An apparatus for in vitro testing of medical device thrombogenicity includes an enclosure; a heating element thermally coupled to the enclosure; and a temperature feedback circuit operably coupled to the heating element and configured to control the heating element to maintain an interior of the enclosure within a preset temperature range. Positive, negative, and intermediate control rods are provided as standards against which to compare a medical device test article. Multiple blood test loops can be established through the enclosure using a common blood supply. The medical device test article can be placed in one of the loops, while the remaining loops can contain controls. Blood can be circulated through the test loops at a flow rate similar to that encountered in vivo, and thrombus formation can be assessed thereafter.

A system for preventing thrombosis in an implantable medical device includes an implantable medical device sized for implantation at least partially within a patient's body. The device includes an at least partially electrically conductive portion that is disposed within a patient's body upon implantation, an electrode coupled to the electrically conductive portion of the device; and a power source coupled to the electrode. The power source provides a negative electric charge to the at least partially electrically conductive portion for an indefinite period of time. The device may be configured to resist thrombosis, infection, and/or undesired tissue growth via the charged conductive portion once implanted. Exemplary embodiments of the implantable medical device include a hemodialysis vasculature graft, a dialysis catheter, a coronary artery, and a heart valve.

Medical devices as wells as methods for making and using medical devices are disclosed. An example medical device may include a left atrial appendage device. The left atrial appendage device may include an expandable frame configured to shift between a first configuration and an expanded configuration. A fabric mesh may be disposed along at least a portion of the expandable frame. An anti-thrombogenic coating may be disposed along the fabric mesh.

Medical devices as wells as methods for making and using medical devices are disclosed. An example medical device may include a left atrial appendage device. The left atrial appendage device may include an expandable frame configured to shift between a first configuration and an expanded configuration. A fabric mesh may be disposed along at least a portion of the expandable frame. An anti-thrombogenic coating may be disposed along the fabric mesh.

Various embodiments of the present invention include a cannula coated or compounded with a material to extend the wear time for a patient by reducing inflammation and therefore increasing the time that the cannula may remain inserted, thereby increasing the effectiveness of the drug delivered using the cannula. The material may include a hydrophilic material, an anti-microbial material, an anti-inflammatory material, anti-thrombogenic material, or a combination of any of these materials.

Medical articles formed from a polyurethane-based resin including an ionically-charged modifier provide enhanced properties. The polyurethane-based resin is a reaction product of ingredients comprising: a diisocyanate; a diol chain extender; a polyglycol; and an ionically-charged modifier incorporated into a backbone, as a side chain, or both of the polyurethane-based resin. Embodiments include the ionically-charged modifier is a combination of anionic and cationic modifiers. Embodiments include the ionically-charged modifier is zwitterionic. Medical articles herein either have inherent antimicrobial and/or anti-fouling characteristics or can easily bond ionic active agents to provide desirable material properties, including antimicrobial, anti-fouling, and/or radiopacity.

Embodiments herein relate to thromboresistant coatings, coated devices, and related methods. In an embodiment, a thromboresistant implantable, partially implantable, or wearable medical device is included having a substrate, a non-fouling basecoat layer, and a lubricious topcoat layer. The non-fouling basecoat layer can include a hydrophilic component and a hydrophobic component. The non-fouling basecoat layer is disposed over the substrate. The lubricious topcoat layer can include a photo-reactive polyvinylpyrrolidone compound and a cross-linking agent. The lubricious topcoat layer can be disposed over the non-fouling basecoat layer. Other embodiments are also included herein.

The present invention relates to stents made of a magnesium alloy degradable under physiological conditions having an inorganic coating comprising magnesium fluoride and having an organic coating. The stents according the invention can additionally be coated with at least one antiinflammatory, antiproliferative, antiangiogenic, antirestenotic, and/or antithrombogenic active agent.

A therapeutic agent which inhibits cytokines and/or inflammatory mediators for use in the treatment of a patient affected by inflammation associated with atherosclerosis and/or a thrombotic state, wherein the treatment includes the local administration of the therapeutic agent in a blood vessel by an intravascular medical device directly at the level of an atherosclerotic plaque, and/or a site of inflammation, and/or a site of a thrombotic phenomenon.

A system for preventing thrombosis in an implantable medical device includes an implantable medical device sized for implantation at least partially within a patient's body. The device includes an at least partially electrically conductive portion that is disposed within a patient's body upon implantation, an electrode coupled to the electrically conductive portion of the device; and a power source coupled to the electrode. The power source provides a negative electric charge to the at least partially electrically conductive portion for an indefinite period of time. The device may be configured to resist thrombosis, infection, and/or undesired tissue growth via the charged conductive portion once implanted. Exemplary embodiments of the implantable medical device include a hemodialysis vasculature graft, a dialysis catheter, a coronary artery, and a heart valve.