Abstract: A system, device and method include a sensing enabled device having an optical fiber configured to perform distributed sensing of temperature-induced strain. An interpretation module is configured to receive optical signals from the optical fiber within a body and interpret the optical signals to determine one or more temperatures or temperature gradients of the device.

Abstract: A medical system for minimally-invasive measurement of blood flow in an artery (AT). An interventional device (IVD) with an optical fiber (FB) comprising a plurality of temperature-sensitive optical sensor segments, e.g. Fiber Bragg Gratings, spatially distributed along its longitudinal extension is configured for insertion into an artery (AT). A temperature changer (TC) is arranged in the WD to introduce a local change in temperature (?T) of a bolus of blood in the artery, to allow thermal tracking over time with the optical fiber (FB). A measurement unit (MU) with a laser light source (LS) delivers light to the optical fiber (FB) and receives light reflected from the optical fiber (FB) and generates a corresponding time varying output signal. A first algorithm (A1) translates this time varying output signal into a set of temperatures corresponding to temperatures at respective positions along the optical fiber (FB).

Abstract: The disclosure is directed solutions and processes to remove substances from substrates. The substances can include photoresist. The solutions can include dimethylsulfoxide, a quaternary ammonium hydroxide, an alkanolamine, and less than 3% by weight water of a total weight of the solution. The quaternary ammonium hydroxide can include tetramethylammonium hydroxide, dimethyldipropylammonium hydroxide, or methyltriethylammonium hydroxide. Additionally, the solutions can include a secondary solvent. For example, the secondary solvent can include an alcohol. In another example, the secondary solvent can include ethylene glycol. Methods for the preparation and use of the solution to remove substances from substrates are also described.

Abstract: A system and method include a shape sensing enabled device too (102) having an optical fiber (126). An interpretation module (115) is configured to receive optical signals from the optical fiber within a structure and interpret the optical signals to determine a shape of the device. An image generation module (140) is configured to receive the shape of the device, register the shape with an image volume of the structure and generate a curved Memory multi-planar reconstruction (CMPR) rendering based on the shape.

Abstract: A guidance system and method include a real-time imaging device (121) configured to intra-operatively collect image data of a target region to provide a real-time image. A target determination module (108) is configured to generate an overlay map (111) registered to the real-time image to project morphological feature information on corresponding features in the real-time image of the target region. A medical instrument (122) is provided to perform a procedure on the target region such that the at least one medical instrument is guided to a region suitable for performing an operative task based upon the overlay map.

Abstract: A method of simultaneously cleaning inorganic and organic contaminants from semiconductor wafers and micro-etching the semiconductor wafers. After the semiconductor wafers are cut or sliced from ingots, they are contaminated with cutting fluid as well as metal and metal oxides from the saws used in the cutting process. Aqueous alkaline cleaning and micro-etching solutions containing alkaline compounds and mid-range alkoxylates are used to simultaneously clean and micro-etch the semiconductor wafers.

Abstract: A tableware item molded from a plastic material, such as polystyrene has a metallic coating applied to at least one surface by a sputtering deposition process. The sputtered coating is suitable for food contact without an overcoat, and imparts the appearance of a metal tableware item. In embodiments, the tableware item is a cup, a plate, a bowl, a tray, a lid, a glass, a champagne flute, a goblet, a napkin ring, a candle holder, or a centerpiece receptacle. The metallic coating can be silver, steel, stainless steel, chromium, aluminum, copper, or gold. In some embodiments, the metallic coating is not applied to all surfaces of the tableware item. In various embodiments, the tableware article is molded from a clear polystyrene resin and coated with a thin stainless steel layer on only one side. The abrasion resistance of the metallic coating can be enhanced by applying a clear protective overcoat.

Abstract: A system, device and method for measuring dynamic movement of a subject include a mesh configured to flexibly and snuggly fit over at least a portion of the subject. The mesh includes one or more shape sensing optical fibers disposed therein, and a second feedback modality of measurement that includes sensors or detectors incorporated therein such that the one or more shape sensing optical fibers monitors movement of the sensors or detectors on a subject. A reconstruction module is coupled to the shape sensing fibers to receive feedback signals and interpret dynamic changes in a shape and position of the sensors or detectors based on the feedback signals. The reconstruction module accounts for the dynamic changes to improve a medical activity on the subject.

Abstract: A system for monitoring changes during therapy includes a first probing segment (112) having an optical fiber sensor disposed therein. The first segment is percutaneously inserted in or near a target area and providing a local reference for one or more treatment devices. A second probing segment (114) has an optical fiber sensor disposed therein. The second segment is generally disposed apart from the first probe and provides a spatial reference point for the first segment. The first and second segments have at least one common position to function as a reference between the first and second probes. A shape determination method (107) is configured to determine a shape of each of the first and second segments based on feedback signals to measure changes in the shapes during a procedure and update a therapy plan in accordance with the changes.

Abstract: A reflection reduction device includes an optical fiber (104) configured for optical sensing and having an end portion. A tip portion (102) is coupled to the end portion. The tip portion includes a length dimension (d) and is index matched to the optical fiber. The tip portion is further configured to include an absorption length to absorb and scatter light within the length dimension, and a surface (S) opposite the end portion is configured to reduce back reflections.

