A medical device and a method and process for at least partially forming a medical device, which medical device has improved physical properties.

The present invention relates to personal care compositions comprising malodor reduction compositions and methods of making and using such personal care compositions. Such personal care compositions comprising the malodor control technologies disclosed herein provide malodor control without leaving an undesireable scent and when perfume is used to scent such compositions, such scent is not unduely altered by the malodor control technology.

A wound covering is provided that comprises a substrate and vitamin D, or analogues or metabolites thereof, embedded in the substrate. Methods of making a wound covering are also provided and include the steps of providing a solution that includes a polymer; adding vitamin D, or analogues or metabolites thereof, to the solution to form a mixture; and forming one or more fibers from the mixture that are then embedded with the vitamin D, or analogues or metabolites thereof. Methods of treating a subject are further provided and include the step of applying a wound covering including one or more fibers embedded with vitamin D, or analogues or metabolites thereof, to a site on a subject.

Disclosed herein are methods relating to manufacturing an embolizing agent precursor. Manufacture of the embolizing agent precursor may involve mixing a first component contained within a first container with a second component contained within a second container, the first component including a plurality of negatively charged gaseous components and a first stabilizer, the second component comprising a plurality of positively charged oil components, a second stabilizer, and a cationic surfactant. Further steps may include mixing the first component with the second component such that the first and second component are held together as a single agglomerated entity.

A biocompatible adhesive is provided comprising one or more water insoluble compounds of structure (1) wherein B is an oligomer derived from a polyester, polyether, polyalkylene glycol, polysilicone or polycarbonate with a MW<10,000 g/mol, Linker L is a urethane, urea bond, or amide bond; Linker L′ is a urethane or urea bond, A is a chain extender of Mw≤3000 g/mol comprising substituted or unsubstituted alkyl, cycloalkyl and/or aromatic groups, W is a terminal adhesive benzene-1,2-diol derivative or a terminal adhesive benzene-1,2,3-diol derivative, m is 0 or 1; and n is 0, 1, 2, 3 or 4; or a cross-linked polymer formed from said compounds. The compound(s) have a Tg lower than 25° C. The biocompatible adhesive is suitable for use without solvent.

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.

The present disclosure provides a method of bioprinting a 3-D structure comprising one or more biologically-relevant materials on a super-hydrophobic surface. In one embodiment, the method comprises providing a composition having one or more biologically-relevant materials dispersed within a biocompatible medium. A pattern comprising a hydrophilic material is deposited on a defined area of the super-hydrophobic surface, wherein the pattern is modeled after a biological structure. The composition having the one or more biologically-relevant materials is then bioprinted atop the hydrophilic surface to form a 3-D structure, wherein the hydrophilic surface maintains the 3-D structure in a desired position or shape on the super-hydrophobic surface.

Object of the present invention is a drug delivery system comprising a decellularized corneal stroma scaffold having dispersed within and/or bound to its surface microparticles containing at least one pharmaceutically active molecule dispersed in a matrix having a composition consisting for at least 70% of polylactic co-glycolic acid (PLGA).

The present invention is an inflatable balloon which is enclosed by an expandable cover which becomes increasingly porous/permeable during expansion. The balloon is coated or enclosed with a matrix which contains a pharmaceutically active agent. During expansion of the balloon, the pharmaceutically active agent is released or extruded through the expandable cover into a body cavity such as an artery or vein. The present invention also provides for a method of treating a disease or condition by delivering the inflatable balloon to a particular body cavity.

Disclosed herein are compositions and methods for an embolizing agent precursor. The embolizing agent precursor may include a gaseous component and a first stabilizer to stabilize the gaseous component, the first stabilizer may include a a polymer, and wherein a gas portion of the gaseous component is selected from the group consisting of sulphur hexafluoride and C3-6 perfluorocarbons. The embolizing agent precursor may further include an oil component which comprises a C1-7 hydrocarbon, a second stabilizer to stabilize the oil component, and a vaporous component configured to enlarge the gaseous component.