Abstract: Described herein is a system for inducing weight loss in a patient, which comprises an extragastric space occupier positionable in contact with an exterior surface of a stomach wall to form an inward protrusion of wall into the stomach, and a retention device positionable in contact with the wall to retain the inward protrusion and to thereby capture the extragastric space occupier within the protrusion.

Abstract: An enclosure has a sidewall with a step that results in an upper part of the sidewall extending over a slide mounting region. A backplane is located at a base of the enclosure and is configured to receive a plurality of data storage drives. A circuit carrier extends from the backplane to the step in the side of the enclosure. The circuit carrier has one or more connectors proximate an upper surface of the step and is configured to receive one or more expansion modules that expand a functionality of the backplane.

Abstract: A printing system for printing a three-dimensional optical component, including a printing unit having a print head with ejection nozzles for ejecting droplets of printing ink, a measurement unit to measure optical properties of a pre-structure of the three-dimensional optical component, wherein the measurement unit includes at least one light source and at least one light detector, further including a process control unit for determining the difference between the measured optical properties of the pro-structure and target optical properties of the pre-structure. The present teachings further relate to a corresponding method.

Abstract: An engineered payload-delivery system includes a target cell binding unit, covalently bound to a pore forming unit, and a payload portion adapted with a region capable of non-covalently binding to the pore forming unit. The pore forming unit is derived from a particular sub-serotype of Clostridium toxin, while the payload region is derived from a different sub-serotype of Clostridium toxin. The disclosed chimeric protein-based composition is capable of specifically delivering payload to neural cells.

Abstract: Embodiments described herein provide devices, systems, and methods that reduce the distance between two locations in tissue, often for treatment of congestive heart failure. For example, an anchor of an implant system may, when the implant system is fully deployed, reside within the right ventricle in engagement with the ventricular septum. The anchor may be deployed into the heart through a working lumen of a minimally invasive access tool. The minimally invasive access tool may have a plurality of grippers near a distal end of the working lumen. The grippers may engage epicardial tissue of the heart and may be moved radially inwardly relative so as to provide stabilization of the epicardial tissue and/or hemostasis near an access site where the anchor is inserted through the epicardium. The minimally invasive access tool may minimize blood loss from the access site and improve anchor implant processes.

Abstract: A lithographic apparatus including a support to support a patterning device, a substrate table to hold a substrate, and a projection system to project a radiation beam patterned by the patterning device onto a target portion of the substrate. A transparent layer is provided to protect the pattering device. The apparatus further includes a transparent layer deformation-determining device to determine a deformation profile of the transparent layer, the deformation profile of the transparent layer expressing a deformation of the transparent layer during a scanning movement of the lithographic apparatus, and a compensator device which is configured to control the projection system, the substrate table and/or the support in response to the deformation profile of the transparent layer to compensate for the deformation of the transparent layer during the scanning movement of the apparatus.

Abstract: A data storage enclosure can employ an acoustic baffle for the purpose of reducing performance degradation in a data storage device, such as a rotating medium hard disk drive. A storage enclosure may house a plurality of data storage devices and at least one cooling feature. One or more acoustic baffles may be positioned between the at least one cooling feature and the plurality of data storage devices. The acoustic baffle can separate a first sound pressure region that is proximal the at least one cooling feature from a second sound pressure region that is proximal the plurality of data storage devices.

Abstract: A data storage enclosure can house and electrically connect to multiple data storage devices respectively secured by a carrier. A toolless data storage device carrier can be configured with a data storage device disposed between first and second rails and a clip physically contacting each rail while spanning the data storage device. The clip being shaped to continuously force each rail into contact with the data storage device.

Abstract: A data storage enclosure can house and electrically connect to multiple data storage devices respectively secured by a carrier. A toolless data storage device carrier can be configured with a data storage device disposed between first and second rails and a clip physically contacting each rail while spanning the data storage device. The clip being shaped to continuously force each rail into contact with the data storage device.

Abstract: A data storage enclosure can have one or more data storage devices positioned in an enclosure slot having one or more stops. A data storage device can be attached to a rail having a rail width and having first and second protrusions offset from one another. The first and second protrusions may each have protrusion widths that are less than the rail width with the second protrusion shaped to provide a positive stop that retains the rail in an enclosure slot.

Abstract: A data storage enclosure can have one or more data storage devices positioned in an enclosure slot having one or more stops. A data storage device can be attached to a rail having a rail width and having first and second protrusions offset from one another. The first and second protrusions may each have protrusion widths that are less than the rail width with the second protrusion shaped to provide a positive stop that retains the rail in an enclosure slot.

Abstract: Embodiments described herein include devices, systems, and methods for reducing the distance between two locations in tissue. In one embodiment, an anchor may reside within the right ventricle in engagement with the septum. A tension member may extend from that anchor through the septum and an exterior wall of the left ventricle to a second anchor disposed along a surface of the heart. Perforating the exterior wall and the septum from an epicardial approach can provide control over the reshaping of the ventricular chamber. Guiding deployment of the implant from along the epicardial access path and another access path into and through the right ventricle provides control over the movement of the anchor within the ventricle. The joined epicardial pathway and right atrial pathway allows the tension member to be advanced into the heart through the right atrium and pulled into engagement along the epicardial access path.

