Abstract: A process for manufacturing a vehicle panel is disclosed. In some embodiments, the process includes processing a metal coil that is made of stainless steel to form a sheet; processing the sheet to form a processed sheet; and bending the processed sheet to form the vehicle panel.

Abstract: Methods for the production of adenoviruses which are suitable for use in a vaccine, and methods for increasing the yield of adenoviruses during production. These methods include adding an adenovirus to a cell population in culture; culturing the cell population under conditions which are permissive for infection of the cell population with the adenovirus to provide a cell population comprising adenovirus-infected cells; culturing the cell population comprising adenovirus-infected cells under conditions which are permissive for replication of the adenovirus; and harvesting the adenovirus from the culture.

Abstract: Methods for the production of adenoviruses which are suitable for use in a vaccine, and methods for increasing the yield of adenoviruses during production. These methods include adding an adenovirus to a cell population in culture; culturing the cell population under conditions which are permissive for infection of the cell population with the adenovirus to provide a cell population comprising adenovirus-infected cells; culturing the cell population comprising adenovirus-infected cells under conditions which are permissive for replication of the adenovirus; and harvesting the adenovirus from the culture.

Abstract: Systems and methods for controlling mixing between one or more fluids are provided. The systems and methods may utilize a vessel comprising one or more zones where the zones are configured to minimize mixing between one or more fluids. Certain systems and methods may utilize a vessel comprising a tortuous flow path. Other systems and methods may utilize a vessel comprising one or more zones.

Abstract: Systems and methods for treating water are provided. The systems and methods may utilize an electrochemical water treatment device comprising ion exchange membranes. In certain systems and methods, a concentrate stream and a dilution stream may be in fluid communication with ion exchange membranes. The ion exchange membranes may be configured to provide a ratio of a pH of the concentrate stream and a pH of the dilution stream to be less than about 1.0. In some instances, the LSI of the concentrate stream may be less than or about 1.0. In certain instances, the electrochemical water treatment device does not require a reverse polarity cycle.

Abstract: Systems and methods for treating water are provided. The systems and methods may utilize an electrochemical water treatment device comprising ion exchange membranes. In certain systems and methods, a concentrate stream and a dilution stream may be in fluid communication with ion exchange membranes. The ion exchange membranes may be configured to provide a ratio of a pH of the concentrate stream and a pH of the dilution stream to be less than about 1.0. In some instances, the LSI of the concentrate stream may be less than or about 1.0. In certain instances, the electrochemical water treatment device does not require a reverse polarity cycle.

Abstract: Systems and methods for treating water are provided. The systems and methods may utilize an electrochemical water treatment device comprising ion exchange membranes. In certain systems and methods, a concentrate stream and a dilution stream may be in fluid communication with ion exchange membranes. The ion exchange membranes may be configured to provide a ratio of a pH of the concentrate stream and a pH of the dilution stream to be less than about 1.0. In some instances, the LSI of the concentrate stream may be less than or about 1.0. In certain instances, the electrochemical water treatment device does not require a reverse polarity cycle.

Abstract: Systems and methods for treating water are provided. In certain examples, the water to be treated is seawater. The systems and methods may utilize an electrochemical water treatment device comprising ion exchange membranes. In at least one example, the electrochemical water treatment device may be configured to perform a desalination process on seawater. In some examples, the ion exchange membranes may be configured to provide a ratio of a pH of the concentrate stream and a pH of the dilution stream to be in a range of from about 0.9 to about 1.2.

Abstract: Systems and methods for treating water are provided. The systems and methods may utilize an electrochemical water treatment device comprising ion exchange membranes. In certain systems and methods, a concentrate stream and a dilution stream may be in fluid communication with ion exchange membranes. The ion exchange membranes may be configured to provide a ratio of a pH of the concentrate stream and a pH of the dilution stream to be less than about 1.0. In some instances, the LSI of the concentrate stream may be less than or about 1.0. In certain instances, the electrochemical water treatment device does not require a reverse polarity cycle.

Abstract: Systems and methods for controlling mixing between one or more fluids are provided. The systems and methods may utilize a vessel comprising one or more zones product where the zones are configured to minimize mixing between one or more fluids. Certain systems and methods may utilize a vessel comprising a tortuous flow path. Other systems and methods may utilize a vessel comprising one or more zones.

