RU160334U1 - METHOD FOR INCREASING ANTIDROMOUS FUNCTION OF SENSOR PEPTIDERGIC PERIVASCULAR FIBERS AND REACTIVITY OF MICRO-VESSELS - Google Patents

Abstract

A method for increasing the antidromic function of sensory peptidergic perivascular fibers and microvessel reactivity, including recording skin blood flow parameters using laser Doppler flowmetry, characterized in that a stimulating electrode is placed on the area of the ventral surface of the mid-wrist, an optical electrode is placed at a distance of 1 cm from it, and sensory electrostimulation is performed fibers, acting with a stimulating current with a stimulation frequency of 2 Hz, a pulse duration of 500 μs, a current strength of 0.5 mA, gradually increasing it in increments of 0.5 mA, until the pain in the stimulation area for 1 minute, simultaneously record the level of perfusion by laser Doppler flowmetry (LDF), the time from the start of stimulation to the start of increasing the level of perfusion, the total rise time of the perfusion, compare the values of the indicators before and after electrical stimulation, then on the area of symmetrical biologically active points E-36, MS-6 and GI-4 are exposed to low-intensity electromagnetic radiation of extremely high frequency (EHF EHF) for 30 minutes, according to Torno electrostimulation is carried out simultaneously record indicators tissue blood flow parameters, as compared with that before and after the impact of electromagnetic radiation EHF determine the increase antidromic peptidergic sensory function perivascular fibers and microvascular reactivity.

Description

The technical solution relates to the field of physiology and medical biophysics and can be used to study the effect of electromagnetic fields on human microcirculatory processes in order to identify and clarify the mechanisms of the biological effect of electromagnetic radiation (EMR) for further prevention and correction of microcirculatory disorders in humans.

The functioning of neurovascular connections, the regulation of vascular tone and tissue trophism, mechanisms, patterns of perivascular innervation and its disorders occupy one of the central places in physiology, biophysics and medicine and are the subject of neuroangiophysiology [Colantuoni, 2000; Krupatkin, 2003, 2007]. Currently, the study of the function of sensory peptidergic perivascular fibers, which are an integral component of perivascular innervation, is of the greatest interest [Krupatkin, 2005]

As a prototype, a method for diagnosing disorders of the antidromic function of sensory peptidergic perivascular fibers (Pat. 2277861 RF, IPC (2006.01) A61B / 06) was selected.

A method for diagnosing disorders of the antidromic function of sensory peptidergic perivascular fibers, which includes registering skin blood flow using laser Doppler flowmetry, which is characterized in that the average cutaneous blood flow is recorded in the autonomous zone of nerve innervation for 6 minutes, and the normalized average maximum amplitude (Ac) of blood flow oscillations is calculated in the range 0.052-0.069 Hz according to the formula Ac = A / δ, where A is the average maximum amplitude of blood flow fluctuations in the above frequency range , δ is the mean square deviation of the amplitude fluctuations in blood flow from the arithmetic mean value, and when the Ac indicator deviates from the average control value by ± 30%, disorders of the antidromic function of sensory peptidergic nerve fibers are diagnosed.

The disadvantage of the prototype is the inability to increase the antidromic function of sensory peptidergic nerve fibers.

The utility model is based on the task of improving the antidromic function of sensory peptidergic perivascular fibers and the microvessel reactivity by conducting electrical stimulation and simultaneously recording parameters characterizing the antidromic activity of peptidergic fibers under the influence of low-intensity EHF EMF. The problem is solved in that in a method for increasing the antidromic function of sensory peptidergic perivascular fibers and microvessel reactivity, which includes recording blood flow parameters using laser Doppler flowmetry, according to a utility model, a stimulating electrode is placed on the area of the ventral surface of the middle of the wrist, at a distance of 1 cm from an optical electrode is placed in it, electrostimulation of the sensor fibers is performed by stimulating current with a stimulation frequency of 2 p, pulse duration - 500 microseconds, the current intensity of 0.5 mA

gradually increasing it in increments of 0.5 mA, until the pain in the stimulation area for 1 minute simultaneously record the perfusion level by the LDF method, the time from the start of stimulation to the beginning of the increase in perfusion level, the total perfusion rise time, the values of the indicators before and after electrical stimulation are compared then the region of symmetric biologically active points E-36, MS-6 and GI-4 is exposed to low-intensity electromagnetic radiation of extremely high frequency (EHF EHF) for 30 minutes, electrical stimulation is repeated Simultaneously record indicators tissue blood flow parameters, as compared with that before and after the impact of electromagnetic radiation EHF determine the increase antidromic peptidergic sensory function perivascular fibers and microvascular reactivity. The method provides due to the action of low-intensity EMR EHF an increase in the effector function of sensory peptidergic fibers and the reactivity of microvessels.

The method is implemented as follows.

A stimulating electrode was placed in the area of the ventral surface of the middle of the wrist of the right hand according to the antidromic technique; ground electrode - on the left hand. The stimulating current parameters were as follows: current frequency - 2 Hz, pulse duration - 0.5 ms. The study began with the supply of pulses of low strength - 0.5 mA, gradually increasing it in increments of 0.5 mA to the pain threshold, within 1 minute. Registration was carried out in the recording mode of the program "Sensory test".

The activity of the effector function of sensory peptidergic perivascular fibers was evaluated during electrical stimulation using the laser Doppler flowmetry (LDF) method using a laser analyzer microcirculation "LAKK-02", while placing an optical waveguide 1 cm distal to the simulating electrode so that both the stimulating and optical lead electrodes were in the same receptor field.

