RU2587946C2 - Method for automated inspection of human before health-improving programs - Google Patents

Abstract

FIELD: medicine; sports.

SUBSTANCE: invention can be used for automated inspection of human before health-improving programs. Method includes measurement of anthropometric and functional properties of examined person. Values are measured using a software-hardware system. For automation of measurements, using a control panel, monitor and control computer with a system block, equipped with a program. Program performs registration, classification, cross analysis of results, issuing structured conclusion for users. Measurements are carried out in seven steps. At first step obtaining anthropometric data. At second step obtaining functional parameters. At third step obtaining performing ECG. At fourth step evaluating general condition of examined person under hypoxia conditions. At fifth step pulmonary volume is measured. At sixth step hand force is measured. At seventh step functional parameters are measured with load tests using a veloergometer. Measurements are carried out using devices.

EFFECT: method enables accurate, fast and effective automated inspection of a person, selecting correction program by assessing most significant parameters and measurement of both at rest, and in conditions of load testing.

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Description

The invention relates to the field of sports medicine, in particular, it is intended for measuring, processing and accumulating data on the health of the human body for diagnostic purposes using computer systems and storage media, is intended for use in health centers: fitness and wellness clubs, resorts, Spa hotels, sports clubs.

A system with an intelligent transducer element for monitoring and analyzing biosignals placed on human skin or implanted in the human body of a patient. The mobile system includes an intelligent miniature element of a converter, a wireless mobile device, a computing device (mobile phone, personal digital assistant, or personal computer), as well as an Internet / Internet server. The system can be used to control various biopotentials (ECG, EEG, ERG, EMG and EOG) and biosignals, such as glucose, phonocardiography and blood pressure. The information obtained is presented to doctors in appropriate medial presentation formats, both numerically and graphically (Application No. EP 20060002331. Publ. EP 1815784 (A1) - 2007-08-08).

However, the known system has a complex scheme and is intended only for use in solving medical problems. In addition, the known system is time-consuming for use in the above health centers. The set of these tests is difficult to execute and interpret, it requires a staff of diverse specialists. The system described above does not have the function of automatic analysis and interpretation of test results; as output from the test results, only specific digital and graphic data are presented in it, followed by analysis by specialists.

A known method and apparatus for health and the treatment of diseases in combination with individual monitoring of data from a wireless Internet connection of a health monitoring device, which can be a medical device. It is possible to use an additional adapter, if necessary. Input data can also be entered manually. Input data is transmitted using standard Internet protocols. Using a computer program that includes an algorithm or artificial intelligence system, the system prepares an answer that can be further reviewed by a medical professional (Application No. US 19990172486 P. Publ. US 2009069643 (A1) - 2009-03-12).

However, the method and apparatus for health and disease treatment described above have a limited (1-2) set of devices capable of transmitting biometric data to software (software) for subsequent processing. The data obtained do not bear any final conclusion (especially assignments), being only "additional data" for consideration by a specialist.

A health management system and method is known, including a fitness center 100 provided with a user terminal 103 connected to a keyboard 105 for inputting personal medical information, a training machine 106, a measuring tool 108 for blood pressure, heart rate, weight, and the like. The exercise information and the measurement result are automatically transmitted to the user terminal 103. The user terminal 103 and the control terminal 101 are connected indirectly through a network by a connecting device. A card reader 102 is connected to a control terminal 101, a card reader 104 is connected to a user terminal 103, a card reader 107 is connected to a training machine 106, and a card reader 109 is connected to a measuring device 108 (Application No. 2004304953 JP. Publish. JP 2006119773 (A) - 2006-05-11).

However, from the above it follows that the devices in the complex system and method of health management do not have a direct connection with a single software that accumulates and analyzes biometric data. However, the latter are not transmitted from device to device by means of a memory drive. The measured information is entered manually. In addition, there is a complex information transfer system for the final analysis: “training machine”, “user terminal”, “control terminal”. The well-known system and method of health management do not provide automatic analysis of data and appointments.

A known simulator, method and fitness information management system, including a machine body, a sensing module, a signal processing module, and an identification identification module. The simulator contains a mechanism for the user, allowing exercise or physical fitness. The sensing module senses the state of movement of the fitness mechanism and / or physical conditions of the user so that the exercise / fitness signal and / or physical signals. The signal processing module for receiving and processing physical exercises / training signal and / or physical signals and perform exercises / receive training information and / or physical information accordingly. The identification module generates and turns exercise / fitness information and / or physical information into a convenient form for displaying it on the display screen easily determined by the user from the camera of a mobile device, as well as used for storage, management and application of various information (Application No. TW 20120138480. Publ. TW 201417030 (A) - 2014-05-01; US 2014113769 (A1) - 2014-04-24).

