Patent application number | Description | Published |
20100022876 | Systems and Methods for Noncontact Ablation - Systems and methods for noncontact ablation of tissues or materials in/on the body using a luminal catheter and a catheter inserted into the lumen. In one embodiment, the luminal catheter is an ablation catheter and the other catheter is a recording/measurement/positioning catheter. The luminal catheter incorporates a noncontact ablation element such as an ultrasonic transducer. The luminal catheter can be inserted through the skin and into the body (e.g., into the heart) and the recording/measurement/positioning catheter can be inserted into the lumen so that the ablation and recording/measurement/positioning catheters are simultaneously positioned to record/measure the electrical activity of the target tissue and ablate the target tissue without causing the trauma that results from the introduction of additional catheters. Either of the ablation and recording/measurement/positioning catheters can be steerable, and either may incorporate recording/measurement electrodes. | 01-28-2010 |
20120323174 | Systems and Methods for Steering Catheters - Systems and methods for steering catheters to facilitate advancing the catheters through the body, wherein the catheters employ multiple steering stages, each of which can move in multiple planes. The steering stages are independently controlled to enable them to form complex shapes. In one embodiment, the steerable catheter includes an elongated catheter body with the steering stages incorporated into the distal end of the catheter. The steering stages may incorporate multiple memory wires and corresponding heating elements that control the temperatures of the memory wires and consequently control the shapes of the wires and the steering stages in which they are embedded. The catheter may be any type of catheter (e.g., a lumen catheter) and may include features that enable the catheter to perform functions such as delivering therapies (e.g., ablation) to target tissues within the body. | 12-20-2012 |
20130274738 | Systems and Methods for Steering Catheters - Systems and methods for steering catheters to facilitate advancing the catheters through the body, wherein the catheters employ multiple steering stages, each of which can move in multiple planes. The steering stages are independently controlled to enable them to form complex shapes. In one embodiment, the steerable catheter includes an elongated catheter body with the steering stages incorporated into the distal end of the catheter. The steering stages may incorporate multiple memory wires and corresponding heating elements that control the temperatures of the memory wires and consequently control the shapes of the wires and the steering stages in which they are embedded. The catheter may be any type of catheter (e.g., a lumen catheter) and may include features that enable the catheter to perform functions such as delivering therapies (e.g., ablation) to target tissues within the body. | 10-17-2013 |
20140039288 | Systems and Methods for Noncontact Ablation - Systems and methods for noncontact ablation of tissues or materials in/on the body using a luminal catheter and a catheter inserted into the lumen. In one embodiment, the luminal catheter is an ablation catheter and the other catheter is a recording/measurement/positioning catheter. The luminal catheter incorporates a noncontact ablation element such as an ultrasonic transducer. The luminal catheter can be inserted through the skin and into the body (e.g., into the heart) and the recording/measurement/positioning catheter can be inserted into the lumen so that the ablation and recording/measurement/positioning catheters are simultaneously positioned to record/measure the electrical activity of the target tissue and ablate the target tissue without causing the trauma that results from the introduction of additional catheters. Either of the ablation and recording/measurement/positioning catheters can be steerable, and either may incorporate recording/measurement electrodes. | 02-06-2014 |
Patent application number | Description | Published |
20110208031 | NEUTRAL PARTICLE NANOPATTERNING FOR NONPLANAR MULTIMODAL NEURAL PROBES - A neural probe includes a probe, wherein a tip of the probe is tapered; an insulating layer covering the probe, and one or more metallic traces, wherein the metallic traces are provide along the length of the probe. The probe also includes one or more contacts provided on the tip of the probe, wherein each of the one or more metallic traces terminates at the one or more contacts, and the one or more contacts provide an array of nanosized metallic pillars. The neural probe may also incorporate a lightguide. The lightguide may include an insulating layer providing a first cladding layer on the probe, a core layer provided on top of the first cladding layer, wherein the metallic traces and contacts are provided in the core layer with a core material, and a second cladding layer provided on top of the core layer. | 08-25-2011 |
20140029003 | METHOD AND SYSTEM FOR ACTIVE-ILLUMINATION PARALLEL RAMAN MICROSPECTROSCOPY - An active-illumination parallel Raman microspectroscopy scheme for simultaneously collecting Raman spectra from multiple points in a full-spectra range. A combination of multi-point laser illumination with wide-field Raman imaging is employed in order to allow for simultaneous imaging of multiple points not aligned on a single line. | 01-30-2014 |
