RU2467681C2 - Method for detecting latent functional cardiovascular disease in sportsman - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention refers to medicine, specifically to sports medicine. Before a training session or a sporting competition, a sportsman counts a number of rest contractions for at least 1 minute and records the value, then the sportsman makes at least 5 deep and fast respiratory movements, and counts a number of contractions for at least 1 minute and records the value. The values of rest contractions and contractions are matched. If a difference of the derived number of contractions and the number of rest contraction is more than 10, the functional cardiovascular state is considered to be good, and the sportsman may start training sessions or competitions; if the difference of the derived number of contractions and the number of rest contractions is between 0 and 9, the functional cardiovascular state is considered to be satisfactory, the sportsman may start training sessions or competitions with decreased load, while the difference of the derived number of contractions in relation to the number of rest contractions is less than 0 the functional cardiovascular state is stated to be unsatisfactory, and training sessions or competitions are contraindicated.

EFFECT: method enables detecting latent functional cardiovascular disease in the sportsman.

2 cl, 4 ex

Description

The invention relates to medicine, namely to sports medicine, and can be used to determine the hidden functional insufficiency of the athlete’s cardiovascular system (CVS) before starting his training or competition.

It is known that the functional state of CVS can be determined by an electrocardiogram (ECG). However, the ECG assesses the functional state of CVS at rest.

A known method of monitoring the functional state of a biological object (see p. No. 2191539, RU, op. October 27, 2002). In the known method, an ECG is recorded, then the duration of each respiratory wave and the sequence of the respiratory waves are determined. The known method can be used to recognize the phases of health and pre-disease in sports medicine, however, the method is quite complicated.

A known method for determining the functional state of the body (see p. No. 2204318, RU, op. 05.20.2003). In the known method measure the number of contractions of the heart muscle (heart rate) at rest. Heart rate is measured after physical exertion and psycho-emotional and physical effects. Squats or inclinations are used as physical activity. And they are subjected to psycho-emotional and physical effects in the form of some kind of activity, for example, attendance at a lecture, lesson, meeting, performance of work duties, etc. The difference between heart rate changes as a result of physical activity and psycho-emotional and physical effects is determined. If this difference is positive or equal to zero, then the influence of the psychoemotional and physical effects on the functional state of the human body is evaluated as positive. If this difference is less than zero, then the effect is evaluated as negative. If the difference is less than zero, then the effect is evaluated as negative. However, the claimed method is used to determine the functional state of the whole organism.

There is a method of quantifying the cost-effectiveness of the functioning of the respiratory system (see item No. 2392854, RU, op. June 27, 2010). In the known method, the tidal volume in liters and the number of respiratory movements in one minute are determined. The known method extends the diagnostic capabilities of assessing the functional state of a person by evaluating the cost-effectiveness of the functioning of the respiratory system, however, the method is quite complicated.

A known method for assessing the functional state of people with disabilities with pathology of the lower extremities and the choice of the type and intensity of physical activity in the rehabilitation process (see No. 2361524, RU, op. 07.20.2009). In the known method determine the tolerance of physical activity by a disabled athlete, determining the effect of physical activity on the athlete's CVS. To do this, a functional examination is carried out, in which blood pressure is measured, heart rate is calculated for a certain time interval, then the Ruffier index is calculated. At the same time, a disabled athlete receives physical activity in the form of push-ups. The functional state of an athlete's CVS can be determined by the influence of physical activity on his CVS. However, this method does not allow to determine the latent functional insufficiency of CCC. During physical activity, to some extent, the adaptation of the athlete's CVS to physical activity occurs and changes in the functional state of the athlete's CVS occur gradually. And, in addition, usually, physical activity is designed to assess the physical fitness of an athlete. This method is chosen as the closest analogue.

The objective of the invention is to develop such a method for determining the hidden functional insufficiency of the athlete's CVS, which is not determined by the ECG at rest, and which is easy to use, at the same time gives simple, expressed in numbers, indicators of the CVS performance, and which allows the athlete , before his training or competition, to determine the latent functional insufficiency of his CVS.