Abstract: An image-guided prosthetic valve deployment system employs a prosthetic valve (80), a catheter (70) and a delivery tracking system (90). The catheter (70) has an elongated body with a proximal tip (71a) and a distal tip (71b), and the elongated body includes a delivery section (72) adjacent the distal tip (71b) for deploying the prosthetic valve (80) relative to a heart valve (21) within an anatomical region (20). The delivery section (72) includes a delivery segment (73) for sensing a shape and an orientation of the delivery section (72) within the anatomical region (20) relative to a reference point (74). The delivery tracking system (90) tracks a position and an orientation of the prosthetic valve (80) relative to the heart valve (21) as a function of a sensed shape and a sensed orientation of the delivery section (72) within the anatomical region (20) relative to the reference point (74) by the delivery segment (73).

Abstract: A system and method for shape sensing assistance in a medical procedure includes providing (402) a three-dimensional image of a distributed pathway system. A shape sensing enabled elongated device is introduced (406) into the pathway system. A shape of the elongated device in the pathway system is measured (410). The shape is compared (414) with the three-dimensional image to determine whether a given path has been selected relative to a target.

Abstract: A plastic cutlery item molded from a plastic material, such as polystyrene, having a metallic coating that imparts to this cutlery item the appearance of metal cutlery or silverware. In one embodiment the plastic cutlery or tableware items are molded using injection molding techniques, and subjected to a vacuum metallizing process in an individualized non-contiguous manner, where a thin metallic layer is deposited on at least one of their surfaces. The resultant items simulate the appearance of metal cutlery or tableware. In one embodiment of the invention the plastic cutlery or tableware articles are molded from a clear polystyrene resin and are coated with a thin stainless steel layer through vacuum sputtering deposition on only one of the sides. The abrasion resistance of the metallic coating can be enhanced by subjecting the articles to a post-metallizing holding period or by applying a clear protective overcoat.

Abstract: The method of the invention includes the sequential steps of providing a plurality of solar cells, interconnecting the solar cells using one or more interconnect tabs, attaching the interconnect tabs to a top side of the solar cell to interconnect the plurality of solar cells by coupling an exposed top surface of a first solar cell to a top surface of an adjacent second solar cell, attaching one or more bypass diodes to a top side of the solar cell, then next applying an adhesive to a first film layer, placing the plurality of solar cells onto the first film layer, then next applying an adhesive to a second film layer, placing the plurality of solar cells and first film layer onto the second film layer to form a sheet assembly, and then forming the solar sheet from the sheet assembly.

Abstract: A tissue ablation device employs one or more energy emitters (21) and one or more photoacoustic sensors (22) in a cooperative arrangement for applying a tissue ablation therapy to a tissue (60). In operation, the energy emitters (21) emit a tissue ablation beam (TA) into a target portion of the tissue (60) to form a lesion (61) therein, and alternatively or concurrently emit a photoexcitation beam (PE) into the target portion of the tissue (60) to excite a photoacoustic response from the tissue (60). The photoacoustic sensor(s) (22) sense the photoacoustic response of the tissue (60).

Abstract: A medical instrument, system and method for calibration are provided. The instrument includes a body (202) and a shape sensing system (204) coupled to the body to permit determination of a shape of the body. A memory element (205, 206) is coupled to the body and configured to store data associated with calibration of the body, the data being readable through a cable (210) connectable to the body so that the data permits calibration of the body.

Abstract: A medical method and system include a medical imaging system (105) configured to generate images of an interventional procedure. An overlay generator (113) is configured to generate an overlay image on the images of the interventional procedure. An interventional device tracking system (108, 125) is configured to track a three-dimensional position, orientation and shape of the interventional device during the procedure, wherein the overlay image is dynamically updated in response to deformations caused to an organ of interest by the interventional device during the procedure.

Abstract: An optical shape sensing system employing an optical fiber (20) and one or more reference markers (41). Each reference marker (41) has an identifiable reference tracking position within a reference coordinate system (42). The optical fiber (20) has a reconstruction launch point (21)within the reference coordinate system (42) serving as a basis for an execution of a shape reconstruction of the optical fiber (20) within the reference coordinate system (42). The reconstruction launch point (21)of the optical fiber (20) has a known spatial relationship with each reference marker (41) to facilitate an identification of the reconstruction launch point (21)within the reference coordinate system (42).

Abstract: An integrated optical shape sensing system and method include an arrangement structure (132) configured to receive a fiber port or connector. A platform (130) is configured to provide a distance relationship with the arrangement structure such that the fiber port or connector is trackable to provide a location reference. The platform secures a patient in proximity to the arrangement structure. An optical shape sensing enabled interventional instrument (102) has a first optical fiber cable connectable to the fiber port or connector. An optical interrogation module (108) is configured to collect optical feedback from the instrument and has a second optical fiber cable connectable to the fiber port or connector such that a known reference position is provided for accurate shape reconstruction.

Abstract: A telescopic endoscope employing a primary endoscope (30, 50) having a instrument channel, a miniature secondary endoscope (40, 60) deployed within the instrument channel of the primary endoscope (30, 50), and an endoscope tracker including one or more sensors (32, 61) and one or markers (41, 52) for sensing any portion of the miniature secondary endoscope (40, 60) extending from a distal end of the instrument channel of the primary endoscope (30, 50).