RU2655186C2 - Method of control of the functional state of a person in extreme operating conditions - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention relates to the medical diagnostics field and can be used in carrying out physiological and psychophysiological monitoring of the performance and reliability of specialists in hazardous occupations. Preliminary registration and analysis of a number of physiological and psychophysiological parameters is carried out and on their basis a "physiological passport" of a specialist is constituted. Additionally, the parameters of a specialist's functional state are recorded directly in the process of performing professional tasks. Then, based on a comparison of the current values of all indicators with their individual optimal values, a functional state integral indicator (FSII) is calculated from the "physiological passport". Degree of deviation of the specialist's performance from the optimal level is determined by the value of the FSII, such as: high, acceptable state, conditionally acceptable state, unacceptable state of decompensation.

EFFECT: method makes it possible to improve the efficiency of the operational control of the functional state and the forecasting of the performance of specialists in hazardous occupations by increasing the reliability of the received data on the deviations of the physiological and psychophysiological parameters of specialists in the course of their activities.

6 cl, 3 tbl, 2 ex

Description

The invention relates to the field of medical diagnostics and allows to evaluate the functional state of a person in extreme conditions of activity. The prompt identification of borderline functional states and the prevention of an unacceptable decrease in the professional working capacity and reliability of specialists in dangerous professions is the main task of physiological and psychophysiological monitoring.

Under extreme conditions of human activity, we understand a combination of factors of various nature that cause such an tension in the mechanisms of maintaining homeostasis that, in the event of the impossibility of timely termination and continued exposure, this leads to irreversible disturbance of physiological functions.

Extreme conditions of activity can be of various nature: physical (for example, high or low temperature, high or low atmospheric pressure), chemical (for example, carbon monoxide content, insufficient oxygen content or excess in the air), biological (for example, exposure to viruses and bacteria) and others. As examples of extreme conditions, we can consider the conditions of the Far North, desert territories, prolonged exposure to diving, working in deep mines, putting out massive forest fires, etc.

Automated rapid assessment of a person’s functional state, increasing accuracy in recognizing functional states and preventing an unacceptable decrease in the effectiveness and reliability of the activities of specialists in dangerous professions is of applied interest to civil and military medicine, the field of professional selection, and monitoring systems for operators.

A known method for assessing the functional state of regulatory systems of the body according to the patent of the Russian Federation No. 2103911, IPC AB 5/04, publ. 02/10/1998, including the measurement of RR intervals of the rhythm of cardiac electroactivity, the formation of a sequential series of digital codes corresponding to the measured durations of RR intervals, the mathematical processing of a series by generating codes reflecting the activity of neurohumoral regulation of the heart rhythm, as well as the calculation of the voltage index of regulatory systems, transformation a series of digital codes into a periodic curve followed by its spectral analysis with determination of the oscillation power in the spectral regions corresponding to first and second order waves and slow waves, the formation of codes on a point scale based on all the indicated indicators, corresponding to the indicator of the total regulation effect characterizing the degree of deviation of the heart rhythm from the physiological norm, the indicator of the function of automatism, the indicator of autonomic homeostasis, the indicator stability of regulation, and the formation on their basis of a code corresponding to the integral indicator of the activity of regulatory systems, according to which Xia assessment of the functional state of regulatory systems.

The disadvantage of the described method is that its implementation is based only on the analysis of heart rhythm. This approach is very limited, since the reaction of the heart rhythm to the action of extreme environmental factors is nonspecific, which in most cases excludes a differentiated assessment of the state of the body under the influence of multimodal external factors. Moreover, the types of regulation of the heart rhythm are characterized by extreme individual variability and variability, which greatly complicates the possibility of their adequate analysis and comparison with reference values. There may be a significant spread of indicators from one cycle of processing the results to the next, not because of a change in the functional state of the researched, but as a result of processing an unsteady array of cardio intervals.

A known method of assessing the functional state of a person based on the analysis of heart rate variability and variability of the duration of the respiratory cycle according to the patent of the Russian Federation No. 2195163, IPC A61 B5 / 02, A61B 5/0452, publ. 12/27/2002, the Method includes simultaneous synchronous recording of ECG and pneumograms. Then, the histogram mode of the duration of the respiratory cycles is calculated, the spectrogram of the high-frequency component of the heart rhythm is graphically superimposed on it, and the boundary of the low-frequency component of the heart rhythm is specified using the peak position of the maximum power of the spectrum. If the peak of the maximum power of the high-frequency component of the heart rhythm differs in frequency from the respiratory rate mode by more than 0.06 Hz, the desynchronization of the respiratory and cardiovascular centers of the central nervous system is diagnosed. If an increase in the power of the low-frequency component is accompanied by a change in the nature of breathing, the patient is diagnosed with a state of psycho-emotional stress.

