RU2136205C1 - Method for current controlling of sportsman's functional state - Google Patents

Abstract

FIELD: medicine, in particular, medical control of individuals involved in sports and physical culture. SUBSTANCE: method involves registering omega-potential before doing exercises; counting omega-potential stabilizing time, intensity and expressiveness of superslow potential oscillations. When omega-potential stabilizing time is 60-180 s, at low-intensity of 1-2 mV and slightly expressed superslow oscillations of 10-20%, functional state of sportsman is considered optimum. When omega-potential stabilizing time is 240-480 s, intensity is within the range of 6-8 mV and expressiveness is within the range of 70-95%, functional state of sportsman is considered as overtrained. EFFECT: increased efficiency and provision for obtaining precise data on sportsman's functional state. 1 tbl, 4 ex

Description

 The invention relates to medicine and can be used in medical supervision of those involved in physical education and sports.

 Aspects of medical and pedagogical control relating to determining the state of health, diagnosing pre-pathological and pathological changes, and the characteristics of the course of diseases of the internal organs of athletes have found deep and comprehensive coverage in a number of guidelines. However, the development of informative objective methods for monitoring the athlete’s functional state continues to be an urgent problem (Sports Medicine. / Ed. By A.V. Chogovadze, L.A. Butchenko. - M .: Medicine, 1984; Children's Sports Medicine / Ed. S.B. Tikhvinsky, S.V. Khrushchev. - M .: Medicine, 1991).

 Current control involves evaluating the delayed training effect, i.e., changes that occur after a certain time after one or more training sessions. Of the forms of organization of this control, the most informative are measurements taken daily in the morning.

где X - прирост частоты сердечных сокращений, полученный при обследовании спортсмена, M и σ - статистические характеристики нормальной реакции (по данным Ю.М. Стойда и В.А. Пономарева М ±. = +19±8). При этом, чем больше Ho, тем ниже качество реакции (по знаку + или - определяется характер реакции, соответственно гипер- или гипосимпатикотонический);
способ оценки функционального состояния спортсмена по анализу сердечного ритма (Ритм сердца у спортсменов. / Под ред. Р.М. Баевского и Р.Е. Мотылянской. - М.: Физкультура и спорт, 1986, 143 с.). При этом у спортсмена в положении лежа в одном из отведений ЭКГ регистрируются не менее 100 сердечных циклов. Затем с точностью до 0,01 с измеряется длительность каждого интервала RR. Индекс напряжения рассчитывается по формуле

где Mo - наиболее часто встречающееся значение длительности интервалов между сердечными сокращениями, отражающее активность гуморального канала регуляции ритма сердца; AMo - амплитуда моды: частота выявления моды (Mo) в процентах от общего числа рассмотренных интервалов, отражает активность симпатической регуляции ритма сердца; X - вариационный размах: X = X_max - X_min, отражает активность вагусной регуляции ритма сердца. Индекс напряжения (ИН) характеризует степень "напряжения" систем организма к условиям внешней среды: чем ниже ИН, тем выше функциональное состояние.Currently, the following are most often used for monitoring the functional state of athletes:
a method for assessing the response of an athlete’s cardiovascular system to an orthostatic test (Stoyda Yu.M., Ponomarev V.A. Use of orthostatic influences to assess the adaptation of an athlete's body to various conditions of activity. - Theory and practice of physical culture, 1974, No. 3, C. 28). It includes the definition of heart rate in the supine position and after three minutes of being in the standing position. To assess the response to an orthoprobe, the normalized (Ho) deviation is calculated by the formula:

where X is the increase in heart rate obtained during the examination of the athlete, M and σ are the statistical characteristics of the normal reaction (according to the data of Yu.M. Stoyda and V.A. Ponomareva M ±. = + 19 ± 8). Moreover, the more Ho, the lower the quality of the reaction (the + or - sign determines the nature of the reaction, respectively hyper- or hyposympathicotonic);
a method for assessing the functional state of an athlete by analyzing heart rhythm (Heart rhythm in athletes. / Under the editorship of R.M. At the same time, the athlete in the supine position in one of the ECG leads records at least 100 cardiac cycles. Then, with an accuracy of 0.01 s, the duration of each RR interval is measured. The stress index is calculated by the formula

