Method for multistep quantitatively detecting serum albumin and metaglobulin in plasma

A technology for serum albumin and fibrinogen, applied in the field of stepwise quantitative detection of serum albumin and fibrinogen in plasma, and stepwise light-up quantitative detection of serum albumin and fibrinogen in plasma, can solve the problem It really achieves the elimination of the detection purpose of separation and purification, and achieves the effect of strong specific response and simple and convenient operation

Inactive Publication Date: 2016-07-20
BEIJING INSTITUTE OF TECHNOLOGYGY
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Problems solved by technology

The acquisition of serum requires blood to undergo a series of complex chemical purifications, which cannot be accomplished in ordinary hospitals, small clinics, or under the conditions of lack of medical equipment, and cannot truly achieve the simple detection purpose that does not require separation and purification.
In addition, the main difference between serum and plasma is that serum does not contain fibrinogen, and fibrinogen plays an irreplaceable role in plasma as a hemostatic protein. While accurately detecting serum albumin content in situ in plasma with fluorescent reagents, research serum The interaction between albumin and fibrinogen has not been reported in the literature

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  • Method for multistep quantitatively detecting serum albumin and metaglobulin in plasma
  • Method for multistep quantitatively detecting serum albumin and metaglobulin in plasma
  • Method for multistep quantitatively detecting serum albumin and metaglobulin in plasma

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Embodiment 1

[0054] A method for stepwise quantitative detection of serum albumin and fibrinogen in plasma, the specific steps of the method are as follows:

[0055] Step 1: Detect the fluorescence response of DP-TPPNa to plasma, as follows:

[0056] (1) Dissolve 19.35 μg of DP-TPPNa in 3 mL of LPBS to obtain a concentration of DP-TPPNa of 1×10 -5 mol / L solution a;

[0057] (2) Centrifuge the normal human blood sample at a speed of 3000rpm for 15 minutes, and take the upper layer of yellow liquid to obtain plasma;

[0058] (3) adopt fluorescence spectrophotometer to detect the initial fluorescence intensity I of DP-TPPNa solution 0 ;

[0059] (4) Get 36 μ L of plasma and add it dropwise in solution a in batches, and measure the fluorescence intensity I of DP-TPPNa in solution a after mixing uniformly after each drop of plasma j ; The amount of plasma added each time is 3 μL;

[0060] (5) draw DP-TPPNa fluorescence intensity change rate (I) according to test result in step (3) and (4) ...

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Abstract

The invention discloses a method for multistep quantitatively detecting serum albumin and metaglobulin in plasma, belonging to the field of bioluminescence marking. The method comprises the following steps: adding fluorescent reagents in different serum albumin concentrations into the fluorescent reagent at several times and measuring DP-TPPNa fluorescence intensity after dropwise adding each time; acquiring the optimal concentration and the detection scope of DP-TPPNa for serum albumin according to a measuring result; dropwise adding the serum albumin and metaglobulin in different mass ratios into the fluorescent reagent at several times and measuring DP-TPPNa fluorescence intensity after dropwise adding each time; drawing a change curve of change rate of DP-TPPNa fluorescence intensity following the concentration of serum albumin according to the measuring result; selecting a standard curve according to the change curve; adding a plasma sample into the fluorescent reagent, measuring the DP-TPPNa fluorescence intensity, substituting into a linear equation of the standard curve and calculating the concentration of the serum albumin and metaglobulin.

Description

technical field [0001] The invention relates to a stepwise method for quantitatively detecting serum albumin and fibrinogen in plasma, in particular to a stepwise light-up method for quantitatively detecting serum albumin and fibrinogen in plasma, which belongs to the field of bioluminescence labeling. Background technique [0002] As a major protein in human plasma, serum albumin accounts for 50% of the total plasma protein. For a normal person, 10-15 grams of serum albumin is synthesized in the liver every day, and 40% of the serum albumin is released into blood vessels through the exchange of blood and interstitium. Serum albumin contains a polypeptide chain with 585 amino acid residues, a tryptophan residue, and a cysteine ​​sulfhydryl free radical, and its half-life in plasma is 15-19 days. Its secondary structure consists of three domains, each containing two subdomains. Three 2D domains form a heart shape, and slight pH changes reveal the flexibility of the central ...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): G01N33/68
CPCG01N33/68G01N2333/75G01N2333/765
Inventor 董宇平陈笛笛李汪洋董立超佟斌石建兵
Owner BEIJING INSTITUTE OF TECHNOLOGYGY
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