RU2186516C1 - Method of controlling and restricting outer loads - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: method involves providing continuous diagnosis of human organism state including controlling pulse rate fp and breathing frequency fb ratio and dispersing this ratio or informational Fisher factor of this ratio. In case fp/fb ratio is less than 3 or greater than 5 and increase of dispersion or informational Fisher factor exceeds 20% with respect to initial state, action of load is to be reduced or stopped. Method allows admissible limits for outer loads to be determined and limited for each individual. EFFECT: increased efficiency and simplified method. 2 cl, 1 dwg, 4 ex

Description

 The invention relates to medicine, in particular to methods for monitoring, dosing and limiting external loads, including sports, medication, environmental, physiotherapy, psychological and other loads that affect a person’s functional state and health.

 There are various methods and devices for monitoring and diagnosing the functional state of the human body and its subsystems [1].

 However, the methods of monitoring, functional diagnostics, diagnostics by the methods of Voll, Reodoraku, Nakatani, etc. do not allow to control the reaction of the patient or athlete directly during physical activity, physiotherapeutic effect or they are not labile and informative for the purpose of individual control and dosing of such effects. The analysis of heart rate rhythms, Holter ECG monitoring and daily monitoring of blood pressure and body temperature, which are used to control system-wide reactions, vegetative status and tension, due to the large individual variability of the recorded parameters, are also not suitable for assessing the maximum permissible exposure levels, functional training load.

 By technical nature, the closest to the proposed method is a method of monitoring and limiting external loads, which consists in calculating the stress index according to Baevsky [2].

 However, the known method does not allow you to quickly and accurately determine the individually permissible boundaries of external loads, which can lead to untimely limitation.

 The technical result is the creation of a method that allows you to accurately determine the individually permissible boundaries of external loads, for their timely limitation.

This is achieved by the fact that in the method of monitoring and limiting external loads, which consists in continuously diagnosing the state of the human body, in which the ratio of the pulse rate f _p to the respiratory rate f _d and the dispersion of this ratio are controlled, according to the invention, when f _p / f _{d is} less than 3 or greater than 5 and an increase in the dispersion of this ratio by more than 20% relative to the initial state before the onset of external load during a time not less than the duration of the transition process characteristic of the body’s reaction to the effect of the external load, reduce or stop the external load, or take preventive measures to normalize the above indicators, in addition, the transition time for the reaction of the body to the action of the external load is chosen equal to at least 20 respiratory cycles.

In addition, this is achieved by the fact that in the method of monitoring and limiting external loads, which consists in the continuous diagnosis of the state of the human body, in which the ratio of the pulse rate f _p to the respiratory rate f _d and the Fisher information indicator of this ratio, according to the invention, with f _p / f _d is less than 3 or greater than 5 and an increase in information rate Fischer this ratio is more than 20% relative to the initial state prior to the action of the external load for a time duration not less than n rehodnogo process characteristic of the body's reaction to the action of the external load, decrease, or stop an external load or take preventative measures to normalize the above figures, moreover, the transient time for the reaction of the organism to the action of the external load is selected to be not less than 20 respiratory cycles.

 The essence of the invention lies in the fact that the choice of the appropriate range of the ratio of the pulse rate to the respiratory rate and at the same time an allowable increase in dispersion or Fisher's information indicator allows for various living organisms to prevent the development of undesirable reactions in a timely manner by reducing, terminating external exposure or taking appropriate preventive measures.

 Comparison of the proposed method with the closest analogue allows us to claim compliance with the criterion of "novelty", and the absence of distinctive features in the analogues indicates compliance with the criterion of "inventive step".

 The experiments using the proposed method allow us to judge the possibility of its widespread use.

 The drawing shows a functional block diagram of a device that implements the inventive method.

The device contains heart rate and respiration sensors 1 and 2, respectively, which are connected through amplifiers 3 and 4 and analog-to-digital converters 5 and 6 to a division unit 7, which divides the current value of the pulse frequency f _p by the current value of the respiratory frequency f _d . The output of the division unit 7 is connected to the input of the calculator 8 and through the comparators 9 and 10 the minimum and maximum limits to the first and second input of the OR element 11, the outputs of the dispersion comparators 12 and 13 and the Fisher information indicator are respectively connected to the third and fourth control inputs of it. The first and second outputs of the calculator 8 are connected respectively to the blocks 14 and 15 of the memory of the variance and the Fisher information indicator, the outputs of which are connected to the corresponding reference inputs of the comparators 12 and 13, the other inputs of which are connected respectively to the third and fourth outputs of the calculator 8. The output of the element "OR "11 is connected to the block 16 of the light and sound indications and through the switch 17 to the input of the apparatus 18 of physiotherapeutic or other physical effects. In addition, the device contains a counter 19 of the number of respiratory cycles and the trigger 20 controls the element "OR" 11.