where Mo is the most common value of the duration of intervals between heart contractions, reflecting the activity of the humoral channel of regulation of the heart rhythm; AMo - mode amplitude: the frequency of mode detection (Mo) as a percentage of the total number of considered intervals, reflects the activity of sympathetic regulation of the heart rhythm; X - variation range: X = X _max - X _min , reflects the activity of vagal regulation of heart rhythm. The stress index (IN) characterizes the degree of "stress" of the body systems to environmental conditions: the lower the IN, the higher the functional state.

The disadvantages of analogues. The use of the presented analogues for current monitoring of the functional state of athletes has some limitations:
it is possible to fulfill the conditions for conducting an orthostatic test as applied to the tasks of current control only during training sessions, when the doctor is constantly with the athletes. In daily work, the athlete comes for examination after breakfast and various household loads;
the process of analyzing the heart rhythm with an assessment of the athlete’s functional state under current monitoring should also be carried out in the morning, on an empty stomach. In this case, a series of stages passes: ECG registration on an electrocardiograph, manual measurement of time intervals of the heart rhythm, input of the received information into a computer with subsequent processing. This option is inconvenient due to a rather significant investment of time. The use of automatic heart rate analyzers in wide sports practice is limited by the high cost of this complex of equipment (Baevsky R.M., Motylyanskaya R.E., 1986).

 As a prototype, an indicator of the magnitude of the omega potential, selected discretely from the surface of the head and reflecting the level of wakefulness of the athlete (the interval from 20 to 39 mV corresponds to the level of optimal wakefulness), was selected. It is proved that this indicator can be used to optimize physical and mental stress by the current control method (Sychev A.G., Protchenko N.N., Scherbakova N.I., Baryshev G.I., Kostenko V.V. Human physiology, 1980 , t. 6, N 1, pp. 178-180; Methodological recommendations. Krasnodar, 1980, 14 pp.).

 The use of a single discrete measurement of the omega potential for current monitoring of the functional state of athletes is not enough. Facts have been obtained that show that sequential recording of this indicator with an interval of 30 s - 1 min from the moment the athlete sat in the chair to stabilize the close omega potential values allows one to determine with a high degree of reliability the stability or instability of the state of the central nervous system and adaptive systemic reactions of the body (Ilyukhina V.A., Khabaeva Z.G., Nikitana L.I. Super slow processes and intersystem interactions in the body. - L.: Nauka, 1986, 192 p.).

 In view of the foregoing, we propose carrying out graphical registration of the spontaneous dynamics of super slow physiological processes in athletes using EVL-1MZ electrodes and a direct current amplifier with a H-39 recording device.

 The goal is to increase the accuracy of assessing the functional state of an athlete with current monitoring.

 Tasks.

 1. In parallel, investigate the indicator of the magnitude of the omega potential, recorded discretely and a set of indicators determined by graphical registration of the spontaneous dynamics of super slow physiological processes in the current control of the functional state of the athlete.

 2. To determine the advantages of a set of indicators of SMPP in comparison with the discrete value of omega potential.

 3. To develop, on the basis of continuous recording of the spontaneous dynamics of the SMPP, a technology for recognizing the athlete's optimal functional state and overtraining state.

 The essence of the invention is the measurement of the indicators of the spontaneous dynamics of SMPP within a few minutes before the start of the training and subject to the stabilization time of the omega potential (60-180 s), low-intensity (1-3 mV) and weakly expressed (10-20%) ultra-slow potential oscillations are considered optimal the functional state of the athlete, and with increasing stabilization time of the omega potential (240-480 s), increased intensity (6-8 mV) and severity (70-95%) of the ultra-slow potential fluctuations determine the state of overtraining.

 Justification of novelty. A patent study showed that to date, the proposed technology for recognizing an athlete’s optimal functional state and overtraining state has not been described and has not been used in ongoing monitoring. Publications and patents in domestic and foreign sources not found.