The technical result of the invention is to simplify the implementation of the method and reduce the amount of information obtained with it to the level of the minimum necessary, to obtain a new technical result, which consists in improving the quality of the training, since the determination of the latent functional insufficiency of the athlete's CVS makes it possible to predict the load of the athlete during training, which , ultimately, determines the increase in the effectiveness of training, or to take the necessary measures to exclude Opportunities for the development of functional insufficiency of an athlete's CVS. In the end, this will eliminate the pathological changes in the athlete's CVS, which are possible with high physical exertion both during training and during the competition.

This is achieved by the fact that in the method for determining the hidden functional insufficiency of the athlete’s cardiovascular system, including measuring the number of contractions of the heart muscle for a certain period of time before and after loading on the athlete’s body, according to the invention, respiratory movements are used as the load, moreover, the athlete before training or competition, at rest, counts the number of contractions of the heart muscle for at least 1 minute and fixes its value, then the athlete makes at least five deep and quick respiratory movements, calculates the number of contractions of the heart muscle for at least 1 minute and fixes its value, then compares the value of the number of contractions of the heart muscle at rest and the obtained number of contractions of the heart muscle according to the degree of growth of the latter, and evaluates the functional state of your cardiovascular system: if the difference in the number of contractions of the heart muscle and the number of contractions of the heart muscle at rest is more than 10, the functional state the cardiovascular system is good and the athlete can start training or competition if the difference in the number of contractions of the heart muscle and the number of contractions of the heart muscle at rest is greater than 0, but less than 9 - the functional state of the cardiovascular system is satisfactory, the athlete can begin training or competition, but the athlete’s load should be reduced, and if the difference in the number of contractions of the heart muscle in relation to the number of contractions of the heart muscle in less than 0 - the functional state of the cardiovascular system is unsatisfactory and training or competition is contraindicated.

In addition, forced breathing is used as respiratory movements.

In addition, the number of cardiac muscle contractions at rest, the obtained number of cardiac muscle contractions after respiratory movements, and the difference in the number of cardiac muscle contractions obtained in relation to the number of cardiac muscle contractions at rest, the trainer writes to the training diary and evaluates the dynamics of the athlete’s CVS functional state over the course of the entire training period.

Forced breathing is known. Forced breathing is associated with excessive activation of the respiratory muscles; the breath is usually noisy, out of breath; exhalation is characterized by significant pressure of the muscles. Under the influence of such frequent respiratory movements, there is a rapid decrease in carbon dioxide in the lungs and arterial blood. This is followed by a decrease in the tone of peripheral vessels, a drop in arterial and pulse pressure, a change in blood circulation in the vessels of the heart and brain, a change in heart rate: heart rate increases. Forced breathing is also a burden for CVS, but changes in the functional state of the CVS occur quickly, adaptation of the CVS to the load is excluded, and the activity of the CVS is evaluated during the functioning of the body.

It was experimentally determined that to determine the latent functional insufficiency of an athlete's CVS it is enough to do at least five deep and quick breathing movements with forced breathing.

Experimentally, with the help of electrocardiography, the athlete’s CCC reactions to the respiratory load were also determined, indicating deviations from the normal functional state of the CCC. It was found that the inventive method allows to obtain information about the state of the CCC, not recorded on the resting ECG. The study was conducted 82 times in 40 skaters and hockey players aged 18 to 25 years. All participants in the study are practically healthy, have been engaged in the chosen sport for more than five years. The inventive method is the result of lengthy observations and subsequent reflection, which makes it possible to use the accumulated experience.

The method is carried out in the following way.

The training process is led by a trainer. The trainer determines the training load for the athlete and keeps a training diary. In the training diary, the trainer reflects the number of contractions of the heart muscle at rest (HR1) and the number of contractions of the heart muscle (HR2) of each athlete, the difference in these readings and the assessment of the difference to determine the functional state of the CVS. Analysis of the obtained data allows the trainer to determine the dynamics of the functional state of the CVS of each athlete and in time to identify the latent functional insufficiency of the CVS of each athlete. This is especially important before the competition. The loads on the competition are extreme. And the coach, already before the competition, knows about the presence or absence of the athlete's latent functional insufficiency of his CVS. This will allow the athlete, for example, hockey players or football players, to exclude the consequences of the competition, even the most unfavorable.