From the above it follows that the well-known simulator, method and fitness information management system are not related to measuring instruments for analyzing and processing biometric data in order to obtain information about the health status of the subject with the subsequent appointment of the optimal training and recovery program. This device only analyzes the exercises performed on it: load, number of repetitions, number of approaches, etc. In addition, it is not always convenient for the consumer.

A well-known health club exercise recording system, which includes a portable device (15), programmed by a trainer or operator to record various exercises. The working memory of the portable device (15) is loaded with an individual exercise data collection program (35). The data collection program (35) displays one or more subprograms (80-85) with the ability to enter information about the exercise. The entered information is stored in the file of the portable device (15) or transmitted directly to the local server (95) located in the fitness club. System (10) may also include an uplink terminal (software) for transmitting data to a remote server (95) connected to a network operations center. The fitness tools software program (150) is uploaded to a remote server (95) to collect and process data that can be reviewed by a trainer and / or user (Application No. US 20040819052. Published. WO 2005099827 (A2) - 2005-10-27) .

However, the well-known system of exercises for recording a fitness club is intended only for the analysis of the training process itself and is the next step after the diagnosis. It is not intended to receive biological signals about the state of human health during exercise and does not allow for centralized, adapted for convenient diagnostician and patient work automated data collection and automated cross-analysis of measured parameters.

There is a method of assessing the reserves of physical health and working capacity of the population, in which the passive, active and restorative phases of diagnosis are carried out. In the phase of passive diagnosis, weight-gain coefficient, pulse at rest, blood pressure, vital indicator, oxygen consumption are determined. In the phase of active diagnostics, the flexibility of the spine, the visual-motor reaction in the test with the capture of the falling ruler, the strength endurance of the muscles of the hands and shoulder girdle by measuring the number of push-ups from the floor, and the strength endurance of the abdominal muscles are assessed. In the recovery phase of the diagnosis, the recoverability of the pulse is determined. Additionally, resistance to hypoxia is assessed by arbitrarily maximizing breath holding, coordination of movements, overall performance, stroke volume of blood. The numerical expression of each separately measured indicator is translated into weighting factors. All weight coefficients are summarized and weight coefficients are added that characterize motor activity, smoking intensity, alcohol consumption intensity, obtained by scoring self-assessment by subjects. Based on the obtained index of the physical state, the physical state and health reserves are estimated by comparing it with the indicators of the scale for assessing the index of the state of human health (Patent for the invention No. 2147208RU. Publ. 10.04.2000).

However, the known method does not provide for the use of an exercise bike and computer systems for obtaining, processing and storing diagnostic data for automated cross-analysis of measured parameters both in statics and in dynamics, because of this, diagnostics in a known manner takes a long time, is a complex and lengthy process. All diagnostic measures in the known method are carried out manually, being time-consuming, subject to errors due to the human factor. In addition, one integral index is proposed as the output, which cannot be deduced for specific conclusions, and even more so for appointments in the form of training and recovery procedures. The test suite is limited and not equipped.

A well-known system for monitoring health indicators and providing telemedicine services, comprising sensors for monitoring biophysical parameters of consumer health, mobile diagnostic devices with an Internet access function, an Internet access point through a user’s mobile device with Internet access (for example, a smartphone, iPhone, tablet computer) , personal computer, laptop or other mobile means of communication equipped with Internet access, or through a basic device offering a current system with the function of recording, recording and transmitting to the Internet data from health monitoring sensors, including via satellite; Cloud Internet service with a database of users and medical consultants; digital archive; mathematical and statistical models for diagnosing diseases, including on the basis of electronic questionnaires and tests for the consumer, forecasting life-threatening conditions by notifying the user of severe and significant deviations from the norm of the recorded parameters in offline mode via the consumer’s mobile communication devices (smartphone, tablet, cellular telephone or other mobile means of communication), a personal computer and / or through active monitoring through a monitoring center, on duty whose members have an exit point to the Internet and access the user's personal account through a cloud service; at the same time, consumer health is monitored continuously 24/7 (24 hours a day, 7 days a week) for a user who is connected to the system and in the field of action of the autonomous remote biomonitoring system (Utility Model Patent No. 123649RU. Published on January 10, 2013).

