The embodiments disclose an apparatus including a test cartridge configured for inserting into a reader, a sample insertion component coupled to the test cartridge a test sample, a heater device coupled to the test cartridge configured to heat to a predetermined temperature the test sample, a sensor array coupled to the test cartridge consisting of at least one electrochemical sensor for sensing analytes in a sample, a reader configured to gather test related data from the sensor array coupled to the test cartridge, an analyzer coupled to the reader configured for determining test results of each sensor in the sensor array and comparing all the test results for confirmation of a valid test and coherent results, a MCU (Microcontroller Unit) to perform main control and processing functions, and orchestrates all the functionality for the Reader, and a BLE Radio RF link between the MCU and an external processing system.

A biosensor system, method and apparatus are provided for implementing threshold based correction functions for biosensors. A primary measurement of an analyte value is obtained. A secondary measurement of a secondary effect is obtained and is compared with a threshold value. A correction function is identified responsive to the compared values. The correction function is applied to the primary measurement of the analyte value to provide a corrected analyte value. The correction method uses correction curves that are provided to correct for an interference effect. The correction curves can be linear or non-linear. The correction method provides different correction functions above and below the threshold value. The correction functions may be dependent or independent of the primary measurement that is being corrected. The correction functions may be either linear or nonlinear.

A test sensor for determining an analyte concertation in a biological fluid comprises a strip including a fluid receiving area and port-insertion region. A first row of optically transparent and non-transparent positions forms a calibration code pattern disposed within a first area of the port-insertion region. A second row of optically transparent and non-transparent positions forms a synchronization code pattern disposed within a second area of the port-insertion region. The second area is different from the first area. The synchronization code pattern corresponds to the calibration code pattern such that the synchronization code pattern provides synchronization of the serial calibration code pattern during insertion of the port-insertion region into the receiving port of the analyte meter.

A method and system for determining a failsafe value for a biosensor having two perimeter electrodes, a distal electrode, and a proximal electrode are disclosed. A liquid measuring medium is applied to a capillary channel of the biosensor. The method includes applying an alternating voltage to the perimeter electrode and the proximal electrode, measuring conductivity to determine a first impedance between the perimeter electrode and the proximal electrode, applying the alternating voltage to the perimeter electrode and the distal electrode, measuring conductivity to determine a second impedance between the perimeter electrode and the distal electrode, determining a value using the first impedance and the second impedance, and providing an error message to the user if the value is out of tolerance. If the value is out of tolerance, then defects or breaks in the electrodes and/or reagent in a reaction area are present and the method disallows the test result.

A fluid ejection controller interface includes input logic to receive control data packets and a first clock signal, each control data packet including a set of primitive data bits and a set of random bits, wherein the input logic identifies the random bits in the received control data packets to facilitate the creation of modified control data packets. The fluid ejection controller interface includes a clock signal generator to generate a second clock signal that is different than the first clock signal, and output logic to receive the modified control data packets, and output the modified control data packets to a fluid ejection controller of a fluid ejection device based on the second clock signal.

An electrochemical detection system is configured to detect a sample. The electrochemical detection system includes an electrochemical test strip and a measuring instrument. The electrochemical test strip includes a main body and at least one electrode group. The measuring instrument is electrically connected to the at least one electrode group. The measuring instrument is adapted to determine whether a flow field condition of the sample is normal via the at least one electrode group.

This document discusses, among other things, systems and methods to compensate for the effects of temperature on sensors, such as analyte sensor. An example method may include determining a temperature-compensated glucose concentration level by receiving a temperature signal indicative of a temperature parameter of an external component, receiving a glucose signal indicative of an in vivo glucose concentration level, and determining a compensated glucose concentration level based on the glucose signal, the temperature signal, and a delay parameter.

The present disclosure provides a system for measuring a property of a sample comprising: a test strip for collecting the sample; a diagnostic measuring device configured to receive the test strip and measure a concentration of an analyte in the sample received on the test strip; and the diagnostic measuring device further comprising a processor programmed to execute an analyte correction for correcting a measurement of the sample due to one or more interferents, comprising: calculating an interferent impedance measurement including a magnitude measurement and a phase measurement using a difference identity to generate a sinusoidal signal with an amplitude proportional to the phase difference; and adjusting the measurement of the analyte in the sample using that the calculated interferent impedance measurement.

Using a biosensor including a flow path into which blood containing a target is introduced, an upstream electrode pair disposed in the flow path and having a reagent reacting with the target disposed on either of the electrodes, and a downstream electrode pair disposed at a downstream side of the flow path; the method includes a first detection step of detecting a first introduction of blood as far as the upstream electrode pair; a second detection step of detecting a second introduction of blood as far as the downstream electrode pair; a time measurement step of measuring a time difference from the first introduction to the second introduction; and a measurement step of acquiring the value related to the target based on the time difference by using any two electrodes among the upstream and downstream electrode pair after the second introduction is detected.

A method for determining contamination of a biosensor in which the biosensor is loaded into a test meter and a sample is then applied. First and second predetermined test voltages are applied between spaced electrodes of the biosensor for respective first and second predetermined time intervals. First and second current values are measured during the respective first and second predetermined time intervals. Reference values are determined based on the measured first and second current values. Based on one or more of the reference values, a determination of contamination is made. Reporting of the analyte concentration of the sample can be suppressed based on the determination.