The present invention provides for systems and methods for inhaled CO therapy to prevent, attenuate, or delay processes that accelerate the loss of organ or tissue function, thereby increasing the lifespan of transplanted organs or tissues, or slowing the decline of native organs or tissues, or delaying the need for replacement of diseased native organs with organ transplants. Such biological processes that are prevented, attenuated, or delayed include chronic persistent inflammation, fibrosis, scarring, as well as immunologic or autoimmune attack.

A stool resuspension solution comprising a hemoglobin stabilization reagent is provided. In some embodiments, the hemoglobin stabilization reagent may be an osmolyte, a polyvalent cation, a sugar or polysaccharide and, optionally, a polyvalent cation, a protoporphyrin, or an HRP stabilization component and, optionally, a polyvalent cation. A method of stabilizing hemoglobin in a stool sample in the solution is also provided, as well as a sample collection device containing the solution.

The present disclosure provides in vitro methods for identifying the presence or absence of haemoglobin S (HbS) or haemoglobin C (HbC) in a blood sample, kits and devices thereof. The inventors have found that HbS shows a substantial decrease in absorption under deoxygenated conditions compared to oxygenated conditions. The inventors expect HbC to show a similar decrease in absorption under deoxygenated conditions compared to oxygenated conditions. The methods, kits and devices of the disclosure employ this decrease in absorption under deoxygenated conditions to identify the presence or absence of HbS or HbC in a blood sample. The methods, kits and devices of the present disclosure are simple, low cost, and provide a rapid way to identify the presence or absence of HbS or HbC in a blood sample in a point-of-care setting.

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.

The present invention provides for systems and methods for inhaled CO therapy to prevent, attenuate, or delay processes that accelerate the loss of organ or tissue function, thereby increasing the lifespan of transplanted organs or tissues, or slowing the decline of native organs or tissues, or delaying the need for replacement of diseased native organs with organ transplants. Such biological processes that are prevented, attenuated, or delayed include chronic persistent inflammation, fibrosis, scarring, as well as immunologic or autoimmune attack.

A method for counting blood cells in a sample of whole blood. The method comprises the steps of: (a) providing a sample of whole blood; (b) depositing the sample of whole blood onto a slide, e.g., a microscope slide; (c) employing a spreader to create a blood smear; (d) allowing the blood smear to dry on the slide; (e) measuring absorption or reflectance of light attributable to the hemoglobin in the red blood cells in the blood smear on the slide; (f) recording a magnified two-dimensional digital image of the area of analysis identified by the measurement in step (e) as being of suitable thickness for analysis; and (g) collecting, analyzing, and storing data from the magnified two-dimensional digital image.
Optionally, steps of fixing and staining of blood cells on the slide can be employed in the method.

This invention provides an amadoriase that acts on the β-chain of hemoglobin A1c (HbA1c) and generates hydrogen peroxide, a method for measurement of HbA1c using such amadoriase, and a reagent kit for measurement of HbA1c using such amadoriase. The method for measurement of HbA1c involves the use of an amadoriase that has specific activity of 0.1 U/mg or greater to αF6P and oxidizes the HbA1c β-chain amino terminus so as to generate hydrogen peroxide, and the reagent kit for measurement of HbA1c comprises such amadoriase. The method and the kit for measurement of HbA1c enable quantification of HbA1c to be performed rapidly, simply, and accurately.

The present disclosure relates to methods of detecting various analytes, including glycated hemoglobin (HbA1c) and total hemoglobin (THb), in a biological sample obtained with a microsampling device.

In one aspect, a sensor for detecting hemoglobin protein (e.g., human hemoglobin protein) in a sample is disclosed, which includes a graphene layer, a plurality of binding agents coupled to said graphene layer to generate a functionalized graphene layer, where the binding agents exhibit specific binding to a hemoglobin protein (e.g., to human hemoglobin protein) and a plurality of electrical conductors electrically coupled to said functionalized graphene layer for measuring an electrical property (e.g., DC electrical resistance) of said functionalized graphene layer. While in some embodiments such binding agents are monoclonal antibodies, in other embodiments they can be polyclonal antibodies.