However, the well-known system is primarily created for medical institutions, for patients with a specific disease and undergoing treatment. It is necessary primarily in order to provide emergency assistance due to a sharp deterioration in the patient's condition. The system described above is not intended for use in health centers. The software used in it for data processing does not have the function of analyzing the received data in order to formulate appointments for the training process and recovery procedures.

There is a method of evaluating the effectiveness of a health-improving training program, including determining the dynamics of the most informative indicators: the percentage of fat and muscle mass, vital and strength index, physical performance according to the PWC ₁₇₀ test; normalizing the type of reaction and reducing recovery time after a Martine stress test, improving well-being, achieving the goal and the desire to continue training, assign a score to each indicator, and then determine the total efficiency score (Patent for invention No. 2313274RU. Publish. December 27, 2007).

However, the known method was created only to assess the effectiveness of the training program in the dynamics and does not provide for the appointment of a specific program of physical education and rehabilitation activities immediately before the client begins classes in the wellness center. All tests involve manual execution and evaluation, and all measurements are reduced to one integral parameter.

The objective of the present invention is the creation of an automated testing algorithm, the result of which is to reduce the error in the measured complex of each indicator, to obtain accurate and reliable data, taking into account the functional indicators in dynamics, reducing test time.

The problem is solved in that in a method of automated examination of a person before conducting wellness programs, including the measurement of anthropometric, functional indicators of the person being examined, the indicators are measured by using a hardware-software complex, a control panel, a monitor and a control computer with a system unit are used to automate the measurements, equipped with a program that performs registration, systematization, cross-analysis of results ntropometric and functional indicators, the issuance of a structured conclusion for users, which is built on the basis of measurement and cross-analysis of the data obtained, and compile a correction program that includes an individually selected set of health measures, the measurements are carried out in seven stages, while the first stage receives anthropometric indicators, at the second stage, functional indicators are obtained, at the third stage, an ECG is performed, at the fourth stage, the general condition of the subject is evaluated a person under hypoxia, at the fifth stage measure the lung volume, at the sixth stage measure the strength of the hands, at the seventh stage measure the functional indicators by performing stress testing using a bicycle ergometer, while the measurements are carried out using instruments.

It is advisable to expand the possibilities of using the method as instruments to use: bioimpedance meter (bioimpedance), tonometer, electrocardiograph, pulse oximeter, hypoxic generator, dynamometer, spirometer, balance and stadiometer, biochemical blood analyzer.

It is advisable to visualize, interpret and store data for each person being examined to carry out a structured conclusion in the form of a “Health passport”.

In the variant of obtaining reliable indications for the optimal implementation of fitness procedures, at the first stage, at rest, anthropometric indicators of the body are measured: weight, height, limb and chest volume, in addition, flexibility is assessed, for this the patient is seated on a mat and asked for it reach with your hands to the foot.

It is advisable to obtain reliable indications in the examined person with increased muscle tone to exercise muscle relaxation at rest by means of a relaxation capsule, and then measure anthropometric indicators.

To improve the accuracy of the measurement results, it is advisable to measure the functional parameters of the person being examined to provide the correct and constant position of the cuff of the tonometer on the shoulder, palms and bare feet on the bioimpedance plates, in addition, the bioimpedance sensor, which is installed on the head, and a pulse oximeter on one of the fingers.

In an embodiment of the invention, which allows reducing labor costs during the examination and improving patient safety, before the ECG, on the proposal of the computer, remove the head bioimpedance sensor, remove the palms from its plates, and place five sensors on the body of the person being examined: one on the chest and one pair respectively on arms and legs in standard common areas.

It is advisable to identify the capabilities of the human body in conditions of hypoxia and adjust training exercises to create hypoxia conditions by artificially reducing the oxygen content in the inhaled air and measure the parameters of the person being examined.

It is advisable to prescribe exercises that develop the upper limbs, to measure the strength of the right and left hands of the person being examined, clamping a dynamometer in each of them, while holding the hands horizontally, in addition, display the dynamometers on the monitor of the control computer.

