Devices and methods are described for measuring formed blood component sedimentation rate. Some of the methods may use (1) centrifugal techniques for separating red blood cells from plasma and (2) video and/or still imaging capability. Both may be used alone or in combination to accelerate formed blood component sedimentation and to measure its rate. In one example, the method may advantageously enable rapid measurement of sedimentation rate using small blood sample volumes. Automated image analysis can be used to determine both sedimentation rate and hematocrit. Automated techniques may be used to compensate for effects of hematocrit on uncorrected sedimentation rate data.

The present disclosure provided a blood cell analyzer, a control device and a blood analysis method thereof. In the method, a first reagent is mixed with a sample to obtain a first testing sample, and then a second reagent is mixed with the first testing sample for a further reaction to get a second testing sample for basophil classification and/or HGB measurement. A blood sample may be tested in one reaction cell through time-division multiplexing technology to obtain four groups leukocytes classification result and HGB result by single detection channel. Thus, the structure of the analyzer may be greatly simplified on the premise of guaranteeing the performance of the analyzer, the size and cost of the analyzer may reduce and a performance-price ratio of the analyzer may increase.

The present disclosure provided a blood cell analyzer, a control device and a blood analysis method thereof. In the method, a first reagent is mixed with a sample to obtain a first testing sample, and then a second reagent is mixed with the first testing sample for a further reaction to get a second testing sample for basophil classification and/or HGB measurement. A blood sample may be tested in one reaction cell through time-division multiplexing technology to obtain four groups leukocytes classification result and HGB result by single detection channel. Thus, the structure of the analyzer may be greatly simplified on the premise of guaranteeing the performance of the analyzer, the size and cost of the analyzer may reduce and a performance-price ratio of the analyzer may increase.

Devices and methods are described for measuring formed blood component sedimentation rate. Some of the methods may use (1) centrifugal techniques for separating red blood cells from plasma and (2) video and/or still imaging capability. Both may be used alone or in combination to accelerate formed blood component sedimentation and to measure its rate. In one example, the method may advantageously enable rapid measurement of sedimentation rate using small blood sample volumes. Automated image analysis can be used to determine both sedimentation rate and hematocrit. Automated techniques may be used to compensate for effects of hematocrit on uncorrected sedimentation rate data.

A method and/or system can include processing a blood sample of a patient by degrading red blood cells of the blood sample using a lysing solution, quenching the degradation of the red blood cells after a threshold lysing time, centrifuging and aspirating the quenched solution to remove degraded red blood cell debris and concentrate white blood cells of the blood sample, and suspending the concentrated white blood cells in a buffer solution; within a threshold transfer time, deforming white blood cells, of the suspended white blood cells, within a microfluidic chip; and determining a probability that the patient is in an immune activation state based on images of the white blood cells acquired while deforming the white blood cells.

Instances of the present technology may include a method for operating a hematology analyzer. The method may include passing a control material through a hematology analyzer. The control material may include a first cell population and a second cell population. The method may also include determining a first cell population volume measurement and a second cell population volume measurement. A first value of a first cell population distribution width and a second value of a second cell population distribution width may be calculated. The method may include comparing the first value to a first reference range. The method may also include comparing the second value to a second reference range. Furthermore, the method may include classifying an operational status of the hematology analyzer based on the comparison of the first value to the first reference range and based on the comparison of the second value to the second reference range.

A microfluidic device (10) for full blood count includes a first measurement channel (11) and a second measurement channel (12) separated from the first measurement channel (11). The microfluidic device (10) furthermore includes a first inlet (13) for providing a whole blood sample to the first and second measurement channel (11, 12), a second inlet (14) for providing a lysis agent for white blood cell count in to the first channel (11), a third inlet (15) for providing a quench solution to the first channel (11), and a fourth inlet (16) for providing a lysis agent for hemoglobin measurement to the second channel (12). A method for forming such a microfluidic device (10) and a method for performing a full blood count test using such a microfluidic device (10) are described.

Disclosed is a sample analyzer for analyzing a sample, including: a preparing unit that mixes a sample, a surfactant-containing diluent, and a nucleic acid staining reagent to prepare a measurement specimen in which nucleic acids of nucleated cells are stained and red blood cells are hemolyzed; a detecting unit that irradiates particles included in the measurement specimen with light to receive scattered light and fluorescence light emitted from the particles and output a detection signal; and a processing unit that counts white blood cells and fungi in the sample based on the detection signal.

Disclosed are apparatus and methods for analyzing bodily fluids, such as blood samples, using an integrated hematology analyzer and flow cytometer system. Under the present approach, an integrated system may operate as a closed fluidic system or an open fluidic system, and may selectively perform automated hematologic protocols, flow cytometer protocols, and custom protocols. Such apparatus may, for example, identify and enumerate multiple cell types in whole blood based on cellular morphology, analyze cellular immunoassays using antibodies labeled to cells, and also detect low abundant analytes in whole blood as well as serum and other bodily fluids not attached to cells using bead-based immunoassay methods. The system may include a fluid handling system to control sample flow, an optical transducer that includes a flow cell, optical detectors for light scatter and/or fluorescence, and also an illumination source.

An apparatus for analyzing individual cell composition in a heterogeneous cell population may include, in one embodiment, a deposition plate having an array of microwells disposed therein, and a cover plate substantially overlying the deposition plate. A pair of electrodes may be associated with one or more of the microwells, and may be configured to generate an electric field within the associated microwell.