Abstract: An expandable implant for inserting within a skeletal space is provided, and a method for using the implant to expand the skeletal space. The implant is preferably designed to be inserted into an intervertebral space to replace at least part of an intervertebral disc between adjacent vertebral bodies. The expandable implant contains at least one first expansion compartment and at least one second expansion compartments, which compartments can be inflatable balloons that are inflated by a catheter. Inflating the first expansion compartment expands the implant in a first direction and inflating the second expansion compartment expands the implant in a second direction.

Abstract: Sensor fusion algorithm techniques are described. In one or more embodiments, behaviors of a host device and accessory devices are controlled based upon an orientation of the host device and accessory devices, relative to one another. A combined spatial position and/or orientation for the host device may be obtained based on raw measurements that are obtained from at least two different types of sensors. In addition, a spatial position and/or orientation for an accessory device is ascertained using one or more sensors of the accessory device. An orientation (or position) of the accessory device relative to the host computing device may then be computed based on the combined spatial position/orientation for the host computing device and the ascertained spatial position/orientation for the accessory device. The relative orientation that is computed may then be used in various ways to control behaviors of the host computing device and/or accessory device.

Abstract: A catheter (100, 200) for insertion into a human and/or animal hollow organ, comprising a catheter shaft (110, 210) with a lumen (120, 220), which opens into a front opening at a distal end (112, 212) of the catheter shaft (110, 210), wherein the catheter shaft (110, 210) has at least a first lateral opening (130, 230a) that is at a distance from the distal end (112, 212) and opens into the lumen (120, 220), is distinguished by virtue of the fact that there is at least a first insertion device (140, 240a), arranged on an external side (114, 214) of the catheter shaft (110, 210) in a region of the first lateral opening (130, 230a), for a wire-like element (300, 400, 500) that should be inserted into the first lateral opening (130, 230a) from the outside.

Abstract: Sensor fusion algorithm techniques are described. In one or more embodiments, behaviors of a host device and accessory devices are controlled based upon an orientation of the host device and accessory devices, relative to one another. A combined spatial position and/or orientation for the host device may be obtained based on raw measurements that are obtained from at least two different types of sensors. In addition, a spatial position and/or orientation for an accessory device is ascertained using one or more sensors of the accessory device. An orientation (or position) of the accessory device relative to the host computing device may then be computed based on the combined spatial position/orientation for the host computing device and the ascertained spatial position/orientation for the accessory device. The relative orientation that is computed may then be used in various ways to control behaviors of the host computing device and/or accessory device.

Abstract: Sensor fusion algorithm techniques are described. In one or more embodiments, behaviors of a host device and accessory devices are controlled based upon an orientation of the host device and accessory devices, relative to one another. A combined spatial position and/or orientation for the host device may be obtained based on raw measurements that are obtained from at least two different types of sensors. In addition, a spatial position and/or orientation for an accessory device is ascertained using one or more sensors of the accessory device. An orientation (or position) of the accessory device relative to the host computing device may then be computed based on the combined spatial position/orientation for the host computing device and the ascertained spatial position/orientation for the accessory device. The relative orientation that is computed may then be used in various ways to control behaviors of the host computing device and/or accessory device.

Abstract: Sensor fusion algorithm techniques are described. In one or more embodiments, behaviors of a host device and accessory devices are controlled based upon an orientation of the host device and accessory devices, relative to one another. A combined spatial position and/or orientation for the host device may be obtained based on raw measurements that are obtained from at least two different types of sensors. In addition, a spatial position and/or orientation for an accessory device is ascertained using one or more sensors of the accessory device. An orientation (or position) of the accessory device relative to the host computing device may then be computed based on the combined spatial position/orientation for the host computing device and the ascertained spatial position/orientation for the accessory device. The relative orientation that is computed may then be used in various ways to control behaviors of the host computing device and/or accessory device.

Abstract: Techniques for mobile device power state are described. In one or more implementations, a mobile device includes a computing device that is flexibly coupled to an input device via a flexible hinge. Accordingly, the mobile device can operate in a variety of different power states based on a positional orientation of the computing device to an associated input device. In one or more implementations, an application that resides on a computing device can operate in different application states based on a positional orientation of the computing device to an associated input device. In one or more implementations, techniques discussed herein can differentiate between vibrations caused by touch input to a touch functionality, and other types of vibrations. Based on this differentiation, techniques can determine whether to transition between device power states.

Abstract: Sensor fusion algorithm techniques are described. In one or more embodiments, behaviors of a host device and accessory devices are controlled based upon an orientation of the host device and accessory devices, relative to one another. A combined spatial position and/or orientation for the host device may be obtained based on raw measurements that are obtained from at least two different types of sensors. In addition, a spatial position and/or orientation for an accessory device is ascertained using one or more sensors of the accessory device. An orientation (or position) of the accessory device relative to the host computing device may then be computed based on the combined spatial position/orientation for the host computing device and the ascertained spatial position/orientation for the accessory device. The relative orientation that is computed may then be used in various ways to control behaviors of the host computing device and/or accessory device.

Abstract: Techniques for mobile device power state are described. In one or more implementations, a mobile device includes a computing device that is flexibly coupled to an input device via a flexible hinge. Accordingly, the mobile device can operate in a variety of different power states based on a positional orientation of the computing device to an associated input device. In one or more implementations, an application that resides on a computing device can operate in different application states based on a positional orientation of the computing device to an associated input device. In one or more implementations, techniques discussed herein can differentiate between vibrations caused by touch input to a touch functionality, and other types of vibrations. Based on this differentiation, techniques can determine whether to transition between device power states.

