobacco or prolonged exposure to ultraviolet (UV) exposure, impaired surface appearance of the skin, impaired viscoelastic or biomechanical properties of the skin, and/or the long-lasting filling of volume defects of the skin.

The present invention provides compositions for extended release of an active ingredient, comprising a lipid-saturated matrix formed from a biodegradable polymer. The present invention also provides methods of producing the matrix compositions and methods for using the matrix compositions to provide controlled release of an active ingredient in the body of a subject in need thereof.

This invention relates to a bone regeneration product comprising at least one stem cell, at least one scaffold, and at least one stem cell. The stem cells suitable for this invention may comprise stem cells suitable for a dense bone regeneration, stem cells suitable for a spongy bone regeneration, or a combination thereof. The bone regeneration product may further comprise a growth factor. This invention also relates to a bone regeneration method and treatment of any bone that has a critical size defect. This invention also relates to a scaffold. This invention further relates to a 3D printed scaffold comprising hydroxyapatite (HA) and tricalcium phosphate (TCP). This invention also relates to a scaffold comprising a polymer. The polymer of this invention may be prepared by using photocurable polymers and/or monomers. The scaffold of this invention may comprise a growth factor and a small molecule. The small molecule N may be a Smurf1 inhibitor.

Polymeric coatings, their applications, and the methods of their preparation are described. The coatings may be used to confer desirable properties to the consumer and/or medical products. Also described are methods of loading therapeutic agents on the polymeric coatings and the applications of the drug eluting polymeric coatings thus obtained.

Methods for inhibiting stenosis, obstruction and/or calcification of a heart valve following implantation in a vessel having a wall are disclosed. In one aspect the method includes providing a bioprosthetic heart valve mounted on an elastical stent; treating the bioprosthetic heart valve with a tissue fixative; coating the stent and the bioprosthetic valve with a coating composition including one or more therapeutic agents; implanting the bioprosthetic valve into the vessel in a diseased natural valve site; eluting the coating composition from the bioprosthetic valve; and inhibiting stenosis, obstruction and/or calcification of the bioprosthetic heart valve by preventing the attachment of stem cells to the bioprosthetic heart valve, the stem cells circulating external and proximate to the bioprosthetic heart valve by activating nitric oxide production (i) in the circulating stem cells, (ii) in an endothelial cell lining covering the bioprosthetic heart valve tissue, (iii) or both.