As a calculator 8, any microprocessor “flashed” in accordance with the formula for calculating the variance and the Fisher information indicator I = N / σ ² , where σ ² is the dispersion and N is the number of respiratory cycles) can be used.

 As blocks 14 and 15 memories can be used any ROM.

The proposed method for monitoring and limiting external loads is to continuously diagnose the state of the human body, in which the ratio of the pulse rate f _p to the respiratory rate f _d and the variance of this ratio or Fisher’s information indicator are monitored.

In addition, a feature of the proposed method is that when the value of f _p / f _{d is} less than 3 or greater than 5 and the dispersion or the Fisher information index increases, this ratio is more than 20% relative to the initial state before the onset of external load through the transition process, or stop, or take preventive measures to normalize the above indicators.

 At the same time, the transition process characteristic of the reaction of the organism to the action of an external load is chosen equal to 20 respiratory cycles.

 It should be noted that control over changes in dispersion is carried out only when the time periods for its assessment before physical exposure and after physical exposure are the same, for example, 20 respiratory cycles.

 If the time periods of the assessment are significantly different, for example, when assessing long-term impacts for tens of minutes or even days, then instead of controlling the variance, an assessment is made by changing the Fisher information indicator.

 The choice of an estimation by dispersion or by Fisher's information indicator can be carried out automatically (software) in the manufacture of the device.

 The proposed method is implemented as follows.

The signals from the sensors 1 and 2 of the pulse and respiration through amplifiers 3 and 4 and the ADC 5 and 6 are fed to the division unit 7 to calculate f _p / f _d , from the output of which the ratio values are fed to the inputs of the comparators 9 and 10 and the calculator 8. In the last the variance of the ratio f _p / f _d and the Fisher information index of this ratio are calculated.

 Prior to the start of the external load, the variance and Fisher exponent are recorded in memory blocks 14 and 15, respectively.

 After a time longer than the duration of the transition process characteristic of the body's response to an external load, specifically 20 respiratory cycles, the counter 19 sets the trigger 20 to a state that allows the "OR" 11 to transmit a signal to the block 16 and the switch 17, which controls the operation of the source 18.

The time for which the variance f _p / f _d is calculated before and after external exposure, it is advisable to take more than the duration of 20 (twenty) respiratory cycles, since this is the characteristic duration of the transition process in the circuit for regulating heart rate and respiration. If the external load lasts for more than 20 respiratory cycles (in most cases this is the case), then with each subsequent respiratory cycle the dispersion value can change, but only its current value, which exceeds the dispersion value calculated by the beginning more than 20%, is critical external load and stored in block 14 of the memory. The Fisher information indicator f _p / f _d and the comparison of its current value with the value stored in the memory unit 15 is used in the case when the calculation time of its value before and during external load is different. For example, when monitoring the effects of prolonged external influences, it is advisable to take the time for calculating the changes within a few hours or per day.

 The control of such types of external loads can include the effects of magnetic storms, weather changes, various environmental loads (noise, vibration, electromagnetic fields, increased radioactive background, changes in chemical and gas composition and other environmental parameters), emotional stress, especially in children, action extreme conditions (work of the driver of the vehicle, pilot of the plane, astronaut, engineer, miner, diver, climber, installer, high altitude surgeon, surgeon during the operation, human operator a, dispatcher, etc.).

 The normalized form of the Fisher information indicator, in contrast to the variance, allows one to correctly compare different times of its calculation before and during external load.

 The usefulness of the proposed method lies in the possibility of detecting preclinical disorders of the functional state and health of a person, in the possibility of predicting adverse reactions (errors, accidents) and their timely prevention, prevention of health disorders or overdose of a physiotherapeutic or sports training load.

