RU2400223C1 - Method for normalising functional responsiveness of cardiovascular system in stenocardia function classes i-ii - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention refers to medicine, namely to cardiology and concerns normalising functional responsiveness of cardiovascular system (CVS) in stenocardia function classes I-II. That is ensured by estimating the condition of functional responsiveness of the CVS in psychoemotional load by recording systolic, diastolic, average dynamic pressure. These data are used to evaluate a functional responsiveness index (FRI) before and after load by formula: FRI=(BPav.dyn. × HR)/100 (standard units). The post-load FRI gain by more than 20 standard units requires the administration of lisinopril in a dose 20 mg a day in the morning and metoprolol in a dose 50 mg a day in the morning.

EFFECT: method provides normalising functional responsiveness of the cardiovascular system and higher psychoemotional load tolerance in the given group of patients within two-month therapeutic course.

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Description

The invention relates to medicine, to the field of cardiology, and can be used in therapeutic departments of clinics and hospitals. Analogues of a method for normalizing the functional reactivity of the cardiovascular system in arterial hypertension (AH) with angina pectoris I-II functional classes (C I-II FC) do not exist.

The aim of the invention is to increase the correction efficiency of the functional reactivity of the cardiovascular system in hypertension and C I-II FC.

The essence of the proposed method for the correction of the functional activity of the cardiovascular system is to increase the tolerance of hypertensive patients with C I-II FC to psychoemotional stress and increase the functional reactivity of the cardiovascular system when they perform a dosed psychoemotional load and reduce the risk of cardiovascular complications during emotional stress evaluated after a dosed psychoemotional load with a constantly increasing speed for 18-20 minutes every minute registration of the parameters of central hemodynamics: systolic blood pressure (BPA), diastolic blood pressure (BPD), average dynamic blood pressure (BPA) and heart rate (HR), determine the value of the functional reactivity index (PFR), which is the product of blood pressure dynamic average at heart rate, calculate the relative increment of the PFR value when the load is performed compared to the value at rest, and according to the value of the PFR, the type of functional reactive ti cardiovascular system: at a value of more than 20 FIU conv reactivity is assessed as hyperfunctional, with a PFR value of less than 10 conventional units the response to the load is assessed as hypofunctional and with PFR values from 10 to 20 conventional units type of functional reactivity is assessed as normal. The time of the psycho-emotional load is no more than 20 minutes. To normalize the functional reactivity index in patients with hypertension with C I-II FC, a combination of lisinopril and metoprolol is used for at least 2 months.

The inventive method is as follows. The value of the PFR indicator is determined by O. Lebedeva, S. A. Radzievsky, S. A. Bugaev A method for assessing the state of functional reactivity of the cardiovascular system RU 2207044. The patient is seated in front of a monitor screen. A cuff is placed on the patient’s left shoulder to measure systolic blood pressure, diastolic blood pressure, dynamic average blood pressure and heart rate before and during exercise. The patient is offered two sets of 4 letters: ANEU and RLOG, from which he must choose one to remember. After registering the hemodynamic parameters for 3 minutes and remembering (30 s) the selected set of letters, the psychoemotional load begins, which consists in the fact that the test person presses the key marks the scattered letters from the set he chooses as he moves on the monitor screen a square frame in random order the letters of the alphabet. The speed of advancement of the frame along the rows of letters during the sampling process increases from 3 letters in 1 s at the beginning of the load to 6 letters in 1 s, starting from 6 min of the load, and this ensures the patient’s gradual development. Errors in marking letters from the selected set are accompanied by sound signals, according to which the subject can navigate the correct execution of the load and try to adjust its performance. After the end of the load, the average values of blood pressure s, blood pressure, blood pressure cf. din. and heart rate in periods: before the load and during the load. Dynamic mean blood pressure is calculated by the formula: ADdr.din = ADd + [0.42 (ADs-ADd)].

Dynamic mean blood pressure is a complex result of all variables of blood pressure. When conducting a test with emotional stress in healthy individuals, the mean dynamic does not change significantly, and heart rate, as a rule, increases. According to studies, an increase in heart rate and blood pressure leads to an increase in myocardial oxygen demand and an increase in its energy expenditure. In conditions of pathology, for example, with hypertension, coronary heart disease, vessels in a state of spasm are not able to provide the required increased amount of oxygen, as a result of which hypoxia, impaired cerebrovascular circulation may develop, an angina attack may develop, etc.

Based on the data obtained, an indicator of functional reactivity is calculated, which allows integratively assessing the degree of increase in the hemodynamic load on the heart and, accordingly, the risk of developing cardiovascular complications, defined as follows:

PFR = (ADdr.din. × Heart rate) / 100 (conventional units)

The increment of PFR values during the transition from rest to load fulfillment is determined by the indicator:

PFR = PFR2-PFR1,

where PFR is the difference between the PFR values before and under load, PFR1 is the average value of the indicator before the load, PFR2 is the average value of the indicator under load. According to the value of the relative increment of PFR values, the type of functional reactivity of the cardiovascular system is evaluated: if the value is *, then it is divided by 100 to obtain arbitrary units (conventional units are two-digit numbers).

In a second study in the dynamics of treatment, the patient is given to memorize a different set of letters in order to prevent addiction.

When the values of the increment after a metered psychoemotional load PFR from 10 to 20 srvc. units functional type of reactivity is assessed as normal. When PFR load more than 20 srvc. a patient with hypertension with C 1-11 FC must be prescribed for at least 2 months a combination of lisinopril 20 mg in the morning 1 time and metoprolol 50 mg in the morning 1 time per day.