The present invention is illustrated by a detailed description and illustrative material, which is a screenshot of the seven stages of monitoring:

FIG. 1 - shows a window for setting and calibrating indicators;

FIG. 2 - shows the start of the test before obtaining indicators, an explanation to the user about the need for a static position and the correctness of the pulse oximeter on the finger of the upper limb signal strength;

FIG. 3 - characterizes the basic test, the need for a static position and the correctness of the pulse oximeter on the finger of the upper limb, signal strength;

FIG. 4 - illustrates indicators of a biochemical blood test performed prior to and during monitoring;

FIG. 5 - shows the measured indicators of the anthropometric user profile used for cross-analysis;

FIG. 6 - illustrates ECG data displayed on a monitor for cross-analysis of indicators;

FIG. 7 - shows the obtained dynamometry indicators, located on the background of the database field of the surveyed users;

FIG. 8 - illustrates spirometry indicators;

FIG. 9 - characterizes the indicators of the hypoxic test in the diagnostic process;

FIG. 10 - characterizes the performance of stress testing for cross-analysis when conducting a bicycle ergometric test;

FIG. 11 illustrates the table of contents of the “Health Passport”, which presents a structured conclusion of the person being examined;

FIG. 12-15 - partially illustrate the information from the "Health Certificate" of the person being examined.

The method of automated examination of a person before conducting wellness programs is as follows.

When implementing the method, a software and hardware complex (MPFC) is used, including a control panel, a monitor and a control computer with a system unit equipped with a program, and a bicycle ergometer. MPFC maximally automates measurements and cross-analyzes both anthropometric and functional indicators in the statics and dynamics of the person being examined. Stress testing by the examined person is carried out using a bicycle ergometer.

The testing algorithm is carried out using instruments or tools authorized by the competent authority for practical use. As instruments and tools use: bioimpedance meter - analysis of body composition, tonometer, electrocardiograph, pulse oximeter, hypoxic generator, dynamometer, centimeter tape, scales and stadiometer, spirometer, biochemical blood analyzer.

Dynamic monitoring is carried out in seven stages, at each stage a set of initial anthropometric and functional indicators is obtained.

At the first stage, to obtain a set of initial anthropometric indicators, the examined person (client) takes off his shoes, stands on the base of the device, which includes scales and height meters. The operator measures the weight and height. Then records the result of measurements. Then it measures the coverage of the chest, waist, pelvis, shoulders, hips in a standing position using a centimeter tape. Records the received measurement results. The results of measurements and measurements are recorded by the operator manually (manually) in the software of the complex.

At the first stage, flexibility is also assessed. To do this, the person being examined sits on the mat, which is located on a horizontal surface, and, leaning forward, covers the corresponding feet with his hands.

At the first stage, the examined person with increased muscle tone is recommended to exercise muscle relaxation. Such relaxation is carried out by means of a relaxation capsule, which allows to reduce increased muscle tone and normalize physiological processes.

At the second stage of research, the examined person is placed in a hardware-software complex. To automate monitoring, they use a control panel, a monitor and a control computer, the system unit of which is equipped with a program. At this stage, to obtain functional indicators, a bioimpedance meter, pulse oximeter, and tonometer are used and indicators such as pressure, hemodynamics, heart rate variability, and body composition analysis are obtained. MPFC has a monitor (panel) of both the examined person and the doctor. During the examination, in order to obtain reliable indicators, they ensure the correct and constant position of the tonometer cuff on the shoulder of the person being examined. In addition, the palms and bare feet of the person being examined are tightly placed on the plates of the bioimpedance meter. A bioimpedance sensor is placed on the head. In addition, a pulse oximeter is fixed on one of the fingers.

At the third stage of the examination, an ECG is performed. Before performing an ECG, the computer through the program suggests removing the head sensor of the bioimpedance meter and removing hands from its plates. In this study, a heart rate monitor and foot contact with the plates are left. In addition, five sensors are attached to the body of the person being examined: one on the chest, two on each arm and two on each leg.

The fourth stage proposes to examine a person in conditions of hypoxia. Thin air is created using a hypoxic generator. In this case, air with a low oxygen content is supplied by the compressor to a mask, which is worn on the person being examined. In case of deterioration of its general condition when breathing air with a low oxygen content provide easy removal of the mask.

In a fifth step, a measurement of lung volume is added. For this, the person being examined makes a sharp exhalation into the spirometer.

At the sixth stage, the manual strength of the right and left hands is measured. To do this, the examined person alternately clamps the dynamometer in the arm extended horizontally to the side. Dynamometer indicators are displayed on the monitor of the control computer.