Abstract: A system for treating a heart includes a catheter that is advanceable into a chamber of the heart and that is repositionable within the chamber between a septal wall and an external wall to enable penetration of the septal and external walls via a needle that is disposed within a lumen of the catheter. A first guidewire is deliverable through the penetration of the septal wall so that a distal end of the first guidewire is disposed within another chamber of the heart. A second guidewire is deliverable through the penetration of the external wall so that a distal end of the second guidewire is disposed externally of the external wall. The first guidewire is connectable to the second guidewire to join or form a path within the chamber that extends between the septal wall and the external wall.

Abstract: Methods and apparatuses for dynamic data normalization and duplicate analysis include normalizing data (e.g., merchant identifier data) received from a source entity (e.g., transaction card provider), as well as identifying and resolving potential duplicate transaction data objects based on one or more transaction characteristics. For example, data normalization includes partitioning an identifier into one or more merchant identifier portions, sending a merchant identifier request to a merchant database, and receiving a set of merchant representation candidates in response to sending the merchant identifier request. Further, for instance, duplicate analysis includes determining whether a transaction data object from the first set of transaction data objects that falls within the overlapping portion is not present in the second set of transaction data objects, and identifying the transaction data object within the second set of transaction data objects and the one or more non-overlapping portions.

Abstract: Methods and apparatuses for dynamic data normalization and duplicate analysis include normalizing data (e.g., merchant identifier data) received from a source entity (e.g., transaction card provider), as well as identifying and resolving potential duplicate transaction data objects based on one or more transaction characteristics. For example, data normalization includes partitioning an identifier into one or more merchant identifier portions, sending a merchant identifier request to a merchant database, and receiving a set of merchant representation candidates in response to sending the merchant identifier request. Further, for instance, duplicate analysis includes determining whether a transaction data object from the first set of transaction data objects that falls within the overlapping portion is not present in the second set of transaction data objects, and identifying the transaction data object within the second set of transaction data objects and the one or more non-overlapping portions.

Abstract: Methods and apparatuses for dynamic data normalization and duplicate analysis include normalizing data (e.g., merchant identifier data) received from a source entity (e.g., transaction card provider), as well as identifying and resolving potential duplicate transaction data objects based on one or more transaction characteristics. For example, data normalization includes partitioning an identifier into one or more merchant identifier portions, sending a merchant identifier request to a merchant database, and receiving a set of merchant representation candidates in response to sending the merchant identifier request. Further, for instance, duplicate analysis includes determining whether a transaction data object from the first set of transaction data objects that falls within the overlapping portion is not present in the second set of transaction data objects, and identifying the transaction data object within the second set of transaction data objects and the one or more non-overlapping portions.

Abstract: Embodiments described herein include devices, systems, and methods for reducing the distance between two locations in tissue. In one embodiment, an anchor may reside within the right ventricle in engagement with the septum. A tension member may extend from that anchor through the septum and an exterior wall of the left ventricle to a second anchor disposed along a surface of the heart. Perforating the exterior wall and the septum from an epicardial approach can provide control over the reshaping of the ventricular chamber. Guiding deployment of the implant from along the epicardial access path and another access path into and through the right ventricle provides control over the movement of the anchor within the ventricle. The joined epicardial pathway and right atrial pathway allows the tension member to be advanced into the heart through the right atrium and pulled into engagement along the epicardial access path.

Abstract: A heart implant alignment and delivery device includes an elongate body having an opening that is disposed near a distal end of the elongate body. The opening is configured so that a heart implant is positionable within the opening with the heart implant exposed to a surrounding environment and so that the heart implant is substantially aligned with the distal end of the elongate body. The device also includes an implant reposition member, such as a cable, that is releasably coupleable with the heart implant and that is operationally coupled with the elongate body so that a first operation of the implant reposition member causes the heart implant to be retractably deployed from the opening of the elongate body. The first operation of the implant reposition member may be effected via a handle mechanism that is attached to a proximal end of the elongate body.

Abstract: A utility vehicle is disclosed. The utility vehicle may include storage areas under the dash. The utility vehicle may include suspension systems for utility vehicles having shocks with both a fluidic stiffness adjustment and a mechanical stiffness adjustment. The utility vehicle may include an electrical power steering.

Abstract: The present application describes an implant system useable for positioning an implant device such as a device useful for restricting passage of ingested food into the stomach. In one embodiment, the disclosed system includes a plurality of anchors that may be coupled to tissue within the stomach, or to a tissue tunnel formed by plicating stomach wall tissue. The anchor includes a loop. During use, the implant device is inserted through the loop and expanded such that it retains its position within the loop until removed. Instruments for implanting and explanting the implant device are also described.