RU2615872C1 - Method for determination of athlete cardiorespiratory system state compliance with selected sport - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: minute respiratory volume is measured in the initial state and at the end of functional exertion with increasing inhalation hypercapnia at carbon dioxide content of 7.5 vol % in the inhaled air. Heart rate is measured n the initial state and at the end of functional exertion with increasing inhalation hypoxia at oxygen content of 11 vol % in the inhaled air. Chemoreactivity fitness index (CFI) of the cardiorespiratory system is calculated by the original formula. If the value of CFI is less than or equal to 40%, the conclusion is made on cardiorespiratory system state compliance with the sport types related to cyclical aerobic muscle activity, accompanied by willed breath delays. If the value of CIF is in the range of 40 to 60% inclusive, the conclusion is made on cardiorespiratory system state compliance with the sport types related to cyclical aerobic muscle activity without willed breath delays. If the value of CFI exceeds 60%, the conclusion is made on cardiorespiratory system state compliance with the sport types related to acyclical aerobic muscle activity with abrupt changes of power or speed load. If the CFI value of an athlete does not correspond to the muscle activity typical for the sport, he/she is engaged with, a conclusion is made on cardiorespiratory system state non-compliance with the selected sport type, it is recommended to select another sport type with CFI value closer to the individual CFI of this athlete.

EFFECT: method allows to determine the cardiorespiratory system state for sport types, detect non-compliance of the cardiorespiratory system state to the selected sport and to recommend the most suitable sport.

4 cl, 1 dwg, 1 tbl, 3 ex

Description

The invention relates to the field of sports physiology and medicine, namely to functional diagnostics, and can be used in sports and preventive medicine centers, restorative medicine rooms to prepare individual recommendations for choosing a sport or sports pursuant to the personalized functional status of the cardiorespiratory system of the body .

There is a method of selecting athletes for sports with a predominant development of endurance, including measuring the diameter of the aortic base in an athlete, characterized in that, in order to improve the accuracy of the method, the left ventricular myocardial mass and the minute blood volume index calculated after testing an athlete individually dosed load, and a conclusion about the prospects of the athlete is made with a value of the aortic diameter of 2.8 cm or more, the mass of the left ventricular myocardium at least 230 g and the index of minutes th volume of blood of not more than 6 (1). The disadvantage of this method is that it does not allow differentiated selection of athletes by sports.

A known method for determining the type of metabolic response of an organism by recording indicators of myocardial contractility with a continuously increasing stepwise load on the body on a bicycle ergometer, followed by calculating the value of the cardiac index at each stage of the load and constructing a dynamic curve, characterized in that the obtained dynamic curve is analyzed and the minimum value the cardiac index on a dynamic curve judges the transition of the body from the anaerobic regimen to aerobic, and the maximum the corresponding value of the heart index is about the type of metabolic response of the body, the maximum value of the heart index in the anaerobic mode corresponds to the sprinter type, the maximum value of the heart index in the aerobic mode corresponds to the styer type, and equal values of the heart index in both modes correspond to the mixed type (2). The disadvantage of this method is that when divided into styers, sprinters and a mixed type, it does not allow to establish the relationship of this separation with specific sports. This is partly due to the fact that the method worked out only for athletes involved in rowing and water polo.

Closest to the claimed one is a method of determining an athlete’s predisposition to athletics with specialization in all-around, including the determination of the sensomotor qualities of athletes, characterized in that athletes are tested using a psychophysiological testing device UPFT-1 / 30- “Psychophysiologist” with an assessment of complex visual-motor reaction by presenting a series of 110 light stimuli with a random distribution of green and red colors, with the first 5 signals consisting of 3 red and 2 green training signals, then they present three groups of signals, consisting of 20 red and 15 green signals, in the first group the red signal is quenched with the “NO” key, the green one with the “YES” key, each subsequent signal is presented 3-5 seconds after the response reactions, in the second group, on the contrary, they red out the red signal with the “YES” key, green - with the “NO” key, each subsequent signal is presented 3-5 seconds after the response, in the third group the green signal is passed, the red signal is extinguished with the “YES” key, green signal exposure 2 s, after the red signal, the next signal is presented after 3-5 s, the device measures the reaction time for each stimulus and the number of erroneous actions with the definition of parameters: average reaction time of the excitation and inhibition processes, the mobility of the nervous processes and the number of errors made on the mobility of the nervous processes, and with an average reaction time of excitation processes of 351.00-373.00 ms, with an average reaction time of inhibition processes of 354.00-386.5 ms, mobility of nervous processes 359.94-407.55 ms, the number of errors in mobility nervous processes 0.83-1.51 athletes are recommended to do athletics with specialization in all-around (3). The disadvantage of this method is that its use is limited to athletics with a specialization in all-around and does not allow its use for other sports. Another disadvantage of the method is that it is limited to determining the visual-motor reaction of an athlete to the light impulse presented and does not take into account the characteristics of the functional reserve of the body, which are key for various sports.