At the seventh stage, a bicycle ergometer is used to study functional indicators under load conditions. The patient in the shoes rotates the pedals, maintaining the necessary speed, and MPFC increases the dynamic load using several steps. The number of the latter depends on the degree of preparation and physical abilities of the person being examined.

The testing algorithm is a set of the above anthropometric and functional indicators. Registration, systematization and cross-analysis of them is carried out using a program embedded in the control computer. The latter carries out their dynamic monitoring. A structured conclusion is drawn up based on a cross-analysis of indicators. In addition, violations are recorded in it and a characteristic is given to them. At the same time, violations are compared, and a program for their correction is proposed with the selection of a complex of appointments and an indication of specific limitations and contraindications.

User - means both the person being examined and the person monitoring the examination, i.e. fitness trainer, doctor, exercise instructor, etc.

Each person examined has a structured conclusion. The latter is performed in the form of a “Health Passport”.

An example of the method.

The person being examined was L., born in 1979, the examination was conducted on January 29, 2014 (all personal data used to describe the invention in the description and graphic materials are fictitious and fantasy).

The study was carried out using MPFC (fitness combine), which contained a control panel, a monitor and a control computer with a system unit equipped with a program and a bicycle ergometer.

Measurements were carried out using instruments and tools authorized by the competent authority for practical use.

The measurements were carried out in seven stages, at each stage a set of initial anthropometric and functional indicators was obtained.

Before the examination, using a computer program, the client was registered, the computer program was connected and calibrated, a start test was performed before receiving indicators, a basic test, the need for a static position and correct pulse oximeter on the upper extremity finger, signal strength (Fig. 1-4).

At the first stage, a set of initial anthropometric indicators was obtained using height-measuring weights (Fig. 6). The examined person took off his shoes, stood on the base of the indicated scales - height meters. The operator carried out the measurement of weight and height. Then I recorded the result of measurements manually using the computer keyboard. Then he measured the coverage of the chest, waist, pelvis, shoulders, hips of the examined person in a standing position. The operator carried out measurements using a centimeter tape. I recorded the obtained measurement results. The results of measurements and measurements were recorded by the operator manually (manually) using the computer keyboard.

Blood sampling was carried out before obtaining functional measured indicators in the static state of the body of the person being examined (Fig. 5, 15). In addition, assessed the flexibility (Fig. 14). To do this, the person being examined sat on the mat, which was placed on a horizontal surface, and leaned forward, reaching with the tips of the fingers to the tips of the fingers corresponding to the feet.

If necessary, muscle relaxation was performed at rest. Relaxation was carried out by means of a relaxation capsule, which made it possible to lower increased muscle tone and normalize physiological processes.

At the second stage of research, the examined person was placed in a hardware-software complex. To automate monitoring, we used a control panel, a monitor, and a control computer. In this case, the system unit was equipped with a program. At this stage, to obtain functional indicators, a bio-impedance meter was used, through which a bio-impedance measurement of body composition was performed. The pressure was measured with a tonometer. Heart rate variability and hemodynamic parameters were measured with a pulse oximeter (Fig. 4).

The examined person, doctor or user received information about the indicators directly using monitors (panels). Obtaining reliable measured indicators ensured the correct and constant position of the cuff of the tonometer on the shoulder of the person being examined. The palms and bare feet of the examined person were located tightly on the bioimpedance plates. A bioimpedance sensor was placed on his head, and a pulse oximeter was fixed on one of his fingers, which allowed him to measure heart rate variability and hemodynamic parameters.

At the third stage of the examination, an ECG was performed (Fig. 7). Before performing an ECG, the computer proposed using a program to remove the head bioimpedance sensor and remove its hands from its plates. In this study, a pulse oximeter and leg contact with the plates were left. On the body of the person being examined, an instrument with five sensors was used to obtain an ECG. One sensor was attached to the chest, two - one for each arm and two - one for each leg.

The examination of the person in the fourth stage was carried out in conditions of hypoxia. Low oxygen air was created using a hypoxic generator. In this case, rarefied air was supplied by the compressor to the mask, which was worn on the person being examined. In case of deterioration of its general condition during breathing with rarefied air, an easy exit from the breathing zone was provided.

At the fifth stage, lung volume was measured. For this, the examined person exhaled sharply to a spirometer (Fig. 9).

