The present disclosure relates to an optical fluorescence sensor comprising a probe for sensing glucose, an intra-reference probe, and a matrix. The present disclosure also relates to an optical fluorescence dual sensor comprising a probe for sensing glucose having two boronic acid moieties, a probe for sensing oxygen comprising modified porphyrin, an intra-reference probe that is rhodamine-based, and a matrix. The present disclosure additionally relates to methods of preparing these sensors and methods of using them.

Apparatus and methods are provided for analyzing a medical condition of a user. The apparatus may include a user interface configured to receive user identification information inputted by the user, an analyzer, and a processor all disposed within a common housing. The analyzer is configured to receive a biological specimen from the user and to analyze the biological specimen to generate analysis information. The processor is configured to store and forward the analysis information and to receive prescription information. The apparatus may include a communication unit configured to transmit the user identification information and the analysis information to a doctor at a remote location for review and to receive the prescription information from the doctor. The apparatus then may dispense the prescribed medication or print a medication prescription.

The present invention generally relates to the determination of an analyte concentration (quantitative determination) or whether an analyte threshold level has been passed (qualitative determination) in a biological sample through employment of a disposable analytical microprocessor device. The device can include a batch-specific, self-executable algorithm for the calculation of the analyte concentration.

Methods and devices to detect analyte in body fluid are provided. Embodiments include processing sampled data from analyte sensor, determining a single, fixed, normal sensitivity value associated with the analyte sensor, estimating a windowed offset value associated with the analyte sensor for each available sampled data cluster, computing a time varying offset based on the estimated windowed offset value, and applying the time varying offset and the determined normal sensitivity value to the processed sampled data to estimate an analyte level for the sensor.

Systems, techniques and methods for estimating the metabolic state or flux, e.g., the body energy state (BES) of a patient, are disclosed. The BES provides a deep insight into the nutritional needs of the patient, thus allowing for a sort of exquisite glycemic control with regard to the patient. The invention discloses systems and methods for estimating fractional gluconeogenesis. The invention also discloses systems and methods for estimating and targeting patient blood lactate concentration, both as a target itself and as an intermediate step to estimating and targeting patient fractional gluconeogenesis glucose production. Nutritional support methods and formulations are also disclosed. The invention is suitable for any sort of patient, including those who are injured, such as with traumatic brain injury, ill, or have other conditions that stress the metabolic system.

A method for detecting at least one analyte in at least one sample of a body fluid is disclosed. Therein, at least one test element (124) is used, the at least one test element (124) having at least one test field (162) with at least one test chemistry (154) is used, wherein the test chemistry (154) is adapted to perform at least one optically detectable detection reaction in the presence of the analyte. The method comprises acquiring an image sequence of images of the test field (162) by using at least one image detector (178). Each image comprises a plurality of pixels. The method further comprises detecting at least one characteristic feature of the test field (162) in the images of the image sequence. The method further comprises correcting a relative position change between the image detector (178) and the test field (162) in the image sequence by using the characteristic feature, thereby obtaining a sequence of corrected images.

The present invention generally relates to the determination of an analyte concentration (quantitative determination) or whether an analyte threshold level has been passed (qualitative determination) in a biological sample through employment of a disposable analytical microprocessor device. The device can include a batch-specific, self-executable algorithm for the calculation of the analyte concentration.

The invention provides monoclonal antibody 3H6 and related antibodies. The 3H6 antibody binds to an epitope within residues 28-36 of IAPP. The antibodies of the invention are useful, for example, for treating disorders associated with IAPP accumulation, particularly accumulation of IAPP deposits. Such disorders include type 2 diabetes, metabolic syndrome, impaired insulin tolerance, impaired glucose tolerance, insulinomas, and related conditions.

A handheld medical device is configured to illuminate a test strip inserted therein and may include a housing having a port configured to receive a test strip. A circuit board may be mounted inside the housing. A measurement module may be mounted to the circuit board and may be cooperatively operable with the test strip inserted into the port to measure a sample of fluid residing on the test strip. The circuit board faces an opposing top surface of the test strip inserted into the port. A light source may be mounted on the circuit board and operable to emit light substantially perpendicular to the opposing top surface of the test strip inserted into the port. The light source may project the light along an optical axis substantially perpendicular to the opposing top surface of the test strip and illuminate an area surrounding a dosing end of the test strip.

Systems, techniques and methods for estimating the metabolic state or flux, e.g., the body energy state (BES) of a patient, are disclosed. The BES provides a deep insight into the nutritional needs of the patient, thus allowing for a sort of exquisite glycemic control with regard to the patient. The invention discloses systems and methods for estimating fractional gluconeogenesis. The invention also discloses systems and methods for estimating and targeting patient blood lactate concentration, both as a target itself and as an intermediate step to estimating and targeting patient fractional gluconeogenesis glucose production. Nutritional support methods and formulations are also disclosed. The invention is suitable for any sort of patient, including those who are injured, such as with traumatic brain injury, ill, or have other conditions that stress the metabolic system.