A liquid formulation of an ophthalmic drug in a pharmaceutical package, for example a syringe, cartridge, or vial, made in part or in whole of a thermoplastic polymer, coated on the interior with a tie coating or layer, a barrier coating or layer, a pH protective coating or layer, and optionally a lubricity coating or layer.

A liquid formulation of an ophthalmic drug in a pharmaceutical package, for example a syringe, cartridge, or vial, made in part or in whole of a thermoplastic polymer, coated on the interior with a tie coating or layer, a barrier coating or layer, a pH protective coating or layer, and optionally a lubricity coating or layer.

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.

An absorbable implantable medical device made of iron-based alloy, including a base made of iron-based alloy and a complex, wherein the complex includes a complexing agent. In a physiological solution, the base made of iron-based alloy can react with the complexing agent to generate a water-soluble iron complex having solubility in the physiological solution of no less than 10 mg/L. A corrosion product generated after the absorbable implantable medical device made of iron-based alloy is implanted in a human body can be quickly metabolized/absorbed by the body.

A processing technique for creating nanowires and hierarchically porous micro/nano structures of ceramic materials is provided. The process includes evaporation of micron-sized water droplets containing dissolved organic salts on heated substrates followed by thermal decomposition of the deposited material. The micron-sized droplets may be generated by supercritical CO.sub.2 assisted nebulization, in which high-pressure streams of aqueous solution and supercritical CO.sub.2 are mixed, followed by controlled depressurization through a fine capillary. Rapid evaporation takes place on the heated substrates and structures are generated due to CO.sub.2 effervescence from the droplets and evaporation of water, along with the pinning of the three phase contact line. Depending on the mass deposited, a mesh of nano-wires or membrane-like structures may result. Sintering of the membrane-like scaffolds above the decomposition temperature of the organic salt creates nanopores within the structures, creating a dual hierarchy of pores.

Disclosed herein are novel peptides that can comprise antimicrobial, antiviral, antifungal or antitumor activity when administered to a subject.

Disclosed herein are novel peptides that can comprise antimicrobial, antiviral, antifungal or antitumor activity when administered to a subject.

An RF charging system for implantable medical devices. The RF charging system includes a radio frequency (RF) signal, a first antenna configured to transmit the RF signal, a second antenna configured to receive the RF signal transmitted by the first antenna, tune characteristics of the RF signal, and improve power transfer with impedance matching circuitry, an RF to direct current (DC) converter configured to convert the RF signal of the second antenna into a DC signal, and a battery management circuit configured to receive the DC signal and provide voltage to a battery.

An implantable medical device may comprise an elongated tubular body having a scaffolding forming a plurality of cells. A polymeric covering may be disposed over at least a portion of the stent. The covering may include a plurality of voids formed in an outer surface thereof. An extracellular matrix material coating may be disposed over the polymeric covering and within the plurality of voids.

An implantable medical device may comprise an elongated tubular body having a scaffolding forming a plurality of cells. A polymeric covering may be disposed over at least a portion of the stent. The covering may include a plurality of voids formed in an outer surface thereof. An extracellular matrix material coating may be disposed over the polymeric covering and within the plurality of voids.