The task to which the claimed invention is directed is the expansion of sports to which the athlete's predisposition is determined.

The technical result is to determine the conformity of the state of the cardiorespiratory system to sports that differ in the nature of muscle activity: cyclic aerobic muscle activity, accompanied by volitional breath holdings (swimming, etc.); cyclic aerobic muscle activity without volitional breath holdings (skiing, biathlon, running and medium and long distance walking, etc.); acyclic muscle activity with sharp changes in the load power of a power or speed direction (boxing, wrestling, weightlifting, etc.).

The solution to this problem is achieved by measuring the minute volume of respiration and heart rate during a functional load in a state of muscular rest, minute volume of respiration is measured in the initial state and at the end of a functional load with increasing inhalation hypercapnia with a carbon dioxide content of 7.5 vol. % in the composition of the inhaled air, the heart rate is measured in the initial state and at the end of the functional load with increasing inhalation hypoxia at an oxygen content of 11 vol. % in the composition of the inhaled air; evaluate the chemoreactive fitness index of the cardiorespiratory system of the body according to the formula:

where MODv is the minute volume of breathing in the initial state when breathing with ordinary air, l / min; MODGk - minute volume of respiration l / min with hypercapnia for the level of 7.5 vol. % carbon dioxide in inhaled air; ChSSv - heart rate in the initial state, beats / min when breathing with ordinary air; ChSSg - heart rate, beats / min with hypoxia for a level of 11 vol. % oxygen in the composition of the inhaled air; when the value of CI is less than or equal to 40%, a conclusion is drawn on the correspondence of the state of the cardiorespiratory system to sports associated with cyclic aerobic muscle activity, accompanied by volitional breath holdings; with a CI value in the range of more than 40% to 60% inclusive - on the compliance of the cardiorespiratory system with sports associated with cyclic aerobic muscle activity without volitional breath holdings; with a HIT value of more than 60% - on the conformity of the state of the cardiorespiratory system to sports associated with acyclic muscle activity with sharp changes in the load power of a power or speed direction; if the athlete’s HIT does not correspond to the type of muscular activity characteristic of the sport he is engaged in, they conclude that the state of his cardiorespiratory system does not match the chosen sport, it is recommended to choose another sport, the HIT value for which is closest to the athlete’s individual HIT; sports associated with cyclic aerobic muscle activity, accompanied by volitional breath holding, include swimming; sports associated with cyclic aerobic muscle activity without volitional breath holding include skiing, running and medium and long distance walking, biathlon; sports associated with acyclic exercises with sharp changes in the load power of a power or speed direction include boxing, wrestling, weightlifting.

Disclosure of invention

A method for determining the compliance of an athlete’s cardiorespiratory system with a selected sport involves measuring the minute volume of respiration and heart rate in a state of muscle rest. Minute breathing volume is measured in the initial state and at the end of the functional load with increasing inhalation hypercapnia with a carbon dioxide content of 7.5 vol. % in inhaled air. The heart rate is measured in the initial state and at the end of the functional load with increasing inhalation hypoxia with an oxygen content of 11 vol. % in inhaled air. Then evaluate the chemoreactive fitness index of the cardiorespiratory system of the body according to the formula:

where MODv is the minute volume of breathing in the initial state when breathing with ordinary air, l / min; MODGk - minute volume of respiration l / min with hypercapnia for the level of 7.5 vol. % carbon dioxide in inhaled air; ChSSv - heart rate in the initial state, beats / min when breathing with ordinary air; ChSSg - heart rate, beats / min with hypoxia for a level of 11 vol. % oxygen in inhaled air. With a value of ChIT less than or equal to 40%, a conclusion is drawn on the correspondence of the state of the cardiorespiratory system to sports associated with cyclic aerobic muscle activity, accompanied by volitional breath holdings. With a CI value in the range of more than 40 and up to 60% inclusive, they conclude that the state of the cardiorespiratory system conforms to sports associated with cyclic aerobic muscle activity without volitional breath holdings. With a HIT value of more than 60%, a conclusion is drawn on the correspondence of the state of the cardiorespiratory system to sports associated with acyclic muscle activity with sharp changes in the load power of a power or speed direction. If the athlete’s HIT does not match the type of muscular activity characteristic of the sport he is engaged in, they conclude that the state of his cardiorespiratory system does not match the chosen sport, it is recommended to choose another sport, the HIT value for which is closest to the athlete’s individual HIT.

