Abstract: A method and apparatus for determining hemoglobin concentration is provided. A method aspect includes the steps of: a) depositing an unlysed, substantially undiluted blood sample into an analysis chamber adapted to quiescently hold the sample for analysis; b) imaging the sample in a region of the analysis chamber where the height of the chamber is no more than about twenty microns (20?) or no less than about two microns (2?), to produce image signals representative of the optical density of the imaged region; c) determining a sample representative optical density value using the image signals representative of the optical density of the imaged region; and d) determining the hemoglobin concentration of the sample using the sample representative optical density value.

Abstract: A method and apparatus for determining hemoglobin concentration is provided. A method aspect includes the steps of: a) depositing an unlyzed, substantially undiluted blood sample into an analysis chamber adapted to quiescently hold the sample for analysis; b) imaging the sample in a region of the analysis chamber where the height of the chamber is no more than about twenty microns (20?) or no less than about two microns (2?), to produce image signals representative of the optical density of the imaged region; c) determining a sample representative optical density value using the image signals representative of the optical density of the imaged region; and d) determining the hemoglobin concentration of the sample using the sample representative optical density value.

Abstract: A method and apparatus for determining a cell volume of a red blood cell is provided. The method includes the steps of: a) depositing a sample into an analysis chamber, the chamber defined by an first panel interior surface, a second panel interior surface, and a known or determinable height, which height is such that at least one red blood cell subject to a sphering agent assumes a partially compressed spherical shape in contact with the interior surfaces; b) imaging the at least one partially compressed spherical red blood cell contacting the interior surfaces, and producing image signals; c) determining a radius of the partially compressed spherical red blood cell from the image signals; and d) determining a volume of the imaged red blood cell using the determined radius.

Abstract: A sensor that generates an output signal in response to a stimulus, where the output signal is generated with a predetermined relationship to one or more properties of the stimulus such that the one or more properties of the stimulus can be determined as a function of the output signal. In one embodiment, the sensor includes a component, a sensor processor, and a transmitter. The component deteriorates, thereby causing predictable fluctuations in the predetermined relationship between the output signal and the one or more properties of the stimulus. The sensor processor provides information related to the deterioration of the component. The transmitter wirelessly transmits the information provided by the processor.

Abstract: A sensor that generates an output signal in response to a stimulus, wherein the output signal is generated with a predetermined relationship to one or more properties of the stimulus such that the one or more properties of the stimulus can be determined as a function of the output signal. In one embodiment the sensor comprises a component, a sensor processor, and a transmitter. The component deteriorates, thereby causing predictable fluctuations in the predetermined relationship between the output signal and the one or more properties of the stimulus. The sensor processor provides information related to the deterioration of the component. The transmitter wirelessly transmits the information provided by the processor.

Abstract: A sensor that generates an output signal in response to a stimulus, where the output signal is generated with a predetermined relationship to one or more properties of the stimulus such that the one or more properties of the stimulus can be determined as a function of the output signal. In one embodiment, the sensor includes a component, a sensor processor, and a transmitter. The component deteriorates, thereby causing predictable fluctuations in the predetermined relationship between the output signal and the one or more properties of the stimulus. The sensor processor provides information related to the deterioration of the component. The transmitter wirelessly transmits the information provided by the processor.

Abstract: A component of a system configured to monitor one or more gaseous analytes. In one embodiment, the component comprises a conduit and a gas sensitive film. The conduit is formed to enable a flow of gas therethrough. The gas sensitive film is disposed in communication with the flow of gas, and is sensitive to one or more gaseous analytes within the flow of gas. In some instances, the film comprises a dye and a polymer matrix. The dye is sensitive to the one or more gaseous analytes. The polymer matrix carries the dye, is porous, and is formed such that the film has (i) a dynamic range of at least from about 20% to about 90% concentration of the one or more gaseous analytes, and (ii) a response time over at least a portion of the dynamic range of less than about 80 milliseconds.

Abstract: A method and apparatus for determining a cell volume of a red blood cell is provided. The method includes the steps of: a) depositing a sample into an analysis chamber, the chamber defined by an first panel interior surface, a second panel interior surface, and a known or determinable height, which height is such that at least one red blood cell subject to a sphering agent assumes a partially compressed spherical shape in contact with the interior surfaces; b) imaging the at least one partially compressed spherical red blood cell contacting the interior surfaces, and producing image signals; c) determining a radius of the partially compressed spherical red blood cell from the image signals; and d) determining a volume of the imaged red blood cell using the determined radius.

Abstract: A system configured to determine information related to one or more gaseous analytes in a body of gas comprises a luminescable material, one or more emitters, one or more photosensitive detectors, and a processor. The emitters emit amplitude modulated electromagnetic radiation onto the luminescable medium in communication with a body of gas causing luminescence in the luminescable medium. The photosensitive detectors receive the amplitude modulated electromagnetic radiation generated by the luminescence of the luminescable medium and generate one or more output signals, at least one of the output signals indicating the intensity of the received electromagnetic radiation. The processor receives the output signals and determines information related to one or more gaseous analytes in the body of gas. The determination of information related to the one or more gaseous analytes may comprise compensating for a delay that varies as a function of the intensity of the received electromagnetic radiation.

Abstract: A sensor that generates an output signal in response to a stimulus, wherein the output signal is generated with a predetermined relationship to one or more properties of the stimulus such that the one or more properties of the stimulus can be determined as a function of the output signal. In one embodiment the sensor comprises a component, a sensor processor, and a transmitter. The component deteriorates, thereby causing predictable fluctuations in the predetermined relationship between the output signal and the one or more properties of the stimulus. The sensor processor provides information related to the deterioration of the component. The transmitter wirelessly transmits the information provided by the processor.

Abstract: A system configured to determine information related to one or more gaseous analytes in a body of gas comprises a luminescable material, one or more emitters, one or more photosensitive detectors, and a processor. The emitters emit amplitude modulated electromagnetic radiation onto the luminescable medium in communication with a body of gas causing luminescence in the luminescable medium. The photosensitive detectors receive the amplitude modulated electromagnetic radiation generated by the luminescence of the luminescable medium and generate one or more output signals, at least one of the output signals indicating the intensity of the received electromagnetic radiation. The processor receives the output signals and determines information related to one or more gaseous analytes in the body of gas. The determination of information related to the one or more gaseous analytes may comprise compensating for a delay that varies as a function of the intensity of the received electromagnetic radiation.