Abstract: Embodiments of the present invention are directed to harvesting a target material from a suspension using a tube and float system. A suspension suspected of containing a target material is combined with a solution having one or more labels that distinguish the target material from other materials in the suspension. The tube, float, and suspension are centrifuged to separate various materials in the suspension according to associated specific gravities. The float expands the axial length of the target material layer and displaces the target material to a narrow space between the float and the inner wall of the tube. The space is illuminated with light that causes the labels to emit light identifying the location of the target material within the tube. One or more openings can then be formed in the tube at or near the point where the target material is located and the target material harvested.

Abstract: A container for holding a biologic fluid sample for analysis is provided which includes a chamber and a label. The chamber includes a first wall, a transparent second wall, and a plurality of features including features spatially located within the chamber. The transparent second wall permits a fluid sample quiescently residing within the chamber to be imaged through the second wall. The plurality of features, including those spatially located within the chamber, are operable to enable the analysis of the biologic fluid. The label directly or indirectly contains information regarding the features and the spatial location of the features within the chamber. The sample is analyzed by an analytical device that utilizes the information communicated through the label.

Abstract: A method for analyzing a blood sample is provided that includes the steps of: providing a blood sample having one or more of each first and second constituents; admixing a colorant with the sample, which colorant is operative to cause the first constituents and second constituents to fluoresce and absorb light; illuminating at least a portion of the sample; e) imaging a portion of the sample; determining a fluorescence value for each the first constituents and second constituents; determining an optical density value for each of the first constituents and second constituents; and identifying the first constituents and the second constituents using the determined fluorescence and optical density values.

Abstract: A method for determining the hematocrit of a blood sample is provided that includes the steps of 1) depositing the sample into an analysis chamber adapted to quiescently hold the sample for analysis; 2) imaging at least a portion of the quiescent sample, which sample portion contains the red blood cells and one or more lacunae to determine an optical density of the imaged portion of the sample on a per image unit basis; 3) selecting optical density values of the image units aligned with the red blood cells; 4) selecting optical density values of the image units aligned with the one or more lacunae; and 5) determining the hematocrit of the sample using the selected optical density values of the image units aligned with the red blood cells and the lacunae.

Abstract: A method for determining the area of an analysis chamber covered by a biologic fluid sample quiescently residing within the chamber is provided. The chamber has a first panel with an interior surface, and a second panel with an interior surface, both of which panels are transparent.

Abstract: Detection and characterization of immunologically detected substances are performed electronically on human and animal biological fluids such as whole blood, serum, plasma, urine, milk, pleural and peritoneal fluids, and semen, which fluids are contained in a thin chamber forming a quiescent fluid sample, which chamber has at least two parallel planar walls, at least one of which is transparent.

Abstract: A method for enumerating platelets within a blood sample is provided. The method includes the steps of: 1) depositing the sample into a sample container having an analysis chamber adapted to quiescently hold the sample for analysis, and an amount of colorant that platelets absorb and which fluoresces upon exposure to one or more predetermined first wavelengths of light; 2) imaging at least a portion of the sample disposed in the analysis chamber, including producing image signals indicative of fluorescent emissions from the platelets illuminated by first wavelengths of light; 3) identifying the platelets using the image signals; and 4) enumerating individual platelets and clumped platelets within the sample using one or more of fluorescent emissions, area, shape, and granularity.

Abstract: A method and apparatus for identifying reticulocytes within a blood sample is provided.

Abstract: A method and apparatus for measuring antibody titers in a thin film sample in an automated system which does not require multiple dilutions. The system provides a simple method for creating an in-situ dilution within a sample analysis chamber without the use of any precision fluid-handling components, and further, to use the same principles to provide a wide range of sample dilutions within the chamber so as to obviate the need for additional dilution steps when dealing with samples possibly containing wide ranges of analyte concentrations.

Abstract: A method for analyzing a blood sample is provided that includes the steps of: providing a blood sample having one or more of each first and second constituents; admixing a colorant with the sample, which colorant is operative to cause the first constituents and second constituents to fluoresce and absorb light; illuminating at least a portion of the sample; e) imaging a portion of the sample; determining a fluorescence value for each the first constituents and second constituents; determining an optical density value for each of the first constituents and second constituents; and identifying the first constituents and the second constituents using the determined fluorescence and optical density values.

Abstract: A method for analyzing a blood sample residing within an analysis chamber, which sample has one or more first and second constituents, which constituents are different from one another. The method includes the steps of: a) imaging the sample containing the first and second constituents, which sample is mixed with a colorant that causes the first and second constituents to fluoresce upon exposure to light, and which colorant is also operative to absorb light, the imaging produces image signals representative of fluorescent emissions from the sample and optical density of the sample; b) determining one or more values representative of fluorescent emission from the first and second constituents; c) determining one or more values representative of optical density for the first and second constituents; and d) distinguishing the first constituents from the second constituents using the fluorescent emission representative values and the optical density representative values.