Example 1. Patient S. 66 years. Trophic ulcer of the left tibia 5 cm ² . During the electrotherapy session, 15 minutes after the start of electrical stimulation of the ulcer area, the light and sound indication of ill-being turned on (red LED and sound on the device), and the power supply to the electric stimulator was turned off at the same time. On the device’s scoreboard, the heart rate / BH value (i.e. f _p / f _d ) is greater than 5 (6, 7), and the dispersion increased by more than 20% compared to the initial level. For 20 respiratory cycles before the start of the session, the variance was 0.40. For the last 20 respiratory cycles preceding the danger signal, the variance was 0.62. ECG recording immediately after the session showed the presence of tachycardia and arrhythmias in the work of the heart, which quickly stopped. A concomitant disease of this patient is coronary heart disease. Individual dosing of physiotherapeutic effects prevented exacerbation and side effects. The decrease in current strength restored the positive reaction of increased microcirculation in this patient, which made it possible to control the effectiveness of physiotherapy and the selected parameters of electrical stimulation.

Example 2. Compared the number of errors when the operator (students at different times of the day, during the preparation and passing exams) when performing tests for physical and mental fatigue. In the first case, the number of circuit closures was recorded by the lamp being illuminated when conducting an electric probe between the rows of electrical contacts. Physical fatigue and hand tremors increased the number of errors. In the second case, the number of errors in strikethrough of vowels in the text was calculated for a given time of presentation of the text (the number of unmarked ones). The results were compared in those periods when the deviation of the heart rate / BH (f _p / f _d ) from the normal range and the dispersion increase f _p / f _{d were} greater than 20% were compared with the results in periods of normal state. When f _p / f _d less than 3, the number of errors in the physical test increased by 2.6 times, and in the mental by 3.2 times. When f _p / f _d more than 5, the number of errors also statistically significantly increased in the physical test by 1.5 times, and in the mental test by 1.3 times. The use of the method is also advisable for testing and monitoring the condition of drivers of vehicles, operators of nuclear plants and when performing complex and critical work.

Example 3. When training a runner on a run for 1,500 meters, the inclusion of sound and light indicators of the output f _p / f _d outside the normal range (more than 5, namely 7.2) and an increase in dispersion of more than 20% turned out to be easily eliminated by the corresponding volitional increase or slowdown with deepening of breathing, which allowed to increase speed endurance and achieve better individual results in running this distance.

Example 4. On a bicycle ergometer "RITM" carried out semi-automatic optimization of the load intensity according to the chronodiagnostic indicators of the proposed method. When going beyond the normal range of the ratio f _p / f _d and increasing the variance and the Fisher information indicator of this ratio more than 20%, the load was manually switched to a lower load by 2-3 times, and when normal values were restored, it was again increased. Before the start of bicycle ergometry, the value of the Fisher information indicator was stable (determination for 20 respiratory cycles I = 53.5, 2 minutes before the load I = 54.0). The hazard signal turned on after 10 minutes of load I = 71. Comparison of the work performed in this case compared with the method used to control the load only by heart rate (the method for Tunturi exercise bikes - maintaining a heart rate of no higher than 170 beats per minute or the PWC150 test for people over 60) turned out to be more, and subjectively, the load and fatigue were smaller. In contrast to the assessment of physical activity by the absolute value of the heart rate, the proposed method uses a normalized value by the respiration rate, which does not depend on the person’s age and fitness.

Thus, the claimed combination of essential features, the peculiarity of which is the use of a certain range of the ratio f _p / f _d and at the same time the variance or the Fisher information indicator, allows to achieve the technical result.

LITERATURE
1. Eljanov M. Medical Information Technologies 2000. Catalog. -M .: Isograph, 2000. -128 p.

 2. The rhythm of the heart in athletes (under the editorship of P.M. Baevsky and R.E. Motylyanskaya. -M.: Physical education and sports, 1986. -143 p.

Claims (2)

1. A method of monitoring and limiting external loads, which consists in continuous diagnosis of the state of the human body, in which the ratio of the pulse rate f _p to the respiratory rate f _d and the variance of this ratio or the Fisher information indicator of this ratio are controlled, and with the value of f _p / f _d less 3 or more than 5 and an increase in the variance or the Fisher information index of this ratio is more than 20% relative to the initial state before the external load begins to act for a time not less than the duration of the transition process, characteristic of the reaction of the body to the action of external load, reduce or stop the external load, or take preventive measures to normalize the above indicators.  2. The method according to claim 1, characterized in that the transition time for the reaction of the body to the action of external load is chosen equal to at least 20 respiratory cycles.