RU2549431C1 - Method for assessing erythrocyte membrane resistance to ischemia - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: measured are: erythrocyte sedimentation rate, total bilirubin, prostacyclin, erythrocyte aggregation, blood viscosity in microcirculatory vessels, carbamide, adhesion of thrombocytes, plasminogen and nitrites. The measured data are used to assess the erythrocyte membrane resistance by coefficient (K_ms). If K_ms is -0.1 or less, the erythrocyte membrane appears to be ischemic resistant, while K_ms of 0.0 or more shows the ischemic resistant membrane.

EFFECT: using declared method enables fast, accurate and objective assessment of the individual ischemic resistance of erythrocytes.

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Description

The present invention relates to medicine, namely to biochemistry and physiology, and can be used to assess the stability of the erythrocyte membrane in humans under normal conditions and with hypertension.

A known method for predicting the stability of the membranes of peripheral blood red blood cells during exacerbation of herpes virus infection in pregnant women. To implement this method in pregnant women in the erythrocyte membranes, the content of lysophosphotidylcholine and protein of the band 4.1 is determined. Using the data obtained, determine the value of the discriminant function (D) using the discriminant equation:

D = -6.790 × protein band 4.1 + 0.609 × the amount of lysophosphotidylcholine.

With a value of D equal to or less than 19.01, erythrocyte membrane instability is predicted (Method for predicting the stability of peripheral blood red blood cell membranes during exacerbation of herpes virus infection in pregnant women: Pat. 2409321 Russian Federation. Federation: A61B 10/00, G01N 33/50 / Lutsenko M.T., Andrievskaya I.A .; published on January 20, 2011).

The disadvantages of this method include the fact that it is intended to determine the stability of erythrocyte membranes only in pregnant women with normal and herpes virus infections and cannot be used for patients with hypertension. In addition to the disadvantages of this method include the duration of the determination, the use of expensive equipment and reagents.

The closest in technical essence to the proposed is a method for assessing the resistance of red blood cells to functional load, including determining biochemical parameters in the patient’s blood, the indicators of which are used to calculate the coefficient of resistance of red blood cells to ischemia (Method for assessing the resistance of red blood cells to functional load: Pat. 2371723 Ros. Federation: G01N 33/49, G01N 33/50 / Pivovarov Yu.I., Kuznetsova E.E., Gorokhova V.G., Koryakina L.B .; publ. 03.03.2008).

The known method is as follows: in the patient’s blood, the content of methemoglobin, membrane-bound hemoglobin, oxidized nucleotides and the total optical density of red blood cells before and after the functional test, which use short-term local ischemia, are determined. Then, the difference in the values of each indicator is determined after and before the functional test, after which the coefficient of resistance of red blood cells to ischemia (K) is calculated by the formula. By the value of the coefficient K less than "0", the resistance of red blood cells to ischemia is estimated to be high, from "0" to 0.1 - normal, above 0.1 - reduced.

The disadvantages of this method include the fact that it can only be used for patients with coronary heart disease. The disadvantages of this method include the fact that it is based on indicators that require special labor-intensive and expensive research methods.

The objective of the proposed technical solution is to develop a method for assessing the resistance of the erythrocyte membrane to ischemia (tissue hypoxia) in patients with hypertension.

The technical result of the proposed method is to increase the accuracy of the assessment by determining the coefficient of stability of the erythrocyte membrane according to the equation of canonical values, as well as simplifying the method through the use of biochemical parameters widely used in the clinic and the absence of the need for ischemic tests.

The technical result is achieved by the fact that the method for assessing the resistance of the erythrocyte membrane to ischemia involves taking a blood sample, determining its biochemical parameters and calculating the coefficient of resistance of the erythrocyte membrane by the formula.

The difference of the proposed method lies in the fact that they determine: ESR, fibrinogen, total bilirubin, prostacyclin, red blood cell aggregation, blood viscosity in the microcirculation vessels, urea, platelet adhesion, plasminogen and nitrite, after which the erythrocyte membrane stability is assessed by the coefficient calculated as canon calculated as value:

The difference of the method lies in the fact that the stability assessment of the erythrocyte membrane is determined by a coefficient calculated as a canonical value.

K _mind = 10.24-0.155 × ESR + 2.107 × Fg-0.087 × OB + 0.031 × PC-0.805 × AGRAr-1.185 × v20 + 3.33 × v50 + 0.378 × Mch-2.92 × v100-0.135 × ADGtr -0.059 × Pg-0.355 × Ηt, where:

K _mind - the coefficient of stability of the membrane of red blood cells;

ESR - erythrocyte sedimentation rate, mm / h;

Fg - fibrinogen, g / l;

OB - total bilirubin, µmol / l;

PC - prostacyclin,%;

AGRer - red blood cell aggregation,%;

v20, v50, v100 - blood viscosity in vessels with a diameter of 20, 50, 100 microns, MPa · s ^-1 ;

Mch - urea, mmol / l;

ADHtr - platelet adhesion,%;

Pg - plasminogen,%;

NT - nitrites, µmol / l.

