Patent application number | Description | Published |
20100132718 | Occlusion Stent - A device for occluding a target body lumen, comprises a wire structure defining a wire structure lumen extending therethrough and movable between a reduced diameter insertion configuration and an expanded diameter deployed configuration and a basket structure extending across the wire structure lumen and including therein a cell growth promoting agent to promote cell growth across the wire structure lumen to occlude the target body lumen. | 06-03-2010 |
20120018090 | HIGH PRESSURE BALLOON - Composite fiber reinforced balloons for medical devices are prepared by applying a web of fibers to the exterior of a preformed underlayer balloon, encasing the web with a matrix material to form an assembly, and inserting the assembly into a preformed outer layer balloon to form the composite balloon. | 01-26-2012 |
20130123696 | HIGH PRESSURE BALLOON - Composite fiber reinforced balloons for medical devices are prepared by applying a web of fibers to the exterior of a preformed underlayer balloon, encasing the web with a matrix material to form an assembly, and inserting the assembly into a preformed outer layer balloon to form the composite balloon. | 05-16-2013 |
20140074142 | CATHETER WITH RELEASABLE BALLOON AND RELATED METHODS - Various embodiments of a balloon catheter and related methods are disclosed. In particular, one exemplary embodiment of a balloon catheter may include a balloon having an inlet opening for receiving inflation fluid and a one-way valve disposed in the inlet opening to allow inflow of the inflation fluid into the balloon while substantially preventing backflow of the inflation fluid from the balloon. The catheter may also include an elongated shaft comprising a proximal end, a distal end, and a lumen extending between the proximal and distal ends. The shaft may be configured to supply the inflation fluid to the balloon through the lumen and to releasably couple the balloon to the distal end of the shaft. | 03-13-2014 |
20150105815 | HIGH PRESSURE TEAR RESISTANT BALLOON - An expandable medical balloon comprising an inner layer formed of a polymer material having a first flexural modulus, an intermediate layer formed of a material having a second flexural and an outer layer formed of a material having a third flexural modulus, wherein the flexural modulus of the inner layer and outer layer is 50,000 psi to about 80,000 psi, the flexural modulus of the intermediate layer is about 130,000 to about 230,000 psi and the calculated burst strength of the balloon determined on a 90 degree bend in the balloon is about 35,000 psi or higher. | 04-16-2015 |
Patent application number | Description | Published |
20110002168 | Binary Logic Utilizing MEMS Devices - Embodiments disclosed herein generally relate to switches that utilize micro-electromechanical systems (MEMS). By replacing transistors in many devices with switches such as MEMS switches, the devices may be used for logic applications. MEMS switches may be used in devices such as FPGAs, NAND devices, nvSRAM devices, AMS chips and general memory logic devices. The benefit of utilizing MEMS devices in place of transistors is that the transistors utilize more space on the chip. Additionally, the MEMS devices can be formed in the BEOL without having any negative impacts on the FEOL or necessitating the use of additional layers within the chip. | 01-06-2011 |
20130335878 | MEMS LIFETIME ENHANCEMENT - The present invention generally relates to methods for increasing the lifetime of MEMS devices by reducing the number of movements of a switching element in the MEMS device. Rather than returning to a ground state between cycles, the switching element can remain in the same state if both cycles necessitate the same capacitance. For example, if in both a first and second cycle, the switching element of the MEMS device is in a state of high capacitance the switching element can remain in place between the first and second cycle rather than move to the ground state. Even if the polarity of the capacitance is different in successive cycles, the switching element can remain in place and the polarity can be switched. Because the switching element remains in place between cycles, the switching element, while having the same finite number of movements, should have a longer lifetime. | 12-19-2013 |
Patent application number | Description | Published |
20100299984 | SIGNAGE INCLUDING INTERLOCKING MECHANICAL FASTENERS - The present application relates to a sign including: (1) a sign blank including multiple first interlockable members; and (2) optically active sheeting including multiple second interlockable members; wherein the first and second matable members interlock with one another to hold the sign blank and the sheeting together. | 12-02-2010 |
20140259830 | MULTI-PANEL SIGN SYSTEMS AND METHODS - A multi-panel sign system including first and second panels, and an adhesive-based fastener. The panels include a panel body and complimentary, first and second interlock structures. The panel body defines a front face for maintaining indicia, and first and second sides. The first and second interlock structures are located adjacent the first and second sides, respectively, and project opposite the front face. In an assembled stated, the first interlock structure of the first panel mechanically locks with the second interlock structure of the second panel to establish a interlocked joint, and the adhesive-based fastener is bonded to the first and second panels. The interlocked joint robustly maintains the panels relative to one another, whereas the adhesive-based fastener serves to prevent inadvertent sliding of the panels. Optically active sheeting can be applied to the front face of the panels, and desired indicia applied to the sheeting. | 09-18-2014 |
20150348454 | SIGNAGE OVERLAY ARTICLE - A signage overlay article includes a polymeric substrate having a thickness in a range from 75 to 1000 micrometers, an optically active sign sheeting fixed to the polymeric substrate, and a pressure sensitive adhesive layer adhered to the polymeric substrate. The pressure sensitive adhesive layer has a thickness in a range from 350 to 3000 micrometers. | 12-03-2015 |