RU2694538C1 - Diagnostic technique for early and late stages of lipidemia - Google Patents

Abstract

FIELD: diagnostics methods; satisfaction of human vital needs.

SUBSTANCE: present invention relates to a method for diagnosing early and late stages of lipidemia by analysing laboratory blood lipid analysis results before treating lipidemia with subsequent determination of atherogenicity coefficient. Method differs by the fact that additionally the relation (TCS+TAG)/CS of HDL cholesterol is determined, and if this ratio is increased to 4.1–4.8 standard units, the early stage of lipidemia is diagnosed, and if the said ratio is increased to 4.9 and more, a late stage of lipidemia.

EFFECT: high accuracy of diagnosing early and late stages of lipidemia using a simple method, which does not require high material costs.

1 cl, 1 tbl, 2 ex

Description

The invention relates to medicine and can be used in cardiology and therapy.

Known methods for the diagnosis of lipidemia in atherosclerosis by calculating the coefficient characterizing the ratio of cholesterol (cholesterol) low-density lipoproteins to cholesterol high-density lipoprotein (HDL), namely LDL / HDL cholesterol. Also known coefficient characterizing the ratio of total cholesterol (total cholesterol) to HDL cholesterol, namely cholesterol cholesterol cholesterol and cholesterol. Both coefficients are recommended by Eurolab for diagnosing the risk of coronary heart disease (CHD) against the background of progressive dyslipoproteinemia (DLP) of atherogenic genesis and complications of its course. “Dyslipoproteinemia markers: diagnosis of atherosclerosis” - Eurolab (http://www.eurolab.md/algoritms/markery-dislipoproteinemii-diagnostika-ateroskleroza/). There is also known a method for the diagnosis of lipidemia in atherosclerosis by calculating the atherogenic coefficient according to the method of A.N. Klimov (1999), which is described by the formula: (cholesterol-cholesterol-cholesterol-free cholesterol-cholesterol-cholesterol-free cholesterol-free cholesterol-free cholesterol-free cholesterol-free cholesterol-free cholesterol-free cholesterol-free cholesterol-free cholesterol-free Published September 15, 2008).

In the clinical diagnostic practice, the study of the coefficients characterizing the LDL / HD cholesterol ratio of HDL with normal up to 3.4 conventional units, as well as the ratio of cholesterol cholesterol / cholesterol HDL with normal up to 3.8 conventional units and the ratio (cholesterol-cholesterol HDL) / cholesterol is used. HDL with a norm equal to 2.0-3.0 conventional units. The latter coefficient is widely used in clinical practice to assess the risk of developing an atherosclerotic process and is known as the atherogenic coefficient. So, if the atherogenic coefficient increases to 3.1-3.5, it is according to the literature data that characterizes the possibility of an early risk of atherosclerosis. An increase in coefficient values within the range of 3.5-4.0 characterizes a moderate degree of risk of developing atherosclerotic process, and an increase in this coefficient to 4.0 or more characterizes a high risk of atherosclerosis in clinical and laboratory studies known in the literature. In addition, at high risk of developing atherosclerosis, the appearance of modified lipoproteins of all classes is possible, which significantly aggravates the course of the atherosclerotic process at any stage of the disease.

The coefficients are known with which atherogenicity is estimated. These are the relations widely used in clinical practice: 1) LDL cholesterol / HDL cholesterol; 2) HCP / cholesterol HDL (http://holesterin.guru/analizy/koeffitsent-aterogennosti/) and 3) (cholesterol cholesterol-HDL cholesterol) / HDL cholesterol (AN Klimov, N.G. Nikulcheva. Lipids, liproteins and atherosclerosis - Peterpress, 1995 pp. 98-102; Metelskaya V.A., Perova N.V. "Modern principles of diagnosis and correction of atherogenic dyslipoproteinemia. Cardiology. Published 15.09.2008).