Sports associated with cyclic aerobic muscle activity, accompanied by volitional breath holding, include swimming. Sports associated with cyclic aerobic muscle activity without volitional breath holding include skiing, running and medium and long distance walking, and biathlon. Sports associated with acyclic exercises with abrupt changes in the load power of a power or speed direction include boxing, wrestling, weightlifting.

When carrying out a functional load with increasing inhalation hypercapnia, the oxygen content in the reservoir for breathing is artificially maintained at a constant level of 30 vol. %

When carrying out a functional load with increasing inhalation hypoxia, the oxygen content in the reservoir for breathing is gradually reduced for 20 minutes from its level in atmospheric air to 11 vol. %

The first is a functional load with increasing inhalation hypercapnia, then the functional load with increasing inhalation hypoxia, because the recovery period after a state of hypoxia is quite long, which significantly increases the time required to implement the claimed method.

The break between the first and second functional loads is at least 30 minutes to restore the heart rate and minute volume of breathing to the initial level.

The functional load with increasing inhalation hypercapnia is carried out by the method of return breathing to an elastic closed container, and the oxygen content in the container is artificially maintained during the functional load at a constant level of 30 vol. %

The functional load with increasing inhalation hypoxia is carried out by breathing from a closed container, initially filled with atmospheric air, and during the functional load, the oxygen content in the tank is gradually reduced to 11 vol. Over 20 minutes. %

Before the start of the examination, the athlete can get used to the conditions of the room with a temperature of 23-25 ° C for 30 minutes, then the initial heart rate and MOD are measured before the start of the functional load.

The functional load with increasing inhalation hypercapnia is performed according to the standard scheme with return breathing to a 5-liter capacity pre-filled with a gas mixture of the composition: 5 vol. % carbon dioxide - CO ₂ , 30 vol. % oxygen - O ₂ and 60 vol. % nitrogen - N ₂ (4). During this functional load, the concentration of O ₂ in the tank is artificially maintained at 30 vol. % with its continuous control in gas samples from the tank by any suitable gas analyzer, for example, as part of an Oxycon Pro® ergospirometric system. Moreover, the concentration of CO ₂ is also continuously recorded using any capnograph or a suitable gas analyzer, for example, as part of an Oxycon Pro® ergospirometric system. Upon reaching a concentration of CO ₂ 7.5 vol. % in the composition of the inhaled air, the examination is completed and the values of the MOD parameters are recorded.

After a 30 minute break necessary to restore the MOD and heart rate to the initial level, the subject breathes through the mask for 5 minutes with ordinary air. After that, continuous registration is carried out for 5 minutes, heart rate, followed by averaging the values of heart rate indicators for the initial state (heart rate). Then, a functional load is carried out with increasing inhalation hypoxia in a prolonged modification with a smooth decrease in the content of O ₂ in the respiratory mixture according to (5, 6). To do this, use a container with a volume of 250 l, which is initially filled with atmospheric air and connected to a source of a hypoxic gas mixture with a concentration of O ₂ 10 vol. % in N ₂ , for example, with a gas cylinder with the desired concentration of the gas mixture, or with the outlet of a hypoxicator - a device converted from NewLife oxygen concentrator from AirStep (USA) according to utility model certificate No. 24098 of July 27, 2002. With the onset of hypoxic exposure include the supply of a gas mixture with a constant and excess relative to pulmonary ventilation flow (15 l / min), which allows you to standardize the dynamics of hypoxic exposure for all examined individuals. After 20 minutes at a concentration of O ₂ in the inhaled mixture of 11 vol. % measure heart rate. Optimal is a fourfold registration of heart rate within a minute, followed by averaging to reduce the effect of the current variability of the indicator. In the formula substitute the heart rate in the initial state (heart rate) and at the end of the functional load (heart rate).

The invention is illustrated in the drawing. The results of calculations of average HIT values and a 95% confidence interval for individual intragroup changes in HIT obtained for the three examined groups of athletes. Designations: the squares on the tops of the columns denote the average values of HIT for each group; vertical segments with them - ± 95% confidence interval; horizontal arrows indicate the intergroup dividing levels of HIT: arrow I with a HIT value of 60% distinguishes between athletes of group 2 from group 3, and arrow II with a HIT value of 40% distinguishes athletes from group 1 from group 2.

