RU2456032C1 - Method of increasing body performance capability - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention refers to medicine, specifically to sports medicine. A method involves a colour-pulse exposure. The exposure is performed in a red visible spectrum, at wave length 630 nm and frequency 40 Hz. Each eye is alternately exposed for 5 minutes. The sessions are daily; the therapeutic course is 10 procedures.

EFFECT: method provides higher adaptation effect ensured by optimising vegetative regulation, sensory visual system and body microcirculation.

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Description

The invention relates to sports physiology and medicine and can be used in sports (including sports of the highest achievements), sports medicine and general medical practice.

A known method of restoring the dynamic balance of excitatory-inhibitory processes in the visual analyzer during the correction of ophthalmopathology by alternating photostimulation of the organ of vision. This method is used in clinical ophthalmology. Photostimulation is carried out by color-pulse exposure with a physiological frequency of 0.2 Hz alternately for each eye with an exposure of 15 minutes using the ASO-05 apparatus, a microprocessor binocular generator of light quanta in the visible spectrum from red (650 nm) to blue (450 nm) with the formation achromatic and chromatic light of various tones, brightness and saturation, and the supply of pulses of different frequencies. At the same time, a change in the level of homeostasis was achieved with a decrease in the sympathetic and increase in the parasympathetic tone of the autonomic nervous system. (Volkova L.P. Mechanisms of autonomous regulation of the binocular visual system and the ways of its restorative correction in case of eye diseases // Abstract of thesis ... MD, MD, 2009.)

The method is time consuming and expensive, requires the use of sophisticated exclusive equipment.

There is a way to recover from physical and psychological stress, prevent visual fatigue and correct ophthalmopathology by photostimulating the organ of vision with a uniform unstructured field. Stimulation is carried out by light radiation in the range of green (510 nm) and red (650 nm) visible spectrum alternately for each eye with an exposure of 15 minutes using the AFZA photodiagnostics and stimulation device. (Ministry of Education and Science of the Russian Federation. GKN02.522.11.2015 “Creation of photo- and electrical stimulation technologies for the diagnosis and rehabilitation of lesions of the neuromuscular system and the musculoskeletal system, production of prototypes of equipment.” Innovative developments by the Federal State Institution VNIIFC.)

Application of the method is possible only with the exclusive AFZA device.

The objective of the invention is to simplify the way to improve the health of the body, the exclusion of the use of expensive exclusive equipment for widespread implementation in the system of biomedical support of sports of the highest achievements.

The essence of the proposed method lies in the fact that they carry out visual color-pulse treatment (VCIV) in the red range of the visible spectrum of 630 nm, with a physiological frequency of 40 Hz, alternately for each eye with an exposure of 5 minutes, a course of 10 sessions in one session every day.

Carrying out VTsIV with a physiological frequency of 40 Hz, in the red range of the visible spectrum, can, along with improvements in the performance of the sensory visual system, cause a systemic adaptive effect in the form of optimization of the autonomic regulation of cardiac activity and general microcirculation of the body. High-frequency oscillations with a value of 40 Hz make it possible to synchronize the activity of neurons of various fields of the cerebral cortex, which creates favorable conditions for the organization of adaptive functional systems.

The impact is carried out using a "Flash device" of Russian production, inexpensive and easy to use, included in the equipment of the eye cabinet of each medical institution in accordance with the standards of the Ministry of Health and Social Development of the Russian Federation.

Example. Athlete F. 17 years old, master of sports, world champion among juniors in long jump.

On the day of the start of the VTsIV course, visual testing was performed: the area of visual fields in total degrees = 507/504, the critical flicker fusion frequency (CFSM) to red light = 22/27 Hz, the indicators of autonomic regulation of heart activity were taken: heart rate (HR) = 66 bpm, the index of autonomic equilibrium (IIR) = 91, the adequacy of regulatory processes (CAP) = 0.36, the vegetative rhythm index (VLR) = 33, the index of voltage of regulatory systems (IN) = 58, the total microcirculation of the body was determined by biomicroscopy suck Dov conjunctiva of the eye on a slit lamp: total conjunctival index (OCI) = 23 points.

