Various aspects of the present invention provide compositions and implantable devices including a water-insoluble therapeutic agent solubilized in a matrix of a gallate-containing compound. Other aspects provide methods of manufacturing and using such compositions and devices.

A method of modifying the surface of a medical device to release a drug in a controlled way by providing a barrier layer on the surface of one or more drug coatings. The barrier layer consists of modified drug material converted to a barrier layer by irradiation by an accelerated neutral beam derived from an accelerated gas cluster ion beam. Also medical devices formed thereby.

Various aspects of the present invention provide compositions and implantable devices including a water-insoluble therapeutic agent solubilized in a matrix of a gallate-containing compound. Other aspects provide methods of manufacturing and using such compositions and devices.

Adjuncts for surgical devices including agonists and antagonists are provided. In general, an implantable adjunct can have two or more medicants releasably disposed therein that are each releasable from the adjunct. At least one of the medicants can include an agonist configured to encourage a physiological response, and at least one of the medicants can include an antagonist configured to discourage the physiological response encouraged by the agonist. The physiological response can include an aspect of wound healing such that the aspect of wound healing may be both encouraged by and discouraged by the adjunct. The adjunct having one or more agonists and one or more antagonists releasably disposed therein can be configured to be applied to tissue by a surgical stapler in conjunction with staples.

The present invention relates to an implant having a surface comprising a coating on at least a portion of the surface of the implant, wherein the coating comprises at least two coating layers of bioactive compounds adjacent to each other, obtainable in a process comprising the following steps: providing an implant with a surface, providing a first suspension comprising at least one first bioactive compound in a first solvent, wherein the first bioactive compound is non-soluble or partially soluble in the first solvent, applying said first suspension comprising the at least one first bioactive compound onto at least a part of the implant surface forming a first coating layer; drying the first coating layer, providing a second solution comprising at least one second bioactive compound in a second solvent, wherein the second bioactive compound is soluble or readily soluble in the second solvent; applying said second solution comprising the at least one second bioactive compound onto the first coating layer forming a second coating layer, and drying the second coating layer.

Hydrogel-substrate laminate structures and tough biocompatible hydrogel coatings for various equipment such as medical devices and underwater equipment, in which robust interfaces are formed between the hydrogel coatings and the substrate/equipment surface(s). The hydrogel coatings provide a highly-hydrated, ultra-low friction structure that does not rupture or delaminate under stress. The hydrogel coatings may further incorporate a variety of therapeutic agents and/or sensing mechanisms to provide for environmental sensing and therapeutic agent release.

The present invention concerns a polyelectrolyte coating comprising at least one polycationic layer consisting of at least one polycation consisting of n repetitive units having the formula (1) and at least one polyanionic layer consisting of hyaluronic acid. The polyelectrolyte coating has a biocidal activity and the invention thus further refers to the use of said polyelectrolyte coating for producing a device, in particular a bacteriostatic medical device, more particularly an implantable device, comprising said polyelectrolyte coating, and a method for preparing said device and a kit.

A method for depositing a coating comprising a polymer and at least two pharmaceutical agents on a substrate, comprising the following steps: providing a stent framework; depositing on said stent framework a first layer comprising a first pharmaceutical agent; depositing a second layer comprising a second pharmaceutical agent; Wherein said first and second pharmaceutical agents are selected from two different classes of pharmaceutical agents.

Various aspects of the present invention provide compositions and implantable devices including a water-insoluble therapeutic agent solubilized in a matrix of a gallate-containing compound. Other aspects provide methods of manufacturing and using such compositions and devices.

A catheter includes a tubular body having an outer surface, and a sleeve disposed on only a portion of the outer surface of the tubular body. The sleeve includes an outer layer overlying an inner layer. The catheter contains a water-soluble, anti-microbial agent in the outer layer of the sleeve. Methods of making the catheter are also disclosed.