Abstract: A duct for enclosing post tension reinforcing tendons includes a first closed circumference conduit having at least one minimum internal radius. The conduit includes at least one corrugation including two longitudinally spaced apart end members wherein a radial outer surface of each end member defining at least one external radius. A reduced diameter portion is disposed between the two end members. The reduced diameter portion defining at least one intermediate radius larger than the at least one minimum internal radius and smaller than the at least one external radius.

Abstract: A guide wire for a catheter comprises an elongated hollow shaft has a lumen for delivering or leading away the fluid, and an insertion aid in the form of a flexible wire coil connected coaxially to a distal end of the hollow shaft. The wire coil has a guide wire tip arranged at a distal end, a core wire being arranged in the lumen of the hollow shaft to control the flexibility of the guide wire. The core wire extends out of the lumen and through the wire coil to the guide wire tip. A distal inner area of the wire coil adjacent to the guide wire tip in a proximal direction communicates with the lumen of the hollow shaft by means of a fluid channel formed next to the core wire and has at least one outwardly open passage opening for the fluid to be introduced or removed.

Abstract: A catheter (100, 200) for insertion into a human and/or animal hollow organ, comprising a catheter shaft (110, 210) with a lumen (120, 220), which opens into a front opening at a distal end (112, 212) of the catheter shaft (110, 210), wherein the catheter shaft (110, 210) has at least a first lateral opening (130, 230a) that is at a distance from the distal end (112, 212) and opens into the lumen (120, 220), is distinguished by virtue of the fact that there is at least a first insertion device (140, 240a), arranged on an external side (114, 214) of the catheter shaft (110, 210) in a region of the first lateral opening (130, 230a), for a wire-like element (300, 400, 500) that should be inserted into the first lateral opening (130, 230a) from the outside.

Abstract: The invention relates to a catheter for introducing into a hollow human or animal organ. Said catheter comprises a catheter tip that protrudes forwards and a region that is encased by an expandable tubular hollow body and that is situated behind the catheter tip. Said catheter is characterised in that a wire spiral is located in the encased region. It can also be advantageous to provide a radiopaque ring, in particular a platinum, gold or tungsten ring, on a hollow shaft of the catheter, together with several rib-type projections running around the hollow shaft and projecting from the latter, in a region in front of and/or behind the radiopaque ring.

Abstract: The present invention provides for methods of using guide wires adapted for passage across a heart valve. The guide wires have an increased diameter and a shorter, relatively floppy distal tip; the increased diameter providing improved pushability to facilitate positioning in a blood jet and passage through a heart valve. The distal tip comprises a section of rectangular cross-section that, in conjunction with the decreased tip length, causes the distal tip to vibrate, or “dance”, when positioned within a blood jet at the outlet of a heart valve. This vibratory motion may be used to position the distal tip within the blood jet, thus facilitating passage through the valve without damage to leaflets of the valve or emboli generation.

Abstract: A method for coaxially connecting a first plastic tube (10, 110) to a second plastic tube (20, 120), said plastic tubes (10, 20). In particular being provided as part of a medical catheter (102), the two plastic tubes (10, 20) being connected by way of a tubular connecting piece (50), characterized in that the first plastic tube (10) and/or the second plastic tube (20) are integrally molded from the outside onto the tubular connecting piece (50) using a forming process such that an adhesive and/or positive connection is produced.

Abstract: A thermal sensing system includes a one-piece clip formed of a thermally conductive material. The clip includes a flat, substantially enclosed portion with tabs extending upward from it for connecting the clip to a printed circuit board. The clip also includes a contact portion that is configured to contact a thermally emitting object along a substantial portion of its surface. The thermal sensing system also includes a thermistor. The thermistor may be mounted to the printed circuit board or directly mounted to the clip. Heat is transferred from the thermal object to the thermistor via the clip. This system may be used in various arrangements in which temperature of an object is monitored or maintained within a given range. For example, the system may be used with a rechargeable mouse to monitor the temperature of the replaceable battery during charging and discontinue charging should the temperature reach a predetermined limit.

Abstract: A thermal sensing system includes a one-piece clip formed of a thermally conductive material. The clip includes a flat, substantially enclosed portion with tabs extending upward from it for connecting the clip to a printed circuit board. The clip also includes a contact portion that is configured to contact a thermally emitting object along a substantial portion of its surface. The thermal sensing system also includes a thermistor. The thermistor may be mounted to the printed circuit board or directly mounted to the clip. Heat is transferred from the thermal object to the thermistor via the clip. This system may be used in various arrangements in which temperature of an object is monitored or maintained within a given range. For example, the system may be used with a rechargeable mouse to monitor the temperature of the replaceable battery during charging and discontinue charging should the temperature reach a predetermined limit.

Abstract: The invention relates to a process for administering a medication in a blood vessel using a balloon catheter with a balloon which has at least one flank. An inflow direction of the medication is established (i.e., takes place) at an angle ? from 0° to 89°, the angle ? being formed from the flow direction of the blood in the blood vessel and the flank of the balloon.

Abstract: A device for treatment of mitral annulus dilatation comprises an elongate body having two states. In a first of these states the elongate body is insertable into the coronary sinus and has a shape adapting to the shape of the coronary sinus. When positioned in the coronary sinus, the elongate body is transferable to the second state assuming a reduced radius of curvature, whereby the radius of curvature of the coronary sinus and the radius of curvature as well as the circumference of the mitral annulus is reduced.

Abstract: A guiding aid for an instrument to be advanced within a vascular system, particularly the human vascular system, comprising a flexible shapeable shaft comprising a first bent section having a first curvature and at least one further bent section, wherein the bent sections of the shaft have the same sign of curvature and are located substantially within the same plane. Such a guiding aid may be pre-formed by the manufacturer such that the guiding aid may be introduced into vascular branchings both from large lumen and small lumen vessels by a physician manipulating the instrument from its proximal end.