Patent application number | Description | Published |
20080206305 | Implantable barrier device - A barrier device is formed of a barrier component that can exhibit anti-inflammatory properties, non-inflammatory properties, and/or adhesion-limiting properties, as well as generate a modulated healing effect on injured tissue. The barrier component can be a non-polymeric cross-linked gel derived at least in part from a fatty acid compound, and may include a therapeutic agent. The barrier device can have anchoring locations to provide an area on the barrier device to interface with an anchoring mechanism. The anchoring locations can include openings and/or anchor elements. The barrier device can also include truss structures that provide additional strength to the barrier component. The barrier device is implantable in a patient for short term or long term applications, and can include controlled release of the therapeutic agent. | 08-28-2008 |
20100183697 | TISSUE-SEPARATING FATTY ACID ADHESION BARRIER - Exemplary embodiments of the present invention provide adhesion barriers having anti-adhesion and tissue fixating properties. The adhesion barriers are formed of fatty acid based films. The fatty acid-based films may be formed from fatty acid-derived biomaterials. The films may be coated with, or may include, tissue fixating materials to create the adhesion barrier. The adhesion barriers are well tolerated by the body, have anti-inflammation properties, fixate, well to tissue, and have a residence time sufficient to prevent post-surgical adhesions. | 07-22-2010 |
20100233232 | FATTY-ACID BASED PARTICLES - The present invention is directed toward fatty acid-based particles, and methods of making such particles. The particles can be associated with an additional, therapeutic agent. Also provided herein is a method of forming fatty acid particles, comprising associating a cross-linked, fatty acid-derived biomaterial with a cryogenic liquid; and fragmenting the bio material/cryogenic liquid composition, such that fatty acid particles are formed. The particles can be used for a variety of therapeutic applications. | 09-16-2010 |
20110213302 | METHOD OF COATING A FOLDED MEDICAL DEVICE - A non-polymeric or biological coating applied to a radially expandable interventional medical device in a collapsed, wrapped, or folded configuration, the coating applied within at least one fold. Properties of the coating material applied to the medical device are adjusted or varied to result in a desired combination of coverage of the surface of the medical device, drug loading, and coating thickness. The coating is sterile, and is capable of being carried by a sterile medical device to a targeted tissue location within the body following radial expansion. The therapeutic coating transfers off the medical device due in part to a biological attraction with the tissue and in part to a physical transference from the medical device to the targeted tissue location in contact with the medical device. | 09-01-2011 |
20110274823 | APPLICATION OF A COATING ON A MEDICAL DEVICE - Methods and devices for the provision of a coating on an implantable medical device. The coating includes a bio-absorbable carrier component. In addition to the bio-absorbable carrier component, a therapeutic agent component can also be provided. The methods and devices provide a coating having improved uniformity and coverage which in turn allow for greater control of the amount and dosage of the coating. | 11-10-2011 |
20120213839 | HYDROPHOBIC CROSS-LINKED GELS FOR BIOABSORBABLE DRUG CARRIER COATINGS - Coatings for medical devices, methods of making the coatings, and methods of using them are described. | 08-23-2012 |
20120315219 | Drug Delivery Coating For Use With A Stent - A coated medical device and a method of providing a coating on an implantable medical device result in a medical device having a bio-absorbable coating. The coating includes a bio-absorbable carrier component. In addition to the bio-absorbable carrier component, a therapeutic agent component can also be provided. The coated medical device is implantable in a patient to effect controlled delivery of the coating, including the therapeutic agent, to the patient. | 12-13-2012 |
20130035637 | COATED FOLDED MEDICAL DEVICE - A non-polymeric or biological coating applied to a radially expandable interventional medical device in a collapsed, wrapped, or folded configuration, the coating applied within at least one fold. Properties of the coating material applied to the medical device are adjusted or varied to result in a desired combination of coverage of the surface of the medical device, drug loading, and coating thickness. The coating is sterile, and is capable of being carried by a sterile medical device to a targeted tissue location within the body following radial expansion. The therapeutic coating transfers off the medical device due in part to a biological attraction with the tissue and in part to a physical transference from the medical device to the targeted tissue location in contact with the medical device. | 02-07-2013 |
20130074452 | PERFORATED BIOABSORBABLE OIL FILM AND METHODS FOR MAKING THE SAME - A bio-absorbable stand-alone film is derived at least in part from fatty acids. The bio-absorbable stand-alone film can have anti-adhesive, anti-inflammatory, non-inflammatory, and wound healing properties, and can additionally include one or more therapeutic agents incorporated therein. The stand-alone film has one or more perforations or depressions formed therein. Corresponding methods of making the bio-absorbable stand-alone film with one or more perforations or depressions include molding, cutting, carving, puncturing or otherwise suitable methods to create the perforations or depressions in the bio-absorbable stand-alone film. The resulting stand-alone film is bioabsorbable. | 03-28-2013 |
20150079191 | CURED GEL AND METHOD OF MAKING - A cured non-polymeric gel including a plurality of non-polymeric cross-links. The non-polymeric cross-links result from curing an oil or oil composition at selected curing conditions to achieve a desired amount of cross-linking to form the non-polymeric get. The desired amount of cross-linking is selected based on a desired rate of degradation of the gel after the gel is implanted. The oil or oil composition comprises one or more of eicosapentaenoic acid (EPA), docosahexaenoic acid (DHA), or alphalinolenic acid (ALA). | 03-19-2015 |