However, sometimes there is a discrepancy between the low values of these indicators within the normal range and severe severity of the atherosclerotic process, identified using clinical and instrumental methods for examining patients, which makes it necessary to develop fundamentally new coefficients for calculating atherogenicity.

As a prototype, the closest to the proposed by the technical nature and the achieved result of the method selected atherogenic factor (cholesterol-HDL-C) / HDL-C (A. Klimov, 1999).

At the same time, this prototype coefficient does not always allow revealing lipidemia in the presence of coronary atherosclerosis against the background of a significantly altered lipidogram of atherogenic genesis. This is due to the fact that in a number of patients with ischemic heart disease, not only the level of total cholesterol (cholesterol) and “atherogenic” lipoproteins, such as LDL, but also the concentration of “atherogenic” lipoproteins, HDL, is sharply increased. A significant increase in HDL with the progression of coronary atherosclerosis is a protective reaction of the body, but such a protective reaction is pronounced rarely. Therefore, only a small contingent of patients with atherosclerosis with prolonged progression of the disease, the atherogenic coefficient (cholesterol-cholesterol-HDL-C) / HDL-C even at the age of 60-75 years remains within normal values, that is, 2.0-3.0, although according to the results of clinical - instrumental studies in these patients with IHD develop a high risk of complications of the course of thrombogenic complications. Therefore, in order to timely clarify the diagnosis of lipidemia, it is necessary to develop a new criterion for diagnosing lipidemia to the already existing coefficients, allowing to clarify the presumptive diagnosis of lipidemia, or establish a clinical and laboratory diagnosis of lipidemia for the first time. In addition, according to Fredrickson's classification IIa, the type of dyslipoproteinemia (DLP) is much less common than type IIb, characterized by a simultaneous increase in the blood of IHD patients like total cholesterol, LDL cholesterol, VLDL, and triacylglycerol (TAG). According to the method of the prototype, this indicator characterizing the growth in the blood of total lipids is not taken into account. Therefore, in patients with coronary artery disease IIb type DLP in some cases, laboratory diagnosis of lipidemia remains ineffective, making it difficult to make a clinical diagnosis of lipidemia.

The aim of the invention is to improve the accuracy and efficiency of diagnosis of lipidemia.

This goal is achieved by predicting the atherogenic coefficient with an additional definition of the ratio (OHS + TAG) / HDL cholesterol and with an increase in this ratio to 4.1–4.8 conventional units, an early stage of lipidemia is diagnosed, and with an increase in the above ratio to 4.9 or more diagnosed with late stage lipidemia. Therefore, only a comprehensive modernization of the prototype method allows to obtain the desired result.

Each newly introduced into the claims feature performs the function of improving the accuracy and efficiency of the method. The introduction of the level of TAG into the calculation formula of the atherogenic coefficient allows maximizing the information content, accuracy and reliability of diagnostics of early and late stages of lipidemia.

The study of lipids and lipoproteins of different classes in the diagnosis of lipidemia and ischemic heart disease (IHD) is recommended by the All-Russian Scientific Society of Cardiology according to the provision of the European Atherosclerosis Society recommendations - "Diagnosis and correction of lipid metabolism disorders for the prevention and treatment of atherosclerosis" (Moscow, 2005 g .: Clinical laboratory diagnostics, No. 10, 2008, p. 21-32).

Currently promising are studies of lipids, lipoproteins and analysis of their ratio.

It is known that the leading risk factor for atherosclerosis is dysliporotinemia (DLP) of atherogenic genesis, indicating a genetic predisposition to cardiovascular diseases. Currently, special attention is paid to the study of blood lipids: cholesterol (cholesterol) and triacylglycerol (TAG), and the study of the composition of blood lipoproteins, namely very low density lipoproteins (VLDL), low density lipoproteins (LDL), high density lipoproteins (HDL) ) and their constituent MS. Currently, the ratio of “harmful” or “atherogenic” cholesterol to “good” or “anti-atherogenic” cholesterol is being studied. Particular attention is paid not so much to the study of the concentration of total blood cholesterol, as its distribution between lipoprotein fractions, since cholesterol itself is necessary for normal functioning of the body. With his participation, membranes of cells and tissues, hormones of a steroid nature are synthesized. That is, without cholesterol, the human body cannot grow, develop, multiply and function. Transport of lipids from the intestine also occurs with the participation of cholesterol. Since cholesterol is hydrophobic, it can be transported in the blood only as part of lipoproteins (LP) of different classes in combination with apoproteins and phospholipids. Therefore, in the blood there are simultaneously LDL, VLDL and HDL in different ratios, and the most atherogenic are modified LP of different classes.