The authors of the proposed method found that when the value of K, the _{mind is} less than or equal to

-0.1 erythrocyte membrane in hypertensive patients evaluated unstable when the value of K is greater than or equal to _mind 0.0 membrane of erythrocytes in these patients is resistant to ischemia.

A comparative analysis with the prototype showed that the proposed method differs from the known above methods and, therefore, meets the criteria of the invention of "novelty."

From the analysis of patent and specialized literature it was found that the proposed method has features that distinguish it not only from the prototype, but also other technical solutions in this and related fields of medicine. In the available literature, the authors of the proposed technical solution have not identified a method for assessing the resistance of the erythrocyte membrane to ischemia in patients with hypertension with the above methods.

The differences of the proposed method from the known ones consist in the possibility of assessing the resistance of the erythrocyte membrane to ischemia without the use of special and time-consuming research methods. So, in the proposed method, biochemical, hemostasiological and hemorheological parameters of the erythrocyte membrane are widely used in the clinic. In addition, according to the claimed method, the assessment of the resistance of red blood cells to ischemia does not require an ischemic test, which simplifies the method and reduces the determination time.

Analysis of the results allowed the authors of the proposed method to determine the resistance of the erythrocyte membrane to ischemia and evaluate it as stable and unstable.

Clinical observations of the authors indicate that the use of the proposed technical solution allows us to evaluate the resistance of the erythrocyte membrane to ischemia in patients with hypertension. The authors showed that the value of K _mind can be used to quantify the individual characteristics of the resistance of cells (red blood cells) to ischemia (tissue hypoxia). The probability of error is 8.7%.

The above allows us to conclude that the technical solution meets the criterion of "inventive step".

The method comprising the claimed invention is intended for use in medicine, namely in biochemistry and physiology. The possibility of its implementation is confirmed by the examples and means described in the application, therefore, the proposed solution meets the criteria of the invention "industrial applicability".

The inventive method is as follows.

In the morning on an empty stomach, from the cubital vein, blood is drawn into a test tube containing 3.8% sodium citrate solution.

All biochemical blood parameters are determined in the initial state.

The erythrocyte sedimentation rate is determined in the capillary.

The fibrinogen level is determined by the photometric method on a photometer.

The concentration of total bilirubin is established by a direct method with a diazoreagent.

Plasma prostacyclin activity is evaluated indirectly - by the degree of reduction of platelet aggregation induced by adenosine diphosphate (ADP) in a sample enriched with platelets of plasma with the addition of plasma from the same patient, but "poor" in platelets.

Red blood cell aggregation is measured automatically in the microcapillary of the ESR analyzer (mm / h).

Determination of blood viscosity in the vessels of the microcirculation system of the appropriate caliber (20, 50 and 100 μm) is carried out using viscometry on a rheological analyzer.

Urea level is examined on a Bekman automated biochemical analyzer Synchron-9.

Platelet aggregation is determined on a two-channel laser platelet aggregation analyzer.

The level of plasminogen is evaluated on an automatic TSA coagulometer.

The concentration of nitrites in blood plasma is determined using the Griss reagent, i.e. by color intensity at a wavelength of 540 nm in relative units of optical density.

The obtained values are used in the following formula to determine the coefficient of resistance of the erythrocyte membrane to ischemia:

K _mind = 10.24-0.155 × ESR + 2.107 × Fg-0.087 × OB + 0.031 × PC-0.805 × AGRAr-1.185 × v20 + 3.33 × v50 + 0.378 × Mch-2.92 × v100-0.135 × ADGtr -0.059 × Pg-0.355 × Ηt, where:

K _mind - the coefficient of stability of the membrane of red blood cells;

ESR - erythrocyte sedimentation rate, mm / h;

Fg - fibrinogen, g / l;

OB - total bilirubin, µmol / l;

PC - prostacyclin,%;

AGRer - red blood cell aggregation,%;

v20, v50, v100 - blood viscosity in vessels with a diameter of 20, 50, 100 microns, MPa · s ^-1 ;

Mch - urea, mmol / l;

ADHtr - platelet adhesion,%;

Pg - plasminogen,%;

NT - nitrites, µmol / l.

When the value of K is less than or equal to _mind -0,1 erythrocyte membrane resistant to ischemia, at the value K is greater than or equal to _mind 0,0 erythrocyte membrane is stable.

The proposed method is illustrated by examples of specific performance.

Example 1. Patient C, medical history 23, diagnosis: hypertension 2 degrees.

The patient was identified biochemical and rheological parameters in the initial state.

