Patent application number | Description | Published |
20080215131 | METHOD FOR LOADING A MEDICAL DEVICE INTO A DELIVERY SYSTEM - A process to load a medical device comprising a shape memory material into a delivery system is described herein. According to one aspect, the method includes applying a force to the medical device to obtain a delivery configuration thereof, where the device is at a first temperature within an R-phase temperature range of the shape memory material during application of the force. The medical device is cooled in the delivery configuration to a second temperature at or below a martensite finish temperature of the shape memory material. The force is then removed from the medical device, and the device is loaded into a delivery system. Preferably, the medical device substantially maintains the delivery configuration during the loading process. | 09-04-2008 |
20090054872 | Endovascular Device Tip Assembly - An endovascular device tip assembly and method of making the same, incorporating a tip device with a first and second flange, usable with catheters and other suitable endovascular devices is provided. The tip assembly incorporates a tip device by providing a counterbore within a primary bore of a tubular end portion of an endovascular device. The tip device is fitted securely within the counterbore by placing the first flange within the counterbore and the second flange on the outside of the end portion. | 02-26-2009 |
20090139614 | METHOD OF CHARACTERIZING PHASE TRANSFORMATIONS IN SHAPE MEMORY MATERIALS - A method of characterizing phase transformations of a shape memory material specimen entails recording data from the specimen during heating and cooling. The temperature of the specimen is changed in a first direction to a first temperature sufficient to define a first inflection and a second inflection in the data being recorded. The temperature of the specimen is changed in a second direction to a second temperature sufficient to define a third inflection in the data. The third inflection is formed by overlapping primary and secondary sub-inflections. The temperature of the specimen is changed in the first direction to a third temperature sufficient to define the first inflection but not sufficient to define the second inflection. The temperature of the specimen is then changed in the second direction to a fourth temperature sufficient to define the secondary sub-inflection in the data being recorded. | 06-04-2009 |
20090171426 | RADIALLY EXPANDABLE STENT - An expandable stent radially adjustable between a collapsed state and an expanded state. The stent generally includes a main body and a plurality of connector segments. The main body has first and second ends, a longitudinal axis extending from the first end to the second end, and a plurality of ring structures. Each of the plurality of connector segments joins adjacent ring structures. Some ring structures may be connected by a pair of diamond connector segments that define a diamond-shaped portion when the stent is in the expanded state. Some ring structures may be connected by flex connector segments oriented to permit rotation of the second ring structure about the longitudinal axis during radial expansion of the stent. | 07-02-2009 |
20090171427 | SEQUENTIAL IMPLANT DELIVERY SYSTEM - A method and device includes advancing a first stent and a second stent into a stenosed region of a blood vessel to protect or shield the vessel from possible blockage. The delivery device may include placement rings, selectively engagable by positioning members disposed on the outer wall of in inner catheter. The positioning members and the placement rings may be utilized to accurately place multiple stents within an afflicted vessel, in a single invasive procedure. | 07-02-2009 |
20100031491 | Method of Incorporating a Tip into an Endovascular Device - An endovascular device tip assembly and method of making the same, incorporating a tip device with a first and second flange, usable with catheters and other suitable endovascular devices is provided. The tip assembly incorporates a tip device by providing a counterbore within a primary bore of a tubular end portion of an endovascular device. The tip device is fitted securely within the counterbore by placing the first flange within the counterbore and the second flange on the outside of the end portion. | 02-11-2010 |
20100137966 | SYSTEM AND METHOD FOR SEQUENTIALLY DEPLOYING TWO OR MORE IMPLANTABLE MEDICAL DEVICES - An intraluminal delivery system for sequentially deploying two or more implantable medical devices includes two or more such devices arranged longitudinally adjacent to each other about an inner catheter. One or more separator bands are slideably disposed about the inner catheter, and each of the bands is positioned between adjacent medical devices. An outer catheter, which is proximal to the medical devices, overlies the inner catheter but does not overlie the medical devices. A tubular sheath overlies the outer catheter, the one or more separator bands, and the medical devices. Relative motion between the tubular sheath and the inner catheter allows the medical devices to be sequentially deployed at one or more treatment sites, and relative motion between the inner catheter and the outer catheter allows a distal tip of the inner catheter to be retracted after deployment of each device. | 06-03-2010 |
20100168837 | BLOOD PERFUSION DEVICE - Medical devices, as well as methods of treatment and manufacturing such devices, are provided for applying vascular therapy locally within the body vessel. The medical devices include an expandable tubular frame and a sleeve or graft material. The medical devices can be used for local delivery of a therapeutic agent within a body vessel or a tamponade for a lacerated body vessel, while simultaneously allowing perfusion of fluid or blood flow distal of the implanted medical device. The tubular frame of the medical device may have a proximal non-expanding portion and a distal self-expanding support structure. The self-expanding support structure can expand radially outward to urge the graft material to contact the wall of the body vessel. In the expanded configuration, a portion of the device allows fluid flow to continue while the sleeve is against the body vessel wall. | 07-01-2010 |
20110137398 | METHOD OF LOADING A MEDICAL DEVICE INTO A DELIVERY SYSTEM - A method of loading a medical device into a delivery system includes providing a two-stage shape memory alloy at a temperature at which at least a portion of the alloy includes austenite. A stress which is sufficient to form R-phase from at least a portion of the austenite is applied to the medical device at the temperature. A delivery configuration of the medical device is obtained, and the medical device is loaded into a restraining member. Preferably, the delivery configuration of the medical device includes stress-induced R-phase. | 06-09-2011 |
20120060348 | TWO-STAGE METHOD OF COMPRESSING A STENT - A two-stage method of compressing a stent entails providing an expandable stent ( | 03-15-2012 |
20120277689 | QUATERNARY NICKEL-TITANIUM ALLOY - A quaternary nickel-titanium alloy includes: Ni at a concentration of between about 48 at. % and about 52 at. %; Cr at a concentration of from about 0.3 at. % to about 1 at. %; Co at a concentration of from about 0.5 at. % to about 2 at. %; and Ti at a concentration wherein a ratio of Ni:Ti is about 1.03. According to one exemplary embodiment of the alloy, the concentration of Cr may be about 0.5 at. % and the concentration of Co may be about 0.75 at. %. According to another exemplary embodiment of the alloy, the concentration of Cr may be about 0.25 at. % and the concentration of Co may be about 0.5 at. %. | 11-01-2012 |
20130018220 | METHOD FOR ELECTROSPINNING A GRAFT LAYER - A method for making a graft layer is provided. The graft layer has at least two layers with different porosities. The two layers are applied by electrospinning. The parameters of the electrospinning may be varied when applying the first and second layers in order to achieve different porosities of the first and second layers. | 01-17-2013 |