Timely and effective correction of PFR in patients with hypertension with C I-II FC will allow them to quickly normalize the functional reactivity of the cardiovascular system, which will shorten the period of temporary disability in these patients, prevent strokes and heart attacks, reduce the number of disability exits and reduce mortality among patients with hypertension with I-II FC.

Example 1. A patient L. 56 years old, suffering from coronary heart disease was examined: stable angina pectoris I FC, hypertension II degree, stage III, BUT 3 years. In the study of hemodynamics in the initial state before the psychoemotional load, the blood pressure was 142 mmHg, blood pressure was 92 mmHg, and ADd.din. - 113.0 mm Hg, heart rate - 80 beats. in 1 min. PFR before the start of the psychoemotional load was equal to (9040) / 100 = 90.4 conv. units During the psychoemotional load, blood pressure increased to 166 mmHg, blood pressure - 105 mmHg, blood pressure. up to 130.6 mmHg, heart rate - up to 92 beats. in 1 min, the value of PFR increased to (12017) / 100 = 120.2 srvc, that is, the increment of PFV on the load or, what is the same - PFR, amounted to 29.8 srvc. (from 90.4 conventional units to 120.2 conventional units), which can be regarded as a manifestation of hyperfunction of the cardiovascular system. The patient was prescribed a combination of lisinopril 20 mg in the morning and metoprolol 50 mg in the morning. After 2 months of treatment, the value of PFR decreased before the start of the load compared with the same before treatment: blood pressure - up to 125 mmHg, blood pressure - up to 82 mmHg, blood pressure.din. - up to 100.0 mm Hg, heart rate - up to 70 beats. in 1 min, PFR - up to 70.0 conv. units When performing the load, there was a decrease compared to the state before treatment, the degree of increase in blood pressure values - up to 138 mm Hg, blood pressure - up to 88 mm Hg, blood pressure. - up to 109.0 mm Hg, heart rate - up to 76 beats. in 1 min., PFR - up to 82.8 conv. units, that is, an increase in PFR, or PFR, by 12.8 srvc (by 29.8 srvc. units before treatment), which may indicate an increase in the tolerance of the cardiovascular system to psychoemotional stress, a decrease in hyperfunction of the cardiovascular system, and, consequently, economization of cardiac activity.

Example 2. Patient I. 49 years old, suffering from coronary heart disease was examined: stable angina pectoris is intense II FC, grade III hypertension, stage III, BUT 6 years. In the study of hemodynamics in the initial state before the psychoemotional load, the blood pressure was 162 mmHg, blood pressure was 96 mmHg, and blood pressure was one. - 123.7 mmHg, heart rate - 84 beats. in 1 min. PFR before the start of the psychoemotional load was equal (10394.5) / 100 = 103.9 conv. units During the psychoemotional load, blood pressure increased to 186 mmHg, blood pressure - 112 mmHg, blood pressure. up to 143.1 mm Hg, heart rate - up to 100 beats. in 1 min, the value of PFR increased to 143.1 srvc, that is, the increment of PFV at the load or, what is the same - PFR, amounted to 39.2 srvc. (from 103.9 conventional units to 143.1 conventional units), which can be regarded as a manifestation of hyperfunction of the cardiovascular system. The patient was prescribed a combination of lisinopril 20 mg in the morning and metoprolol 50 mg in the morning. After 2 months of treatment, the value of PFR decreased before the start of the load compared with the same before treatment: blood pressure - up to 126 mmHg, blood pressure - up to 80 mmHg, blood pressure.din. - up to 99.3 mm Hg, heart rate - up to 70 beats. in minutes, PFR - up to 69.5 conv. units When the load was performed, a decrease compared with the state before treatment, the degree of increase in the values of blood pressure - up to 145 mm Hg, blood pressure - up to 88 mm Hg, blood pressure. - up to 111.9 mm Hg, heart rate - up to 76 beats. in 1 min, PFR - up to 85.1 conv. units, that is, an increase in the values of PFR, or PFR, by 15.6 conventional units is noted. (before treatment - by 39.2 srvc. units), which may indicate an increase in the tolerance of the cardiovascular system to psychoemotional stress, a decrease in hyperfunction of the cardiovascular system and, consequently, on the economization of cardiac activity.

As a result of the application of the proposed method for correcting the state of the functional reactivity of the cardiovascular system in patients with hypertension with C I-II FC, normalization of the functional reactivity of the cardiovascular system to a dosed psychoemotional load is achieved, which allows the method to normalize the tolerance of patients with hypertension with C I-II FC to psychoemotional stresses, reduce the degree of hemodynamic stress when exposed to stress, reducing the risk of development with psychoemotional stresses tnyh vascular responses (angina, myocardial infarction, cerebrovascular disease and others.).

Claims (1)

A method for normalizing the functional reactivity of the cardiovascular system (CVS) in patients with a combination of arterial hypertension with angina pectoris of functional classes I-II, including assessing the state of functional reactivity of CVS under psychoemotional stress, for which systolic, diastolic, and average dynamic pressure are recorded, based on these data, it is determined the indicator of functional reactivity before and after the load, using the formula: PFR = (ADsr. unit. · HR) / 100 (srvc.), and with an increase in the value of PFR after load more than 20 conv inject lisinopril at a dose of 20 mg per day in the morning and metoprolol at a dose of 50 mg per day in the morning for at least 2 months.