Abstract: A biological fluid analysis cartridge is provided. In certain embodiments, the cartridge includes a base plate extending between a sample handling portion and an analysis chamber portion. A handling upper panel is attached to the base plate within the sample handling portion. A collection port is at least partially formed with the handling upper panel. An initial channel and a secondary channel are formed between the handling upper panel and the base plate. The collection port and initial and secondary channels are in fluid communication with one another. A chamber upper panel is attached to the base plate within the analysis chamber portion. At least one analysis chamber is formed between the chamber upper panel and the base plate. The secondary channel and the analysis chamber are in fluid communication with one another.

Abstract: An apparatus for analyzing biologic fluid is provided that includes first and second planar members, and at least three separators. At least one of the first planar member and second planar member is transparent. The separators are disposed between the planar members, and each individually has a height. The separators collectively having a mean height, and separate the planar members to form a chamber having a height extending between the planar members. At least one of the first planar member, second planar member, or separators is sufficiently deformable when the first planar member and second planar member are drawn toward each other by capillary force from a biologic fluid quiescently residing within the chamber to cause the mean chamber height to be substantially equal to the mean height of the separators.

Abstract: A method and apparatus for determining the hematocrit of a blood sample disposed within an analysis chamber, the method comprising the steps of: a) imaging at least a portion of the sample that contains one or more red blood cells contacting the interior surfaces of the chamber and one or more areas void of red blood cells; b) determining a representative optical density value for a plurality of image units optically aligned with portions of the red blood cells that are in contact the interior surfaces, and assigning an optical density first boundary value to those image units; c) determining a representative optical density value of a plurality of image units optically aligned with the one or more regions of the sample devoid of red blood cells, and assigning a second optical density boundary value to those image units; and d) determining the hematocrit of the sample.

Abstract: A method and apparatus for measuring antibody titers in a thin film sample in an automated system which does not require multiple dilutions. The system provides a simple method for creating an in-situ dilution within a sample analysis chamber without the use of any precision fluid-handling components, and further, to use the same principles to provide a wide range of sample dilutions within the chamber so as to obviate the need for additional dilution steps when dealing with samples possibly containing wide ranges of analyte concentrations.

Abstract: A tube and float system for use in separation and axial expansion of the buffy coat includes a transparent or semi-transparent, flexible sample tube and a rigid separator float having a specific gravity intermediate that of red blood cells and plasma. The float includes a main body portion of reduced diameter to provide a clearance gap between the inner wall of the sample tube and the float. One or more protrusions on the main body portion serve to support the flexible tube. During centrifugation, the centrifugal force causes the diameter of the flexible tube to expand and permit density-based axial movement of the float in the tube. The float further includes a pressure relief system to alleviate pressure build up in the trapped red blood cell blood fraction below the float, thereby preventing red blood cells from being forced into the annular gap containing the buffy coat layers.

Abstract: A method for analyzing a blood sample residing within an analysis chamber, which sample has one or more first and second constituents, which constituents are different from one another. The method includes the steps of: a) imaging the sample containing the first and second constituents, which sample is mixed with a colorant that causes the first and second constituents to fluoresce upon exposure to light, and which colorant is also operative to absorb light, the imaging produces image signals representative of fluorescent emissions from the sample and optical density of the sample; b) determining one or more values representative of fluorescent emission from the first and second constituents; c) determining one or more values representative of optical density for the first and second constituents; and d) distinguishing the first constituents from the second constituents using the fluorescent emission representative values and the optical density representative values.

Abstract: A method for analyzing a blood sample is provided that includes the steps of: providing a blood sample having one or more of each first and second constituents; admixing a colorant with the sample, which colorant is operative to cause the first constituents and second constituents to fluoresce and absorb light; illuminating at least a portion of the sample; e) imaging a portion of the sample; determining a fluorescence value for each the first constituents and second constituents; determining an optical density value for each of the first constituents and second constituents; and identifying the first constituents and the second constituents using the determined fluorescence and optical density values.

Abstract: A method for enumerating platelets within a blood sample is provided. The method includes the steps of: 1) depositing the sample into a sample container having an analysis chamber adapted to quiescently hold the sample for analysis, and an amount of colorant that platelets absorb and which fluoresces upon exposure to one or more predetermined first wavelengths of light; 2) imaging at least a portion of the sample disposed in the analysis chamber, including producing image signals indicative of fluorescent emissions from the platelets illuminated by first wavelengths of light; 3) identifying the platelets using the image signals; and 4) enumerating individual platelets and clumped platelets within the sample using one or more of fluorescent emissions, area, shape, and granularity.

Abstract: A method and apparatus for focusing a device for imaging a biologic sample is provided. A method aspect includes the steps of: disposing lenslets within a biologic sample, which lenslets have a height and a refractive index, which refractive index is different from that of the sample, wherein one or both of the imaging device and the sample are relatively locatable so a focal position of the imaging device can be moved along the height of the lenslets; imaging a portion of the sample including lenslets using transmittance at one or more wavelengths; determining an average light transmittance intensity of the sample at the wavelengths; determining an average light transmittance intensity of a region of each lenslet at the wavelengths; and determining the focal position of the imaging device using the average light transmittance intensity of the sample and the average light transmittance intensity of the region of the lenslets.