A test load was carried out on a bicycle ergometer for 5 minutes with a frequency of 60 rpm. After the load, visual testing indicators: the area of the visual fields in total degrees = 500/502, CFCF for red light = 20/25 Hz. Indicators of autonomic regulation of cardiac activity: heart rate = 70 beats / min, IVR = 98, PAPR = 0.32, VLP = 34, IN = 61. Total microcirculation of the body: OKI = 26 points.

Using the "Flash device", an IPW was performed in the red range of the visible spectrum of 630 nm with a physiological frequency of 40 Hz, alternately for each eye with an exposure of 5 minutes. The exposure was carried out 10 days daily, 1 session per day.

On the day of the end of the VTsIV course, visual testing indicators: the area of the visual fields in total degrees = 519/520, CFCF for red light = 49/46 Hz. Indicators of autonomic regulation of cardiac activity: heart rate = 62 beats / min, IVR = 61, PAPR = 0.38, VLP = 21, IN = 32. Total microcirculation of the body: OKI = 12 points.

The day after the VTsIV course, a test load was carried out on a bicycle ergometer for 5 minutes at a frequency of 60 rpm. After the load, the indicators of visual testing, the autonomic regulation of cardiac activity and the general microcirculation of the body did not change compared to the same indicators taken on the day the end of the VTsIV course.

The test of the method was carried out in two groups: a group of athletes of cyclic sports, aged 17 to 19 years (men n = 25, women n = 24) and a control group consisting of persons not involved in sports aged 17 to 19 years ( men n = 10, women n = 10).

In both groups, each test subject was given a test load on a bicycle ergometer for 5 minutes at a frequency of 60 rpm. After the load, visual testing indicators were taken: the area of the visual fields in total degrees, CFSM for red light, indicators of the autonomic regulation of cardiac activity: heart rate, IVR, PAPR, VPR, IN. The total microcirculation of the body was determined: OCI in points. On the same day, the VTsIV course was started according to the above scheme.

On the day of the end of the VTsIV course, indicators of visual testing were taken, indicators of the autonomic regulation of cardiac activity, and the general microcirculation of the body were determined.

The data obtained are presented in tables.

Table 1 presents the indicators of visual testing when using VTsIV.

An increase in CSFM (see Table 1) after VTsIV sessions indicates normalization of the visual function of athletes. In the same group, there was a tendency to a certain increase in the field of view after VTsIV, which indicates a predominant increase in peripheral vision. The IHAC contributed to the normalization of the caliber of subconjunctival capillaries.

In untrained subjects, even after exposure to VCIV, the venous congestion of the conjunctiva remained, which was significantly different from the effective normalization of capillary blood flow achieved in athletes who underwent VCIV.

Table 2 presents the data on the dynamics of indicators of cardiac activity after a course of VTsIV.

From table 2 it follows that after VTsIV, athletes tended to decrease heart rate, indicating a vagal effect. According to the index of IVR, we can conclude that there is a normalization of autonomic dysfunction in trained subjects. Exposure to the IWAC did not lead to a change in CAD. After VTsIV significantly improved CDF.

For untrained students, the initial heart rate was higher than for athletes, which is consistent with literature. In the same group, the IVR significantly exceeded the norm and the corresponding indicator in the experimental group. The parameters of VLOOKUP, CAPR and IN were the same without gender differences. After VTsIV, untrained subjects showed a tendency toward a reduction in heart rate.

The indicators of the autonomic regulation of cardiac activity in the control group were optimized with a 2.2-fold increase in the IN index compared with the experimental group.

From these tables we can see the presence of a direct positive relationship between the optimization of the performance of the sensory visual system and the parameters of both autonomic regulation and the general microcirculation of the body. This is an important factor in improving the health of the body, in particular the athlete’s body during training cycles, the pre-competition period and post-competition rehabilitation.

Thus, the proposed method directly affects the optimization of both the activity of the sensory visual system and the autonomic regulation of cardiac activity and the general microcirculation of the body. This is an important factor in increasing the workability and the ability to work in extreme loads of top-level athletes in the training cycle, in the pre-competition and competition periods, as well as in the rehabilitation of athletes in the post-competition period. The method is simple to implement, does not require large material costs and exclusive equipment.

Claims (1)

A way to increase the health of the body by visual color-pulse exposure in the red range of the visible spectrum, characterized in that the visual color-pulse effect is carried out at a wavelength of 630 nm, with a physiological frequency of 40 Hz, alternately for each eye with an exposure of 5 minutes, a course of 10 sessions, one session daily.