Abstract: A sensor-dispensing instrument is adapted to determine an analyte concentration of a fluid and comprises a body, a cap, a cartridge, a test-sensor receptacle, and a sensor-advancement mechanism. The cap is adapted to move between an open position and a closed position. The cap and body are adapted to correspond with each other to form the closed position. The cartridge contains a plurality of test sensors. The cartridge is located substantially within the cap. The sensor-advancement mechanism is adapted to advance the plurality of test sensors, one at a time, to a position that allows a user to manually remove the test sensor and place the test sensor in the test-sensor receptacle. The sensor-dispensing instrument may also include a lancing device including a lancet.

Abstract: The present disclosure provides an orientation-nonspecific sensor port for use in analyte meters designed to detect and quantify analyte levels in a fluid sample along with methods of using the same. The present disclosure also provides compositions and methods for facilitating the correct insertion of a sensor into a corresponding analyte meter.

Abstract: The present disclosure provides an orientation-nonspecific sensor port for use in analyte meters designed to detect and quantify analyte levels in a fluid sample along with methods of using the same. The present disclosure also provides compositions and methods for facilitating the correct insertion of a sensor into a corresponding analyte meter.

Abstract: The present disclosure provides an orientation-nonspecific sensor port for use in analyte meters designed to detect and quantify analyte levels in a fluid sample along with methods of using the same. The present disclosure also provides compositions and methods for facilitating the correct insertion of a sensor into a corresponding analyte meter.

Abstract: Methods and devices to generate a tool for testing, simulating and/or modifying a closed loop control algorithm are provided. Embodiments include receiving glucose data for a predetermined time period, determining a variation in the glucose level based on the received glucose data, filtering a received glucose data based on the determined variation, substituting a negative change in the glucose data value with a predetermined value to generate a sequence of modified glucose values, and integrating the sequence of modified glucose values to determine an uncontrolled blood glucose excursion condition.

Abstract: A sensor-dispensing instrument is adapted to determine an analyte concentration of a fluid and comprises a body, a cap, a cartridge, a test-sensor receptacle, and a sensor-advancement mechanism. The cap is adapted to move between an open position and a closed position. The cap and body are adapted to correspond with each other to form the closed position. The cartridge contains a plurality of test sensors. The cartridge is located substantially within the cap. The sensor-advancement mechanism is adapted to advance the plurality of test sensors, one at a time, to a position that allows a user to manually remove the test sensor and place the test sensor in the test-sensor receptacle. The sensor-dispensing instrument may also include a lancing device including a lancet.

Abstract: A method and apparatus are provided for processing a nucleic acid. The apparatus includes a disposable self-contained processing module that contains the nucleic acid and substantially all of the fluids to effect a nanoparticle hybridization test, a pump coupled to the processing module, a valving system disposed between the pump and processing module and a control system coupled to the pump and valving system causing the processing fluids to interact with the nucleic acid to effect a sandwich hybridization test using nanoparticles.

Abstract: A sensor-dispensing instrument is adapted to determine an analyte concentration of a fluid and comprises a body, a cap, a cartridge, a test-sensor receptacle, and a sensor-advancement mechanism. The cap is adapted to move between an open position and a closed position. The cap and body are adapted to correspond with each other to form the closed position. The cartridge contains a plurality of test sensors. The cartridge is located substantially within the cap. The sensor-advancement mechanism is adapted to advance the plurality of test sensors, one at a time, to a position that allows a user to manually remove the test sensor and place the test sensor in the test-sensor receptacle. The sensor-dispensing instrument may also include a lancing device including a lancet.

Abstract: A method and apparatus are provided for processing a nucleic acid. The apparatus includes a disposable self-contained processing module that contains the nucleic acid and substantially all of the fluids to effect a nanoparticle hybridization test, a pump coupled to the processing module, a valving system disposed between the pump and processing module and a control system coupled to the pump and valving system causing the processing fluids to interact with the nucleic acid to effect a sandwich hybridization test using nanoparticles.

Abstract: The present disclosure provides an orientation-nonspecific sensor port for use in analyte meters designed to detect and quantify analyte levels in a fluid sample along with methods of using the same. The present disclosure also provides compositions and methods for facilitating the correct insertion of a sensor into a corresponding analyte meter.