Patent application number | Description | Published |
20090043228 | LASER SHOCK PEENING OF MEDICAL DEVICES - A laser shock peening process for producing one or more compressive residual stress regions in a medical device is disclosed. A high-energy laser apparatus can be utilized to direct an intense laser beam through a confining medium and onto the target surface of a workpiece. An absorption overlay disposed on the target surface of the workpiece absorbs the laser beam, inducing a pressure shock wave that forms a compressive residual stress region deep within the workpiece. Medical devices such as stents, guidewires, catheters, and the like having one or more of these compressive residual stress regions are also disclosed. | 02-12-2009 |
20090043283 | MICROFABRICATED CATHETER WITH IMPROVED BONDING STRUCTURE - Medical devices and methods for making and using the same. An example medical device may include a tubular member and a liner disposed within the liner. The tubular member may have a plurality of slots formed therein. A space may be defined between the tubular member and the liner. One or more bonding members may be disposed in the space. | 02-12-2009 |
20100198128 | FLEXIBLE STRUCTURAL APPARATUS, SPRING, WOUND COVERING, AND METHODS - A flexible structural apparatus which may be used as a wound covering which extends above the wound such that the wound covering does not contact the wound and also protects the wound from contact. The apparatus provides a high degree of flexibility while retaining structural strength and resisting collapse, for example, so as to adequately protect the wound. Various embodiments include parallel beams and connections between beams that alternate in location along the beams to provide flexibility. Some embodiments may be used as springs and may have attachment features, such as holes, which may be located at the end beams, for example. | 08-05-2010 |
20100204774 | STENT DELIVERY CATHETER - Stent delivery catheters adapted to provide both flexibility and strength are disclosed. Such stent delivery catheters may have outer shafts adapted for tensile strength and inner shafts adapted for compressive strength. In some instances, at least one of the outer shaft and/or the inner shaft may include a micromachined portion. | 08-12-2010 |
20130072904 | MICROMACHINED MEDICAL DEVICES - Medical devices that include micromachined hypotubes or that have themselves been micromachined can provide advantages in flexibility, strength and other desirable properties. Examples of such medical devices may include catheters such as guide catheters and balloon catheters. Such devices may also include dual shaft medical devices in which an outer shaft is reversibly lockable onto an inner shaft. | 03-21-2013 |
20130072924 | ABLATION ANTENNA - A radio frequency ablation antenna is disclosed. The micro-strip ablation antenna has a dielectric member having a substantially tubular shape. A first conductor is disposed within the dielectric member, and a second conductor is disposed on an outer surface of the dielectric member. The first conductor is configured to be electrically connected to a radio frequency source or ground, and the second conductor is configured to be electrically connected to the other of the radio frequency source or the ground. | 03-21-2013 |
20150366612 | ABLATION EMITTER ASSEMBLY - An emitter assembly can include a proximal shaft, a distal shaft, a shunt that connects the proximal shaft to the distal shaft, and a tip that is connected to a distal end of the distal shaft. An inner conductor can extend through the proximal shaft, the shunt, and the distal shaft and into the tip to provide microwave energy to the tip. An outer conductor can extend into the shunt. The shunt can therefore form an electrical connection between the outer conductor and a proximal ring of electrically conductive material formed on an exterior surface of the distal shaft. Distal shaft can be made of a thermally conductive but electrically insulated material to facilitate transfer of heat from the distal shaft to the proximal shaft. | 12-24-2015 |
20150366613 | ABLATION PROBE WITH METALIZED CERAMIC COMPONENT - Ablation probes can include one or more metalized ceramic components. A metalized ceramic component can include one or more traces for conducting electrical energy and/or for functioning as an antenna for emitting radiation during an ablation procedure. A shaft of an ablation probe may be formed of metalized ceramic to give the shaft strength and to provide an electrical insulator between traces formed on the shaft and other components of the probe. A tip of an ablation probe may also be formed of metalized ceramic. | 12-24-2015 |