The ratio between "atherogenic" and "anti-atherogenic" lipoproteins can be assessed using various factors. For this purpose, the ratio of cholesterol-free cholesterol / HDL cholesterol is determined, however, this coefficient is often evaluated in conjunction with other indicators, such as C-reactive protein (PSA) to assess the severity of the inflammatory response in atherosclerosis and the risk of thrombogenic complications. In addition, the ratio between “atherogenic” and “anti-atherogenic” PL is estimated by calculating the LDL / HDL-C LDL-C coefficient, but the atherogenic coefficient proposed in 1999 is most widely studied in clinical practice. Klimov, namely (cholesterol-cholesterol HDL) / cholesterol-free cholesterol, expressed in arbitrary units and equal in the norm of 2.0-3.0.

So, all three above atherogenic factors: LDL cholesterol / HDL cholesterol; LPVP / cholesterol cholesterol and cholesterol cholesterol (cholesterol cholesterol-cholesterol-cholesterol-cholesterol-cholesterol-free cholesterol-free cholesterol-free cholesterol-free cholesterol-free cholesterol-free cholesterol-free cholesterol-free cholesterol-free cholesterol-free cholesterol-free cholesterol is characterized by the ratio of "atherogenic" lipids to "antiatherogenic" lipoproteins. Violation of this ratio is characterized by DLP atherogenic and most often type IIa according to Fredrickson's classification, characterized by a significant increase in blood cholesterol cholesterol and LDL cholesterol, and type II b DLP with simultaneous increases in blood cholesterol, LDL cholesterol, cholesterol LDL and TAG. Type III DLP is known as “floating” dis-β-lipoproteinemia with a high level of cholesterol cholesterol and LDL and VLDL, which occupies the entire area of β and pre-β-PL in electrophoretic studies of lipoproteins. In clinical practice, the most common type IIB DLP. The most severe manifestation of type IIB DLP is its combination with hypo-α-lipoproteinemia, that is, a low level of HDL cholesterol. This feature of the most common form of CHP in CHD is the complexity of interpreting the values of the atherogenic coefficient according to the prototype method: (OXC-HDL-C) / HDL-C, used as a prototype and recommended for use in clinical practice by the Eurolab Medical Portal. The boundaries of the population norm of lipid indices are established in the region. For blood cholesterol, the upper limit of the population standard is 6.5 mmol / l, and the lower limit of HDL cholesterol is 0.9 mmol / l. Therefore, the atherogenic index in the prototype method is normally 2.0-3.0. In the majority of patients with CHD, total cholesterol (cholesterol) varies from 5.0 to 7.0 mmol / l, rarely exceeding these values, and the HDL cholesterol level varies with IHD in the range of 0.7-1.4 mmol / l. Therefore, the atherogenic coefficient of the prototype in these patients exceeds 3.0. But there are patients with coronary artery disease and a combined atherosclerotic lesion of the aorta and main arteries, in which the total cholesterol is 6.5 mmol / l or more, but the HDL cholesterol level increases to 1.8 mmol / l. Consequently, the atherogenic index of the prototype is 2.6-3.0, that is, it conditionally characterizes the absence of the atherosclerotic process. At the same time, an x-ray examination in the aortic arch and large arteries revealed calcified atherosclerotic plaques characteristic of the late stage of the atherosclerotic process. This is also evidenced by the clinical picture of the disease: angina, FC II-III, as well as the phenomenon of cerebral circulation disorders.