The implementation of the invention

36 athletes were examined, divided into the following groups:

Group 1 - athletes involved in sports associated with cyclic anaerobic muscle activity, accompanied by volitional breath holdings: swimming - 12 people.

Group 2 - athletes involved in sports associated with cyclic aerobic muscle activity without volitional breath holdings: skiing for medium and long distances - 11 people.

Group 3 - athletes involved in sports associated with acyclic muscle activity with sharp changes in the load power of a power or speed direction: a total of 13 people, including boxing - 5 people, wrestling - 5 people; weightlifting - 3 people.

Each athlete successively underwent functional loads according to the claimed method with increasing inhalation hypercapnia and increasing inhalation hypoxia, followed by an assessment of the individual chemoreactive fitness index (CIT) of the cardiorespiratory system of the body. The drawing shows the average values of HIT for each group of athletes, their fluctuations within 95% of the intragroup confidence interval of HIT values, and also determined the boundary values of HIT, indicated by arrows I and II.

The table below shows the average HIT values for each of the groups of athletes and the boundaries of the HIT values within the group. As can be seen from the drawing and the table, the three indicated types of muscle activity clearly differ in the response of the cardiorespiratory system, assessed by the HIT index, which allows using the HIT value to determine whether the state of the cardiorespiratory system corresponds to sports characterized by the corresponding type of muscular activity.

Example 1. Athlete N., swimmer. According to the claimed method, HIT = 29. A conclusion was drawn on the conformity of the state of the cardiorespiratory system to the chosen sport, which is confirmed by the fact that the indicated athlete has the title of Honored Master of Sports and is a prize winner of the Olympic Games.

Example 2. Athlete K., a swimmer. According to the claimed method, HIT = 37. A conclusion has been drawn on the conformity of the state of the cardiorespiratory system to the chosen sport, which is confirmed by the fact that the indicated athlete has the title of Honored Master of Sports of the international class and is a winner of the World Cup.

Example 3. Athlete G., swimmer. According to the claimed method, HIT = 43. It was concluded that the state of the cardiorespiratory system did not match the chosen sport, which is confirmed by the fact that the specified athlete has a second sports category, during long training sessions, he did not reach a higher sports category. It is recommended to choose a sport associated with cyclic aerobic muscle activity without volitional breath holdings (skiing, running and medium and long distance walking, biathlon).

Example 4. Athlete B., skiing. According to the claimed method, HIT = 54. A conclusion was drawn on the conformity of the state of the cardiorespiratory system to the chosen sport, which is confirmed by the fact that the indicated athlete is a master of sports and a prize winner of the Universiade of Russia.

Example 5. Athlete G., skiing. According to the claimed method, HIT = 56. A conclusion was drawn on the conformity of the state of the cardiorespiratory system to the chosen sport, which is confirmed by the fact that this athlete is a master of sports and a prize winner of the Russian Universiade.

Example 6. Athlete B., skiing. According to the claimed method, HIT = 38. It was concluded that the state of the cardiorespiratory system did not match the chosen sport, which is confirmed by the fact that the specified athlete has a second sports category, during long training sessions, he did not reach a higher sports category. It is recommended to choose a sport associated with cyclic aerobic muscle activity, accompanied by volitional breath holdings (swimming).

Example 7. Athlete E. Cross-country skiing. According to the claimed method, HIT = 61. It was concluded that the state of the cardiorespiratory system did not match the selected sport, which is confirmed by the fact that the indicated athlete has the third sports category, during long training sessions, he did not reach the higher sports category. It is recommended to choose a sport associated with acyclic muscle activity with sharp changes in the load power of the power and speed direction (boxing, wrestling, weightlifting).

Example 8. Athlete L., middle and long distance running. According to the claimed method, HIT = 40. It was concluded that the state of the cardiorespiratory system did not match the selected sport, which is confirmed by the fact that the specified athlete has the first sports category, during long training sessions, he did not reach the higher sports category. It is recommended to choose a sport associated with cyclic aerobic muscle activity, accompanied by volitional breath holdings (swimming).

Example 9. Athlete F., wrestling. According to the claimed method, HIT = 69. A conclusion was drawn on the conformity of the state of the cardiorespiratory system to the chosen sport, which is confirmed by the fact that this athlete is a master of sports, winner of the Russian championship.

Example 10. Athlete E. Boxing. According to the claimed method, HIT = 67. A conclusion was drawn on the conformity of the state of the cardiorespiratory system to the chosen sport, which is confirmed by the fact that this athlete is a candidate for master of sports, a participant in the Russian championship.