Before starting a training session, at rest, the athlete counts heart rate (HR1) for at least 1 minute to determine the initial functional state of his heart rate. The trainer records heart rate in the training diary. Then the athlete performs forced breathing in the form of at least 5 respiratory movements, and immediately calculates his heart rate (HR2) for at least 1 minute. The trainer records heart rate in the training diary. Then the athlete evaluates the functional state of his CVS. To do this, subtract heart rate from heart rate2, and the trainer fixes the received difference in the training diary and evaluates the received heart rate difference. According to the data received, the coach determines what the athlete needs. The difference in heart rate is greater than 10 - the CVS response is adequate. Hidden functional insufficiency of CVS in an athlete is absent. An athlete may begin training or competition. The difference in heart rate is greater than 0, but less than 9 - CVS is not able to adequately compensate for the resulting deterioration in the functional state of CVS. For such athletes, it is necessary to revise the training plan and physical activity during training or to change the task facing the athlete during training. The heart rate difference is less than 0 - there is a hidden functional insufficiency of the heart rate. The athlete's CVS is not able to compensate for the resulting deterioration in the functional state of the CVS. The athlete needs an in-depth examination of his CVS. Assessing the obtained data in dynamics throughout the training period, the coach has the opportunity to determine the prospects of the athlete for his participation in the competition.

Example 1. Skater. Age 20 years old. Heart rate 1 = 62, heart rate 2 = 76. The difference in heart rate = 14 (more than 10). The athlete is ready to perform physical activity and can begin to train or to compete.

Example 2. Hockey player. Age 18 years old. Heart rate 1 = 68, heart rate 2 = 71. Heart rate difference = 3 (greater than 0). Complaints of lethargy. It is necessary to revise the training plan, reduce the level of physical activity.

Example 3. Hockey player. Age 22 years old. Heart rate 1 = 66, heart rate 2 = 73. The difference in heart rate = 7 (less than 9). Complaints of fatigue. It is necessary to revise the training plan, reduce the level of physical activity.

Example 4. Skater. Age 25 years. It was a cold illness. Heart rate 1 = 67, heart rate 2 = 62. Heart rate difference = less than 0 (-5). Indicates the presence of functional insufficiency of the athlete's CVS. There is a pathology of CVS. The athlete needs an in-depth examination.

The inventive method is simple, convenient, safe for health and allows you to evaluate the functional state of the athlete's CVS on the basis of the here and now principle. The method allows you to get specific benefits with its skillful use, especially skaters, skiers, biathletes, hockey players and soccer players. Repeated observations showed that the claimed method allowed to improve athletic performance in these athletes. The quality of training has improved. In addition, the method can be used for athletes with disabilities. In this case, athletes with disabilities do not need to perform physical exercises, they do not need various devices for recording the status of CVS, and complex calculations are not needed to assess the status of CVS, as, for example, in the prototype. In addition, the inventive method is available for implementation in healthcare during mass inspections. A technical result is achieved that satisfies a long-existing need, attempts to obtain which for a long time did not succeed specialists.

Claims (2)

1. A method for determining the hidden functional insufficiency of the athlete’s cardiovascular system in hockey or speed skating, including measuring the number of contractions of the heart muscle before and after exercise, characterized in that respiratory movements are used as the load, and the athlete counts before training or competition at rest the number of contractions of the heart muscle for at least 1 min and fixes its value, then the athlete makes at least 5 deep and quick respiratory movements, counts the number of contractions of the heart muscle for at least 1 min and fixes its value, then compares the value of the number of contractions of the heart muscle at rest and the obtained number of contractions of the heart muscle according to the degree of growth of the latter and according to the data it estimates the functional state of its cardiovascular system: if the difference the obtained number of contractions of the heart muscle and the number of contractions of the heart muscle at rest is more than 10 - the functional state of the cardiovascular system is good and the athlete can proceed to training or competition, if the difference between the number of contractions of the heart muscle and the number of contractions of the heart muscle at rest is greater than 0, but less than 9 - the functional state of the cardiovascular system is satisfactory, the athlete can begin training or competition, but the athlete's load should be reduced and if the difference in the number of contractions of the heart muscle with respect to the number of contractions of the heart muscle at rest is less than 0, the functional state of the cardiovascular system we are unsatisfactory and training or competition is contraindicated. 2. The method according to claim 1, characterized in that forced breathing is used as respiratory movements.