| Patent application number | Description | Published |
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| 20100241015 | OPTICAL SYSTEMS FOR DIAGNOSING AND MONITORING DERMAL MICROVASCULAR HEALTH - The invention generally relates to a device for assessing dynamic microvascular refill (DMR), a novel measure of microvascular function. Microvascular refill is determined under dynamic conditions by monitoring changes in fingernail reflectance spectra in response to small shear forces applied to the fingernail. A hemodynamic model is described to examine the physiological significance of observed signals. The invention will provide healthcare workers with a simple, user friendly, non-invasive method of rapidly assessing microvascular function that would greatly facilitates the early detection and monitoring of the onset and treatment of vascular diseases. | 09-23-2010 |
| 20110037832 | Defocusing Feature Matching System to Measure Camera Pose with Interchangeable Lens Cameras - A lens and aperture device for determining 3D information. An SLR camera has a lens and aperture that allows the SLR camera to determine defocused information. | 02-17-2011 |
| 20110074932 | Accurate 3D Object Reconstruction Using a Handheld Device with a Projected Light Pattern - A lens and aperture device for determining 3D information. A projector projects an optical pattern toward a surface. The camera has at least two off-axis apertures thereon, arranged to obtain an image of the projected pattern including defocused information. The camera is movable between different positions to image the surface from said different positions, and the projector is at a specified angle of at least 5° relative to said camera. A processor carries out a first operation using information received through the apertures to determine a pose of said camera, and to determine three dimensional information about the object based on a degree of deformation of said optical pattern on said surface indicative of a three dimensional surface. An embodiment projects a grid of laser dots and uses laser-dot defocusing for approximate Z and thus grid correspondence, which can greatly increase the working depth of the system. | 03-31-2011 |
| 20110111365 | APPARATUS AND METHODS FOR ROOT CANAL TREATMENTS - Apparatus and methods for root canal treatments are provided. In some embodiments, an aiming element may be used to position a high-velocity liquid jet near a desired location in the tooth. Embodiments of the aiming element may include an interrupter that deflects or impedes the liquid jet when it is not desirable for the jet to propagate from the aiming element. Embodiments of the aiming element may include an elongated member that permits passage of the liquid jet through a channel. The elongated member may include one or more openings, for example, on sides and/or ends of the member. Some root canal cleaning techniques include one or more applications of the liquid jet followed by application of a disinfectant such as, for example, an aqueous solution of sodium hypochlorite. | 05-12-2011 |
| 20110165001 | HELICALLY ACTUATED POSITIVE-DISPLACEMENT PUMP AND METHOD - First and second structures are connected by helical fibers. The orientation between the first and second structures are changed, and by doing so, the positions of the helical fibers are correspondingly changed. The position of change of the helical fibers can be used for a pumping effect, or to change some other fluidic characteristics. One other fluidic characteristics, for example, may use the movement of the helical fibers as a valve. | 07-07-2011 |
| 20110189627 | ROOT CANAL FILLING MATERIALS AND METHODS - In various embodiments of a method for filling root canal spaces, the root canal spaces are cleaned and irrigated, for example, by any suitable endodontic procedure, and the irrigating liquid is not removed from the canal spaces prior to filling. In some embodiments, a hydrophobic filler material is introduced into the root canal spaces while they are filled with liquid. As the canal spaces are filled, the hydrophobic filler material displaces the liquid and drives it out of the canal spaces, towards the crown of the tooth, where it can be removed. The hydrophobic filler material may comprise magnetically responsive particles having a hydrophobic surface coating that are compacted into the root canal spaces by application of a magnetic force field. In other embodiments, hydrophilic filler material in a flowable phase is introduced into the canal spaces where it partly displaces and partly absorbs the irrigating liquid before solidifying. | 08-04-2011 |
| 20110236619 | FABRICATION OF ANCHORED CARBON NANOTUBE ARRAY DEVICES FOR INTEGRATED LIGHT COLLECTION AND ENERGY CONVERSION - A method of fabricating optical energy collection and conversion devices using carbon nanotubes (CNTs), and a method of anchoring CNT's into thin polymeric layers is disclosed. The basic method comprises an initial act of surrounding a plurality of substantially aligned nanostructures within at least one fluid layer of substantially uniform thickness such that a first end of the plurality of nanostructures protrudes from the fluid layer. Next, the fluid layer is altered to form an anchoring layer, thereby fastening the nanostructures within the primary anchoring layer with the first ends of the nanostructures protruding from a first surface of the primary anchoring layer. Finally, a portion of the anchoring layer is selectively removed such that a second end of the nanostructures is exposed and protrudes from the anchoring layer. The resulting product is an optically absorbent composite material having aligned nanostructures protruding from both sides of an anchoring layer. | 09-29-2011 |
| 20110251670 | EXPANDABLE STENT THAT COLLAPSES INTO A NON-CONVEX SHAPE AND EXPANDS INTO AN EXPANDED, CONVEX SHAPE - An expandable stent that can transform between a collapsed state and an expanded state is described. The stent includes a first cross-sectional shape and a second cross-sectional shape. The first cross-sectional shape is a non-convex shape when the stent is in the collapsed state. Alternatively, the second cross-sectional shape is a convex shape when the stent is in an expanded state. The stent can be formed of super elastic Nitinol, which allows it to be shape set in the desired shape. Due to its shape setting properties and the non-convex cross-section, the stent is capable of dramatically reducing its cross-sectional radial profile which is beneficial in a variety of procedures. | 10-13-2011 |