At the sixth stage, the manual strength of the right and left hands was measured (Fig. 8). To do this, the examined person alternately clamped the dynamometer in the arm extended horizontally to the side. The dynamometer indicators were displayed on the monitor of the control computer. The arms were extended horizontally. This made it possible to conclude about different strengths in the right and left hands and adjust the training program.

At the seventh stage, a bicycle ergometer was used to study biometric indicators under load (Figs. 11, 13). The examined person in shoes turned the pedals, maintaining the necessary speed, and MPFC increased the dynamic load using several steps. The number of the latter depended on the degree of preparation and physical abilities of the person being examined.

The measurements were the above anthropometric and functional indicators (Fig. 10, 16). Their registration, systematization and cross-analysis is carried out using a program embedded in the control computer of a hardware-software complex, which, based on a cross-analysis of measurements, recorded violations, compared violations with normal measured parameters at rest, and proposed a correction program with selection of a set of appointments and an indication of specific limitations and contraindications.

The examined person was given a structured opinion included in the “Health Passport” (Figs. 10, 12, 16).

The proposed method allows to create an automated testing algorithm, which helps to reduce the error in the measured set of indicators of the person being examined and to obtain reliable data for a structured conclusion.

The proposed method, based on reliable data, offers a correction program with the selection of a set of appointments and an indication of specific limitations and contraindications, visualizes the results of the examination for the convenience of consumers with recommendations for fitness training, recovery procedures and nutrition.

The range of use of the method is expanded by obtaining measurements of indicators both at rest and load testing, followed by automated issuance of a conclusion that includes general recommendations for each analyzed indicator.

In addition, the proposed method improves the quality of services provided by fitness clubs, SPA centers, while spending a minimum amount of time for the operator and the person being examined to test.

The proposed method is highly effective and meets the requirements of modern computer technology in the field of diagnostic activities.

Claims (9)

1. A method for developing individual wellness programs based on the automated determination of the integral indicators of the functional systems of the body and their dynamic monitoring, including the measurement of anthropometric, biometric and physiological parameters of the person being examined, characterized in that they perform dynamic monitoring of the indicators through the use of a hardware-software complex for monitoring automation use the control panel, monitor and control computer with s a dark unit equipped with a program that records, systematizes, cross-analyzes the results of anthropometric and biometric indicators, which make up the general testing algorithm, their screening and 3D visualization, by issuing a structured conclusion for users, which is built on the basis of measurement and cross-analysis of the data obtained, when this fix violations and give them definitions, compare violations and offer a correction program, including the selection of a complex of appointments, Azan specific limitations and contraindications, monitoring is carried out in seven stages, in each stage is prepared starting set of biometric data, stress testing is carried out using ergometer, the total testing algorithm performed by instruments. 2. The method according to p. 1, characterized in that the devices use, respectively, a bioimpedance meter, tonometer, electrocardiograph, pulse oximeter, hypoxic generator, dynamometer, spirometer, balance and growth meter, biochemical blood analyzer. 3. The method according to p. 1, characterized in that the structured conclusion of the examined person is performed in the form of a "Health passport". 4. The method according to p. 1, characterized in that at the first stage, at rest, blood sampling is carried out, anthropometric indicators of the body are measured: weight, height, limb and chest volume, in addition, flexibility is assessed, for this the patient is seated on a mat and ask him to reach his feet with his hands. 5. The method according to p. 4, characterized in that they carry out the relaxation of muscles at rest, through a relaxation capsule. 6. The method according to p. 1, characterized in that, after placing the patient in the hardware and software complex, ensure the correct and constant position of the cuff of the tonometer on the shoulder, palms and bare feet on the bioimpedance plates, using a bioimpedance sensor, which is installed on the head In addition, a pulse oximeter is placed on one of the fingers. 7. The method according to p. 1, characterized in that before the ECG the computer offers to remove the head bioimpedance sensor, remove the palms from its plates, while five sensors are placed on the body of the examined person: one on the chest, and one pair, respectively, on the hands and legs in standard common areas. 8. The method according to p. 1, characterized in that the hypoxia conditions are created by artificially lowering the oxygen content in the inhaled air and a set of initial biometric indicators of the person being examined is obtained. 9. The method according to p. 1, characterized in that they measure the strength of the right and left hands of the person being examined, clamping a dynamometer in each of them, the hands being placed horizontally, in addition, the dynamometer readings are displayed on the monitor of the control computer.

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