Example 11. Athlete I., wrestling. According to the claimed method, HIT = 51. It was concluded that the state of the cardiorespiratory system did not match the chosen sport, which is confirmed by the fact that the specified athlete has the third sports category, during long training sessions, he did not reach the higher sports category.

Example 12. Athlete E. Wrestling. According to the claimed method, HIT = 59. It was concluded that the state of the cardiorespiratory system did not match the chosen sport, which is confirmed by the fact that the specified athlete has the third sports category, during long training sessions, he did not reach the higher sports category. It is recommended to choose a sport associated with cyclic aerobic muscle activity without volitional breath holdings (skiing, running and medium and long distance walking, biathlon).

The results obtained indicate that the claimed method allows you to identify the discrepancy of the status of the athlete’s cardiorespiratory system to his chosen sport and recommend changing the type of port, if during sports training the HIT value does not come in line with that typical for athletes of this sport.

The claimed method can serve as a basis for recommendations when choosing or changing types of sports activities in accordance with the personalized functional status of the cardiorespiratory system of the body.

List of sources used

1. Patent for the invention of the Russian Federation No. 2092100 “Method for the selection of athletes for sports with a predominant development of endurance. Publ. 10/10/1997. IPC А61В 5/02.

2. Patent for the invention of the Russian Federation No. 2108743 "Method for determining the type of metabolic response under load." Publ. 04/20/1998. IPC А61В 5/02.

3. Patent for the invention of the Russian Federation No. 2444992 "Method for determining the predisposition of athletes to athletics, specializing in all-around." Publ. 03/20/2012. IPC А61В 5/16.

4. Read D.J.C. A clinical method for assessing the ventilatory response to carbon dioxide. // Australas Ann. Med. 1967. V. 16. P. 20.

5. Krivoshchekov S. G., Divert V. E., Melnikov V. N. et al. Comparative analysis of gas exchange reactions and the cardiorespiratory system of swimmers and skiers on increasing normobaric hypoxia and physical activity // Human Physiology. 2013.Vol. 39, No. 1. S. 117.

6. Divert V.E., Krivoshchekov S.G. Cardiorespiratory reactions in case of increasing normobaric inhalation hypoxia in a healthy person // Human Physiology. 2013.Vol. 39, No. 4. S. 82.

Claims (6)

1. The method of determining the compliance of the state of the athlete’s cardiorespiratory system with the chosen sport, including determining the body’s response to the functional load, characterized in that the minute volume of respiration and heart rate are measured at the functional load in the state of muscular rest, the minute volume of respiration is measured in the initial state and at the end of the functional load with increasing inhalation hypercapnia with a carbon dioxide content of 7.5 vol. % in the composition of the inhaled air, the heart rate is measured in the initial state and at the end of the functional load with increasing inhalation hypoxia at an oxygen content of 11 vol. % in the composition of the inhaled air; evaluate the chemoreactive fitness index of the cardiorespiratory system of the body according to the formula:

, where MODv is the minute volume of breathing in the initial state when breathing with ordinary air, l / min; MODGk - minute volume of respiration l / min with hypercapnia for the level of 7.5 vol. % carbon dioxide in inhaled air; ChSSv - heart rate in the initial state, beats / min when breathing with ordinary air; ChSSg - heart rate, beats / min with hypoxia for a level of 11 vol. % oxygen in the composition of the inhaled air; when the value of CI is less than or equal to 40%, a conclusion is drawn on the correspondence of the state of the cardiorespiratory system to sports associated with cyclic aerobic muscle activity, accompanied by volitional breath holdings; with a CI value in the range of more than 40 and up to 60% inclusive - on the compliance of the cardiorespiratory system with sports associated with cyclic aerobic muscle activity without volitional breath holdings; with a HIT value of more than 60% - on the conformity of the state of the cardiorespiratory system to sports associated with acyclic muscle activity with sharp changes in the load power of a power or speed direction; if the athlete’s HIT does not correspond to the type of muscular activity characteristic of the sport he is engaged in, they conclude that the state of his cardiorespiratory system does not match the chosen sport, it is recommended to choose another sport, the HIT value for which is closest to the athlete’s individual HIT. 2. The method according to p. 1, characterized in that the sports associated with cyclic aerobic muscle activity, accompanied by volitional breath holding, include swimming. 3. The method according to p. 1, characterized in that the sports associated with cyclic aerobic muscle activity without volitional breath holding include skiing, running and medium and long distance walking, biathlon. 4. The method according to p. 1, characterized in that the sports associated with acyclic exercises with sharp changes in the load power of a power or speed direction include boxing, wrestling, weightlifting.

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