Abstract: A method includes: receiving, at a computing device, diabetes management data from a diabetes management device, wherein the diabetes management data does not include a blood glucose (bG) measurement; using the computing device, transmitting an indicator of an account and the diabetes management data to a diabetes management server. The method further includes, using the diabetes management server: creating a bG measurement entry for the account in a database, leaving empty a field of the bG measurement entry for a bG measurement in the bG measurement entry based on the diabetes management data not including a bG measurement; and storing the diabetes management data in one or more respective fields of the bG measurement entry. The method further includes, using the diabetes management server, generating a user interface for displaying data stored in the bG measurement entry and at least one other bG measurement entry associated with the account.

Abstract: A method for displaying contextual information by a diabetes reporter of a diabetes management system is provided. The method may include: displaying a graphical representation of a plurality of data values over a period of time in a first area of an interface display; receiving a selection of a desired data value from among the plurality of data values displayed in the first area; displaying, in response to the selection, a first set of data entries and a second set of data entries in a second area of the interface display concurrently with the graphical representation of the plurality of data values in the first area of an interface display. The first set of data entries and the second set of data entries are displayed in chronological order within a preset time period.

Abstract: A vacuum chuck for holding a semiconductor wafer during high pressure processing comprises a wafer platen, first through third lift pins, and an actuator mechanism. The wafer platen comprises a smooth surface, first through third lift pin holes, and a vacuum opening. In use, the vacuum opening applies vacuum to a surface of a semiconductor wafer, which chucks the semiconductor wafer to the wafer platen. The first through third lift pins mount within the first through third lift pin holes, respectively. The actuator mechanism couples the first through third lifting pins to the wafer platen. The actuator mechanism operates to extend the first through third lift pins in unison above the smooth surface of the wafer platen. The actuator mechanism operates to retract the first through third lift pins in unison to at least flush with the smooth surface of the wafer platen.

Abstract: A high pressure chamber for processing of a semiconductor substrate comprises a high pressure processing cavity, a plurality of injection nozzles, and first and second outlet ports. The high pressure processing cavity holds the semiconductor substrate during high pressure processing. The plurality of injection nozzles are oriented into the high pressure processing cavity at a vortex angle and are operable to produce a vortex over a surface of the semiconductor substrate. The first and second outlet ports are located proximate to a center of the plurality of injection nozzles and are operable in a first time segment to provide an operating outlet out of the first outlet port and operable in a second time segment to provide the operating outlet out of the second outlet port. In an alternative embodiment, an upper surface of the high pressure processing cavity comprises a height variation. The height variation produces more uniform molecular speeds for a process fluid flowing over the semiconductor substrate.

Abstract: An apparatus for agitating a workpiece in a high pressure environment comprises a workpiece holder, a bearing, a pressure chamber housing, and a nozzle. The workpiece holder couples to the pressure chamber housing via the bearing. The nozzle couples to the pressure chamber housing. The workpiece holder comprises protrusions and a region for holding the workpiece. In operation a fluid exits the nozzle and impinges the protrusions of the workpiece holder causing the workpiece holder to rotate, which agitates the workpiece.

Abstract: An apparatus for agitating a workpiece in a high pressure environment comprises a workpiece holder, a bearing, a pressure chamber housing, and a nozzle. The workpiece holder couples to the pressure chamber housing via the bearing. The nozzle couples to the pressure chamber housing. The workpiece holder comprises protrusions and a region for holding the workpiece. In operation a fluid exits the nozzle and impinges the protrusions of the workpiece holder causing the workpiece holder to rotate, which agitates the workpiece.

Abstract: A hinge assembly and methods for mounting a hatch relative to a port defined in a cover of a vacuum chamber to close and open the port. A torsion rod mounted between the port and the hatch is in torsion when the hatch is in a closed position relative to the port, assisting port-opening motion. A sleeve surrounds the rod and is movable with the hatch. Friction hinge structures between the cover and the sleeve, and between the hatch and a second sleeve are in a friction-engaging relationship with the corresponding sleeve. Each friction hinge structure provides high resistance to relative motion between a friction spring and the corresponding sleeve. During the port-opening motion of the hatch the friction springs provide low resistance to such relative motion. The hinge structures provide tolerance resistance and vacuum compliance by allowing relative movement between a hinge mounting plate and the hatch.

Abstract: A locking microcentrifuge tube (10) is provided which is capable of being sealed in either of two manners, one being a friction-fit seal which is easily opened and the other being a "locked" seal for higher stress applications. The tube body (12) is adapted to mate with the cap (14) at an aperture (24) such that the plug portion (36) of the cap (14) and the aperture (24) form the friction-fit seal at the early stages of insertion. A collar (26) is provided about the aperture (24) on the tube body (12). The collar (26) is formed to include one or more circumferential projections (28, 30). The cap (14) is formed to include depressions (32, 34) adapted to mate with the projections (28, 30) upon full insertion of the plug portion (36) to create the "locked" seal. The cap (14) is secured to the tube body (12) by a hinge (38) and a tab (40). The primary usage of the locking microcentrifuge tube (10) is in biomedical laboratory analysis.