Therefore, to clarify the diagnosis of DLP with lipidemia of atherogenic genesis, it is necessary to introduce into clinical laboratory practice an additional factor to the existing diagnostic criteria that fundamentally clarifies the presence of early and late stages of DLP atherogenic genesis, that is, a coefficient reliably characterizing the presence of a pronounced atherosclerotic process against the background of DLP atherogenic Genesis, namely the new atherogenic coefficient.

The proposed atherogenic coefficient is the ratio (OHS + TAG) / HDL cholesterol. This coefficient is the most reliable criterion for the presence of a pronounced atherosclerotic process against the background of the early and late stages of lipidemia of atherogenic genesis.

The introduction of the new proposed coefficient will most accurately determine the early and late stages of lipidemia as the disease progresses. Improving the method of diagnosing lipidemia relates to the development of a new proposed atherogenic coefficient, which allows, at the normal value of the atherogenic index of the prototype, to detect the early and late stages of DLP in clinical laboratory diagnostics.

The proposed atherogenic coefficient will allow to identify the optimal ratio of "atherogenic" and "antiatherogenic" lipid fractions of blood with the appropriate diagnostic conclusion, which in certain cases requires immediate correction of lipidemia. Consequently, the proposed ratio will allow diagnosing early and late lipidemia in coronary artery disease before the stage of significant changes in other clinical and laboratory parameters and improve the accuracy of diagnosis of early and late stages of the disease. In turn, such patients with IHD will be given early pathogenetically substantiated therapy. It is equally important to clarify the early and late stages of lipidemia to assess the effectiveness of the therapy of the disease and predict the course of lipidemia in ischemic heart disease. All this indicates the extreme importance of the introduction of the developed method for the diagnosis of lipidemia.

The essential features that characterize the invention, have shown in the inventive combination of new properties, which are obviously not arising from the prior art in this field and not obvious to a specialist.

Identical set of features not found in the study of patent and scientific and medical literature.

This invention can be used in practical health care to improve the accuracy of diagnosis of early and late stages of lipidemia in patients with coronary artery disease.

Thus, it is necessary to consider this technical solution to the relevant conditions of patentability: "Novelty", "Inventive step", "Industrial applicability".

The method is as follows in stages. Patients with coronary artery disease with the presence of lipidemia who were treated at the Research Institute of Cardiology of the Tomsk NITM were examined.

Criteria for the inclusion of patients in the study: 50-70 years, confirmed diagnosis of coronary artery disease: stable angina II-III FC (patients at high risk of cardiovascular complications with cholesterol levels> 4.0 mmol / l, LDL cholesterol> 1.8 mmol / l ), no contraindications to statin therapy. Exclusion criteria: progressive angina pectoris, acute myocardial infarction, acute cerebrovascular accident, individual intolerance of the study drug, increased activity of the enzymes ALT and ACT, myopathy, decompensated diabetes mellitus, chronic heart failure stage III according to Vasilenko-Strazhesko classification.

The study included 37 patients with a diagnosis of coronary artery disease: stable exertional angina I-IV functional class (FC), the average age of patients was 60.7 ± 9.1 years. The distribution of patients by gender is 8 women and 29 men.

Research methods: analytical (analysis of the history of the disease for the purpose of prescribing lipid-lowering therapy; general clinical (analysis of complaints, general examination), assessment of objective status; performance of clinical and laboratory research methods, such as blood pressure and evaluation of the results of an electrocardiogram; biochemical blood analysis included serum of the following indicators: the content of glucose, albumin, C-reactive protein, total protein, uric acid, creatinine, urea, total and direct bilirubin , ceruloplasmin, sialic acids, activity of ALT, ACT, creatine kinase, α-amylase, alkaline phosphatase, lactate dehydrogenase and cholinesterase. The level of HDL cholesterol, TAG and OXC was evaluated. " Russia.