The LDF-metry during the electrostimulation test was carried out according to the following scheme: registration of the initial level of perfusion for 1 minute → registration of blood flow during electrostimulation for 1 minute → registration of the dynamics of perfusion after electrostimulation for 1 minute.

The dependence of the signal on the state of microcirculation can be described as follows:

where PM is the indicator of microcirculation, No. p is the concentration of red blood cells, Vcp is the average speed of movement of red blood cells in the probed volume.

Evaluation of the effector function of peptidergic fibers was performed according to the following indicators:

ΔΠΜ (%) is the microcirculation index characterizing the change in the level of perfusion during electrical stimulation, which was calculated by the formula:

where PMmax is the maximum PM value recorded during the electrostimulation test, Misk. - the initial value of the PM.

On (Fig. 1) is an example of recording LDF-grams in subjects with an electrostimulation test on the ventral surface of the middle of the wrist of the right hand.

The time parameters of the perfusion level change were estimated, namely T1 - the time from the beginning of electrical stimulation to the beginning of the curve rise, in seconds (s); T2 - the total time of the rise of the curve from its beginning to the moment of decline (s).

An electrical stimulation test with simultaneous LDF-metry was performed before exposure to mm radiation (control), as well as immediately after a session of EHF EMF.

Electrical stimulation with simultaneous LDF-metry was performed before exposure to EHF EHF (control), as well as immediately after a session of EHF EHF. Influenced by low-intensity electromagnetic radiation of EHF on the area of symmetric biologically active points E-36, MS-6 and GI-4. The choice of these points is due to their general strengthening, stimulating and reflexogenic effect on the test organism. The exposure to low-intensity EMR EHF was carried out using a 6-channel apparatus "RAMED EXPERT-04". Generator specifications: wavelength - 7.1 mm, radiation frequency - 42.4 GHz, power flux density - 0.1 mW / cm ² . During the study, the subjects were in a sitting position in a comfortable chair. Hands and forearms of the upper extremities were placed on the roller, which ensured their additional fixation and a relaxed state. Statistical processing of experimental data was carried out using computer programs (Microsoft Excell, Statistica 8.0). For statistical data processing, descriptive statistics and nonparametric methods of statistical analysis were used (Wilcoxon test).

Figure 2 shows the dynamics of an indicator characterizing the change in perfusion during electrical stimulation, relative to the initial values (ΔΠΜ,%) recorded before and after the action of EMR EHF in the subjects.

The results of the study showed that the indicator ΔΠΜ%. After exposure to EHF EHF, this indicator increased 2.42 times (p≤0.05) relative to the initial values and amounted to 89.63%. It is known that the ΔΠΜ level characterizes vasodilation of skin vessels caused by antidromic releasing of vasoactive peptides from sensory peptidergic perivascular fibers, that is, in essence, reflects the effector function of these fibers, recorded in the electrostimulation test on an LDF-gram. An increase in this indicator indicates an increase in the effector function of sensory fibers observed after EHF exposure. In addition, the results of the study showed that the T1 indicator, which characterizes the time from the beginning of electrical stimulation to the beginning of the increase in perfusion, in the control was 1.8 s when registering LDF-grams.

On (Fig. 3) shows the dynamics of an indicator characterizing the time from the beginning of electrical stimulation to the beginning of the rise in the level of perfusion (T1, s), recorded before and after EHF exposure.

After a session of EHF exposure, the T1 index on the right hand was 1.04, that is, the latent time from the beginning of electrical stimulation to the appearance of vasodilation was reduced by 42.22% (p≤0.05). Since the indicator T1 characterizes the latent time from the beginning

supply of stimuli before the onset of vasodilation, then its reduction indicates an increase in the reactivity of the response of microvessels observed with EHF exposure. Indicator T2, characterizing the total time of the curve rising from its beginning to the moment of decline, in the control amounted to 64.79 s. After exposure to low-intensity EHF EHF, there was only a tendency to increase this indicator (p> 0.05).

The method provides due to the action of low-intensity EHF EHF a significant change in ΔΠΜ and T1 in the electrostimulation test, which indicates an increase in the effector function of sensory peptidergic fibers and the reactivity of microvessels.

Claims (1)

A method for increasing the antidromic function of sensory peptidergic perivascular fibers and microvessel reactivity, including recording skin blood flow parameters using laser Doppler flowmetry, characterized in that a stimulating electrode is placed on the area of the ventral surface of the mid-wrist, an optical electrode is placed at a distance of 1 cm from it, and sensory electrostimulation is performed fibers, acting with a stimulating current with a stimulation frequency of 2 Hz, a pulse duration of 500 μs, a current strength of 0.5 mA, gradually increasing it in increments of 0.5 mA, until the pain in the stimulation area for 1 minute, simultaneously record the level of perfusion by laser Doppler flowmetry (LDF), the time from the start of stimulation to the start of increasing the level of perfusion, the total rise time of the perfusion, compare the values of the indicators before and after electrical stimulation, then on the area of symmetrical biologically active points E-36, MS-6 and GI-4 are exposed to low-intensity electromagnetic radiation of extremely high frequency (EHF EHF) for 30 minutes, according to Torno electrostimulation is carried out simultaneously record indicators tissue blood flow parameters, as compared with that before and after the impact of electromagnetic radiation EHF determine the increase antidromic peptidergic sensory function perivascular fibers and microvascular reactivity.

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