20140104606 | NANOPOROUS GOLD NANOPARTICLES AS HIGH-PAYLOAD MOLECULAR CARGOS, PHOTOTHERMAL/PHOTODYNAMIC THERAPEUTIC AGENTS, AND ULTRAHIGH SURFACE-TO-VOLUME PLASMONIC SENSORS - A nanoporous gold disk (NPGD) as a novel surface-enhanced Raman spectroscopy (SERS) substrate. NPGD has SERS enhancement factor similar to that of gold nanoshells, but allows, for example, at least three times more benzenethiol molecules to be attached to its surface due to large surface-to-volume ratio. The high capacity enables the rapid detection of attomole-level benzenethiol molecules with relatively high detector temperatures. Additionally, a fabrication process to make NPGD with controlled size and highly reproducible SERS activities. | 04-17-2014 |
20140350375 | INTEGRATED THIN-FILM OPTRODE - An optrode may provide a cylindrical substrate two or more electrodes deposited said cylindrical substrate. The cylindrical substrate and electrodes may be coated by an insulating layer with openings or vias over certain portions of the electrodes that may provide a contact for the neural probe or may be utilized to connect lead lines. Manufacturing of an optrode may utilize a jig that secures a cylindrical substrate coated by a conductive material and a resist. A first mask may be positioned in an opening provided by the jig, and the cylindrical substrate may be exposed ions or neutral particles to define one or more electrode patterns. After regions of the resist and conductive material are removed to form the electrodes, a second mask may be utilized to define vias regions in which portions of the electrodes are exposed and uncoated by an insulating layer. | 11-27-2014 |
Patent application number | Description | Published |
20090128481 | INTEGRATED SYSTEM WITH COMPUTING AND IMAGING CAPABILITES - An integrated system comprising both imaging and computing capabilities comprises a light valve and a CPU, as well as other functional members for performing computing and imaging. | 05-21-2009 |
20090140757 | Microdisplay Assemblies and Methods of Packaging Microdisplays - Microdisplay assemblies, methods of packaging microdisplays, and methods of testing microdisplays are disclosed. In accordance with one embodiment, a microdisplay assembly includes a support and a microdisplay disposed on the support. The microdisplay includes a semiconductor workpiece mounted to the support and an optical device region disposed over the semiconductor workpiece. A plurality of contacts is disposed over a portion of the semiconductor workpiece, wherein each of the plurality of contacts comprises a protruding feature. | 06-04-2009 |
20090267223 | MEMS Package Having Formed Metal Lid - A hermetic MEMS device ( | 10-29-2009 |
20110156179 | Silicon Microphone with Integrated Back Side Cavity - An integrated circuit containing a capacitive microphone with a back side cavity located within the substrate of the integrated circuit. Access holes may be formed through a dielectric support layer at the surface of the substrate to provide access for etchants to the substrate to form the back side cavity. The back side cavity may be etched after a fixed plate and permeable membrane of the capacitive microphone are formed by providing etchants through the permeable membrane and through the access holes to the substrate. | 06-30-2011 |
20110158439 | Silicon Microphone Transducer - A capacitive microphone transducer integrated into an integrated circuit includes a fixed plate and a membrane formed in or above an interconnect region of the integrated circuit. A process of forming an integrated circuit containing a capacitive microphone transducer includes etching access trenches through the fixed plate to a region defined for the back cavity, filling the access trenches with a sacrificial material, and removing a portion of the sacrificial material from a back side of the integrated circuit. | 06-30-2011 |
20120036695 | LOW COST WINDOW PRODUCTION FOR HERMETICALLY SEALED OPTICAL PACKAGES - Disclosed embodiments demonstrate batch processing methods for producing optical windows for microdevices. The windows protect the active elements of the microdevice from contaminants, while allowing light to pass into and out of the hermetically sealed microdevice package. Windows may be batch produced, reducing the cost of production, by fusing multiple metal frames to a single sheet of glass. In order to allow windows to be welded atop packages, disclosed embodiments keep a lip of metal without any glass after the metal frames are fused to the sheet of glass. Several techniques may accomplish this goal, including grinding grooves in the glass to provide a gap that prevents fusion of the glass to the metal frames along the outside edges in order to form a lip. The disclosed batch processing techniques may allow for more efficient window production, taking advantage of the economy of scale. | 02-16-2012 |
20130064400 | SILICON MICROPHONE WITH INTEGRATED BACK SIDE CAVITY - An integrated circuit containing a capacitive microphone with a back side cavity located within the substrate of the integrated circuit. Access holes may be formed through a dielectric support layer at the surface of the substrate to provide access for etchants to the substrate to form the back side cavity. The back side cavity may be etched after a fixed plate and permeable membrane of the capacitive microphone are formed by providing etchants through the permeable membrane and through the access holes to the substrate. | 03-14-2013 |