The content of cholesterol VLDL and LDL was calculated by Friedwald formulas [Friedrich W., 1988]. The calculation of the coefficient of atherogenicity was made according to the formula-prototype (cholesterol-cholesterol-free HDL-C) / HDL-C and expressed in arbitrary units.

The ratio of cholesterol-cholesterol / cholesterol HDL, cholesterol LDL / cholesterol-cholesterole cholesterol was also estimated by calculation and the proposed ratio (cholesterol + TAG) / cholesterol cholesterol was determined. Lipid studies were performed in accordance with the Russian national recommendations for the diagnosis and correction of lipid metabolism disorders for the prevention and treatment of atherosclerosis [V revision, 2012] and the recommendations of EAS / ESC [EAS / ASC, 2016] for the treatment of lipidemias. A detailed blood test was performed using an impedance and optical (flow cytometry) method on a hematological analyzer. As a control group, patients with vegetative-vascular dystonia were examined.

Quantitative values for the normal distribution of data are presented as M ± m, where M is the mean value, m is the mean error.

Statistical data processing was performed using the software package Statistica 13.0 using Student's criteria. Parametric methods were used for distributions that are consistent with normal law. Comparison of quantitative indicators between groups was carried out using student's criterion, and before and after treatment within groups using the Wilcoxon criterion. To analyze the strength of the relationship between the indicators, the Pearson correlation coefficient was calculated. Differences were considered significant at p <0.05.

We describe possible complications when performing research and how to eliminate them.

The prevention of possible false-positive and false-negative results is associated with extremely accurate implementation of research methods. A false positive result is extremely rare and can only be caused by a violation of the serum dilution technique with a high concentration of lipids in it. Before installing the reagents on board the analyzer, you must ensure that there are no bubbles in the vials and on the surface of the reagents to eliminate false-negative results.

Technical result: to confirm the performance of the proposed method and achieve a technical result, a control group (n = 8) and a group of patients with coronary heart disease (CHD) were examined, because At the basis of the pathogenesis of IHD is lipidemia of atherogenic genesis (n = 36). This group is divided into two subgroups of patients with coronary artery disease I-II functional class (FC) (n = 27) and patients with coronary artery disease III-IV FC (n = 9). All groups were examined using the proposed method and the prototype method.

The results of the analysis of blood lipids in patients with coronary artery disease with the presence of early and late stages of lipidemia and in the control group in patients with vegetative-vascular dystonia without the presence of lipidemia are presented in table 1.

As a result of the study in the prototype method, the early and late stages of lipidemia in IHD were not identified, since the normal value of the atherogenic coefficient in the group of IHD patients was 2.54 ± 0.11. According to the proposed method, the atherogenic coefficient (OHS + TAG) / HDL cholesterol significantly exceeded the norm and amounted to 4.33 ± 0.19 in IHD FC I-II and 4.95 ± 0.28 in CHD III-IV FC.

New clinical and laboratory analysis of the results obtained with the calculation of the coefficient (OHS + TAG) / HDL cholesterol allows you to identify lipidemia in the early and late stages of the disease and conduct timely lipid-lowering therapy, which increases the accuracy and specificity of the method. Therefore, the criteria for interpreting the results both clarify the presence of early stages of lipidemia of atherogenic genesis and also allow to evaluate the effectiveness of treatment of lipidemia in the later stages of the disease.

Clinical example No. 1: patient D., 66 years old. Complaints on admission to the pain behind the sternum and in the region of the heart that occur during exercise. The pains are relieved by nitroglycerin. The patient is worried about shortness of breath during exercise. HELL 160/90 mm. Hg, pulse at rest 68 beats per minute.

The results of laboratory studies: total cholesterol is 5.35 mmol / l, triacylglycerol 1.17 mmol / l, HDL cholesterol 1.48 mmol / l, cholesterol LDL 3.36 mmol / l, cholesterol VLDL 0.51 mmol / l, LDL cholesterol ratio / HS HDL 2.27; (OHS-HS LPVP) / HS HS 2.39; (HHS + TAG) / cholesterol HDL 4.40.