 The inventive step is confirmed by non-obviousness.

 The reproducibility of the method is not in doubt, because well-known equipment and processes available for medical personnel were used.

 The implementation of the method. In the morning, before training, in an upright position, an athlete in the vertex area using the international system 10-20 installed one electrode EVL-1M3, the other in the tenar area of one of the hands. After that, the athlete sat on a chair and at the same time turned on a DC amplifier with a H-39 recorder. Registration was carried out until the omega potential became stable with the formation of a “plateau” lasting 2 minutes or more, which was considered the state of its stabilization. The total registration time did not exceed 8 minutes. After recording, the stabilization point was noted and the time to reach the plateau (in s) and the stabilized omega potential (in mV) were measured. The presence and severity of super slow potential fluctuations during the observation period were taken into account.

где P - период волны, T - длительность регистрации (Гоголицын Ю.Л., Илюхина В.А., 1976).Analyzed:
omega potential stabilization time (time in seconds from the start of registration to the omega potential reaching the plateau);
the value of the stabilized omega potential (the level of omega potential stabilized for two or more minutes after reaching a "plateau", in mV);
the intensity of super slow potential oscillations (the amplitude of the oscillations of the potential difference, in mV);
the severity of super slow potential oscillations (SMKP) was determined by the formula

where P is the wave period, T is the registration duration (Gogolitsyn Yu.L., Ilyukhina V.A., 1976).

 In terms of intensity, the SMKPs were distinguished as weak, with an amplitude of 1-3 mV, moderate - 4-6 mV, expressed - 7-8 mV.

 The possibilities of the proposed method for monitoring the functional state of the athlete are reflected in the table.

 The table below shows that the omega potential of highly qualified pentathletes recorded in the morning in the interval from 8 to 9 hours, both before training and before the competition, did not differ. All athletes before the competition noted an increase in the stabilization time of the omega potential. In 15 pentathletes before the competition, weakly expressed QMSS were recorded, and in 11 - expressed QMSS. In the whole group, a decrease in the effectiveness of competitive shooting was observed, compared with the training, but in 15 athletes this decrease was unreliable, while in 11 the accuracy of hitting the target during the competition was significantly lower than during training shooting, against the background of an overall poor performance.

 The generalized results presented in the table can be supplemented with specific observations.

 Example 1. Subject A. Andreev, 19 years old, master of sports in modern pentathlon.

04/13/94, before the control training shooting at 8 a.m., a discrete measurement of the omega potential and graphical registration of the spontaneous dynamics of super slow physiological processes were carried out. The following data were obtained:
the value of the omega potential is discrete. - 31 mV,
omega potential stabilization time - 60 s,
the amplitude of super slow potential oscillations - 1.1 mV,
the severity of super slow fluctuations of potentials - 10%,
the effectiveness of training shooting - 193 points.

04/21/94, before the competition at 8 o’clock in the morning conducted a similar examination. The following data were obtained:
the value of the omega potential is discrete. - 32 mV,
omega potential stabilization time - 180 s,
the amplitude of super slow potential oscillations is 3.1 mV,
the severity of super slow potential oscillations - 20.2%,
competitive shooting performance - 190 points.

 This example shows the conformity of the complex of indicators of SMPP to the optimal functional state of the athlete, confirmed by its high sports performance. The value of the omega potential obtained by discrete measurements also corresponded to the level of optimal wakefulness of the athlete.

 Example 2. Pyshnenko V., 18 years old, candidate of medical science

равна 20%,
где P - период волны, N - количество волн СМКП, T - длительность регистрации, i - волна секундного, декасекундного или минутного диапазонов.02/08/99, at 8 h 30 min, a graphical registration of the spontaneous dynamics of SMPP was carried out. The following data were obtained (Fig. 1, the vertical arrow (A) marks the stabilization time of the omega potential):
omega potential stabilization time - 120 s,
the value of the stabilized omega potential is 30 mV,
intensity of super slow potential oscillations - (1-4 mV),
the severity of super slow potential oscillations,
determined by the formula

equal to 20%
where P is the wave period, N is the number of SMKP waves, T is the duration of registration, i is the wave of the second, decasecond or minute ranges.