ESR: 15.0 mm / h

Fibrinogen: 4.10 g / L

Total bilirubin: 12.0 μmol / L

Prostacyclin: 31.9%

AGRER: 6.60%

v20: 12.6 MPa s ^-1

v50: 9.3 MPa s ^-1

Urea: 3.9 mmol / L

v100: 7.9 MPa s ^-1

ADGtr: 9.9%

Plasminogen: 98.25%

Nitrite: 5.0 μmol / L

K _mind = 10.24-0.155 × 15.0 + 2.107 × 4.10-0.087 × 12.0 + 0.031 × 31.9-0.805 × 6.60-1.185 × 12.6 + 3.33 × 9.3 + 0.378 × 3.9-2.92 × 7.9-0.135 × 9.9-0.059 × 98.25-0.355 × 5.0 = -3.28

The calculated value of the erythrocyte membrane stability coefficient indicates that the erythrocyte membrane is unstable to ischemia.

The patient was recommended complex therapy with the appointment of drugs that affect the biochemical and rheological properties of the blood.

6 months after the course of treatment with the prescribed drugs, this patient underwent a second blood test:

ESR: 2.0 mm / h

Fibrinogen: 4.00 g / L

Total bilirubin: 10.0 μmol / L

Prostacyclin: 86.7%

AGRER: 4.00%

v20: 12.5 MPa s ^-1

v50: 9.2 MPa s ^-1

Urea: 3.9 mmol / L

v100: 7.6 MPa s ^-1

ADGtr: 8.0%

Plasminogen: 120.0%

Nitrite: 5.0 μmol / L

K _mind = 10.24-0.155 × 2.0 + 2.107 × 4.0-0.087 × 10.0 + 0.031 × 86.7-0.805 × 4.00-1.185 × 12.5 + 3.33 × 9.2 + 0.378 × 3.9-2.92 × 7.6-0.135 × 8.0-0.059 × 120.0-0.355 × 5.0 = 2.13

The value of K _mind , equal to 2.13, indicates an increase in the resistance of the erythrocyte membrane to ischemia.

Example 2. Donor K., is practically healthy. In the obtained blood samples, the studied parameters are determined.

ESR: 2.0 mm / h

Fibrinogen: 3.80 g / l

Total bilirubin: 17.4 μmol / L

Prostacyclin: 11.9%

AGRER: 0.16%

v20: 12.0 MPa s ^-1

v50: 9.3 MPa s ^-1

Urea: 5.4 mmol / L

v100: 7.6 MPa s ^-1

ADGtr: 8.7%

Plasminogen: 106.0%

Nitrite: 3.5 μmol / L

K _mind = 10.24-0.155 × 2.0 + 2.107 × 3.80-0.087 × 17.4 + 0.031 × 11.9-0.805 × 0.16-1.185 × 12.0 + 3.33 × 9.3 + 0.378 × 5.4-2.92 × 7.6-0.135 × 8.7-0.059 × 106.0-0.355 × 3.5 = 4.59

The value of K _mind , equal to 4.59, indicates the resistance of the erythrocyte membrane to ischemia.

46 patients with hypertension (GB) of the I-II stage, 1-2 degrees were examined. All patients were male. The diagnosis of GB was established according to the history and clinical and instrumental examination. Differential diagnosis to exclude symptomatic hypertension was carried out in accordance with the recommendations of the All-Russian Scientific Society of Cardiology (GFCF, 2008). The comparison group consisted of 22 clinically healthy men.

The total percentage of discrimination of groups of patients with a stable and unstable erythrocyte membrane was 91.3%, the probability of error was 8.7%.

Thus, the proposed method allows you to quickly, accurately and objectively assess the individual resistance of red blood cells to ischemia without the use of time-consuming techniques.

Claims (1)

A method for assessing the resistance of an erythrocyte membrane to ischemia, including determining biochemical parameters in the patient’s blood and calculating the erythrocyte resistance coefficient by the formula, characterized in that it is determined by ESR, fibrinogen, total bilirubin, prostacyclin, red blood cell aggregation, blood viscosity in microcirculation vessels, urea, adhesion platelets, plasminogen and nitrites, after which the stability of the erythrocyte membrane is assessed by a coefficient calculated as a canonical quantity:
K _mind = 10.24-0.155 × ESR + 2.107 × Fg-0.087 × OB + 0.031 × PC-0.805 × AGRAr-1.185 × v20 + 3.33 × v50 + 0.378 × Mch-2.92 × v100-0.135 × ADGtr -0.059 × PG-0.355 × NT,
Where:
K _mind - the coefficient of stability of the membrane of red blood cells;
ESR - erythrocyte sedimentation rate, mm / h;
Fg - fibrinogen, g / l;
OB - total bilirubin, µmol / l;
PC - prostacyclin,%;
AGRer - red blood cell aggregation,%;
v20, v50, v100 - blood viscosity in vessels with a diameter of 20, 50, 100 microns, MPa · s ^-1 ;
Mch - urea, mmol / l;
ADHtr - platelet adhesion,%;
Pg - plasminogen,%;
NT - nitrites, µmol / l,
and when the value of K is less than or equal to _mind -0,1 assess erythrocyte membrane unstable to ischemia, at the value K is greater than or equal to _mind 0.0 - stable.