Diagnosis: coronary heart disease, angina, FC II, early stage of lipidemia.

The atherogenic coefficient of the prototype method was 2.39, with a norm of up to 3.0. And for a long period this coefficient remained within the normal range, that is, it never exceeded the value of 3.0. At the same time, the atherosclerotic process is constantly progressing and is currently characterized by the presence of atherosclerotic plaques in the main arteries. At the same time, a high level of “anti-atherogenic” lipoproteins, namely HDL with the content of “good” cholesterol in them, remains in the body compensatory for many years. This explains the low value of the atherogenic coefficient in the prototype method. Therefore, it is necessary to introduce into clinical practice a new additional proposed hemoglobin coefficient, such as (OXC + TAG) / HDL cholesterol, which makes it possible to detect the early stage of lipidemia when this coefficient is exceeded up to 4.1-4.8 conventional units.

Even more clearly, the need to use the atherogenic coefficient (OHS + TAG) / HDL cholesterol in clinical practice is demonstrated in the second example.

Example No. 2: Patient P., 61, complaints on admission to pain behind the sternum and in the region of the heart that occur during exercise. Pain relieved by taking nitroglycerin. The patient is worried about shortness of breath during exercise. HELL 140/90 mm. Hg, pulse at rest 66 beats per minute. Diagnosis: coronary heart disease, angina, FC III.

The results of laboratory studies: total cholesterol content of 6.01 mmol / l, triacylglycerol 1.49 mmol / l, cholesterol cholesterol 1.51 mmol / l, cholesterol LDL 4.11 mmol / l, cholesterol LDL 0.66 mmol / l. The coefficients are determined: LDL / HDL cholesterol HDL 3.15; (OHS-HS LPVP) / HS LPVP 2,98; (Cholesterol + TAG) / cholesterol HDL 4.96.

Diagnosis: lipidemia (hypercholesterolemia), coronary heart disease, functional class III.

Therefore, according to the method of the prototype, the atherogenic index does not exceed the norm due to the high level of “antiatherogenic” HDL, containing “good” cholesterol. At the same time, the atherosclerotic process in the body progresses, which led to a violation of the functional activity of the myocardium against the background of a pronounced late stage of lipidemia.

So, in the presented clinical examples No. 1 and No. 2, as well as the results of lipid studies presented in Table 1, the diagnosis of early and late stages of lipidemia is not confirmed by the atherogenic coefficient of the prototype method, but is confirmed only by the atherogenic coefficient of the proposed method (OHS + TAG) / Cholesterol HDL.

The proposed method allows to identify both early and late stages of lipidemia of atherogenic genesis.

The use of the proposed method for the diagnosis of early and late stages of lipidemia, in contrast to the method of the prototype, revealed lipidemia of atherogenic genesis in 98% of cases of CHD, because all indicators characterizing lipidemia were investigated.

The economic efficiency of the new method is to improve the accuracy of detecting the early and late stages of lipidemia in coronary heart disease (CHD) for the medical correction of the disease. The advantage of the proposed method is the low complexity, cost and low cost of research technology. The method does not require the execution of additional expensive reagents and equipment. Methodological errors in the analysis are excluded, which makes the proposed method economically viable.

Since the real characteristic of early and late lipidemia was demonstrated by the atherogenic coefficient (OX + TAG) / HDL cholesterol, it must be introduced into wide clinical practice simultaneously with other coefficients and indicators used, especially since the method is simple to perform and does not require any material costs. In this case, the proposed method is easy to use and interpret the results.

Claims (1)

A method for diagnosing early and late stages of lipidemia by analyzing the results of laboratory studies of blood lipids before treating lipidemia, followed by determining the atherogenic coefficient, characterized in that the ratio (OXF + TAG) / HDL cholesterol is also determined and when this ratio is increased to 4.1-4, 8 conventional units diagnose an early stage of lipidemia, and with the growth of the above ratio to 4.9 or more, a late stage of lipidemia is diagnosed.