 Irregular single waves of the second and decasecond low amplitude ranges (1-2 mV) against the background of average omega potential values (20-40 mV) are the physiological equivalent of the balance of the functional activity of the main regulatory and homeostatic systems and therefore, when calculating the severity, they can be ignored (on omegagram after ih).

 The athlete's optimal condition was confirmed by the data of the SAN test (health, activity, mood) and the trainer's high assessment of the results of training activity.

 Example 3. Pavlov A., 19 years old. c.m.s.

равна 70%.On February 9, 1999, at 8:00 a.m., the spontaneous dynamics of the SMPP was graphically recorded. The following data were obtained (Fig. 2, the vertical arrow (A) marks the stabilization time of the omega potential):
omega potential stabilization time - 330 s,
the value of the stabilized omega potential is 30 mV,
intensity of super slow potential oscillations - (3-13 mV),
the severity of super slow potential oscillations,
determined by the formula

equal to 70%.

 The state of overtraining was confirmed by low SAN test indicators and a decrease in the effectiveness of control training tests.

 A comprehensive analysis of the indicators of the spontaneous dynamics of SMPP for current monitoring has been used by us in the Krasnodar Sports School for Children’s Swimming, Sports School for Modern Pentathlon, Sports School for Athletics and the Climbing and Tourist Club of the Law Institute for more than 10 years. During this time, the method showed a fairly high reliability in predicting the willingness of athletes to implement intense training and competitive activities. However, it should be noted that the doctors of sports schools, when determining the severity of the QMS, prefer a simple calculation of the number of waves during the observation period, instead of calculating according to the well-known formula.

 Example 4. Subject Khorenko I., 19 years old, candidate of medical sciences in modern pentathlon.

04/13/94, before the control firing practice at 8.30 a.m., a discrete measurement of the omega potential and graphical registration of the spontaneous dynamics of super slow physiological processes were carried out. The following data were obtained:
the value of the omega potential is discrete. - 37 mV,
omega potential stabilization time - 243 s,
the amplitude of super slow potential oscillations - 6.2 mV,
the severity of super slow potential oscillations - 70%,
the effectiveness of training shooting - 172 points.

04/21/94, before the competition at 8.30 a.m. a similar survey was conducted. The following data were obtained:
the value of the omega potential is discrete. - 36 mV,
omega potential stabilization time - 480 s,
amplitude of super slow potential oscillations - 7.8 mV,
the severity of super slow potential oscillations - 93%,
the effectiveness of training shooting - 161 points.

 Example 2 shows that under the current control of an athlete, the omega potential values both before training and before the competition corresponded to the optimal level of wakefulness, while the complex of SMPP indicators reflected the tension of mechanisms to compensate for the intensification of the metabolic processes of the body, which was the reason for the decrease in sports performance .

 Thus, as can be seen from the table and examples, a comprehensive analysis of the indicators of spontaneous dynamics of super slow physiological processes more accurately assesses the current functional state in athletes than the prototype.

 The medical and social effect is to increase the recognition accuracy of the athlete’s optimal and non-optimal functional state in order to make the right decision to optimize the training process.

 Compared with the prototype, the proposed method does not require additional hardware, and a slight increase in the duration of the survey is offset by its higher prognostic significance.

Claims (1)

A method for monitoring the athlete’s functional state, including graphical recording of the spontaneous dynamics of omega potential from the surface of the head and a comprehensive analysis of the obtained indicators, characterized in that when the stabilization time of the omega potential is 60–180 s and low intensity 1–2 mV and weakly expressed 10–20% super slow potential fluctuations in determining the severity according to the formula

where P is the period of the wave;
T is the duration of registration,
they consider the athlete’s functional state to be optimal, and with a long stabilization time of omega potential of 240–480 s and intense 6–8 mV and pronounced 70–95% of super slow potential fluctuations determine the state of overtraining.

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