The disadvantage of the described method is that, although the dynamics of the state of the parameters of external respiration and blood circulation systems reflects the degree of tension of regulatory systems and characterizes the adaptive capabilities of the body, the method will not allow to urgently assess a person’s functional state, when borderline and pathological conditions can develop, under conditions for example, extreme hyperthermia, since the measured action (effect) is manifested indirectly, indirectly and after a long period of time .

A known method of assessing human life, implemented in a mobile diagnostic device according to the patent of the Russian Federation for utility model No. 128469, IPC AB 5/00, publ. 05/27/2013, the Method includes monitoring the activity of the cardiovascular system, body temperature, monitoring the activity of the respiratory system, analyzing the hydrophilicity of tissues and the water balance of the human body, motor activity, body position in space and recording a single-channel ECG, as well as analyzing heart rate variability and dynamics of the ST-segment of the cardiogram, allowing to classify various types of cardiac arrhythmias. The assessment of changes in the functional state is based on the calculation of the deviation of the recorded indicators from the reference values.

This method allows you to evaluate many indicators of the functioning of the body, however, the conclusion is made on the basis of calculating the deviation of each of the recorded parameters from the reference values. This approach does not allow us to draw a conclusion about the functional state of a person, since a deviation of an indicator from reference values under various conditions of activity may indicate a normal tension of homeostatic systems. Moreover, the registration of the “exit” of the values of the controlled parameter beyond the reference boundaries does not allow us to conclude which of the physiological systems is more stressed or depleted, as well as the type of the observed functional state.

There is also a method of assessing the functional state of the central nervous system of a person by the electrical activity of the brain according to the patent of the Russian Federation No. 2039524, IPC AB 5/0476, publ. 07/20/1995, According to this method, at rest, the electrical activity of the brain is recorded on an electroencephalograph with monopolar and bipolar switching electrodes, an EEG analysis is carried out with the selection of the main rhythms, the coefficient of proportionality of frequencies (W ₁ ), the coefficient of proportionality of the amplitudes of the main rhythms (W ₂ ) and the indices of the ratio of frequencies and rhythms, determine the coefficient of proportionality of amplitudes (N). If the values of W ₁ and W ₂ correspond to a value of 1.309 ± 0.07 and the value of N corresponds to a value of 1.0 ± 0.05, then the state is determined to be satisfactory, with a change in W ₁ and W ₂ or N by 10 to 20%, the state it is defined as a state of functional tension and overstrain, and with a deviation of more than 20%, a violation of the functional state of the central nervous system is detected (risk of pathological dysfunction).

The limitations of this method are that the use of indicators of the bioelectric activity of the brain does not provide an operational solution to monitoring the functional state of specialists in connection with extremely complex technical requirements that must be observed when registering an EEG. In addition, EEG indices are distinguished by pronounced individual variability, which sharply reduces their reliability for solving problems of diagnosing pre-painful conditions. Existing methods of EEG analysis are focused mainly on a binary scale (absence / presence of pathology), which makes it impossible to fix borderline deviations of the functional state and, therefore, make a forecast of their transition to unacceptable.

Closest to the claimed invention is a method of integral periodic assessment of the health of specialists during long "working cycles" (see Sapov IA, Solodkov AS The state of body functions and the health of sailors. - L .: Medicine, 1980. - 192 C.), considered as a prototype.

In this method, the assessment of the level of performance is carried out according to the following formula:

where A is an integral quantitative indicator of health,

a 'is the value of the informative indicator before the start of the work cycle,

a '' is the value of the informative indicator in the process (after) of the working cycle,

W - "weight" coefficient for each informative indicator.

According to the authors of this work, informative indicators of the performance of shipboard specialists-operators are such as the critical flicker fusion frequency, heart rate, pulse blood pressure, endurance to static muscle effort, the latent period of a complex sensorimotor reaction, and a 2-minute step test index. The weight value of each informative indicator is estimated by calculating the correlation coefficient between the criteria of the functional state of the body and the professional activities of ship specialists. Evaluation of the dynamics (stages) of health is carried out by calculating the deviation of the integral indicator from the initial level, namely: a deviation of less than 30% is defined as an acceptable state (stage of full compensation), 30-40% - conditionally acceptable state (stage of incomplete compensation), more than 40% - an unacceptable state of decompensation (stage of a progressive decrease in working capacity).

The disadvantages of the presented method is the discreteness of the assessment of the working capacity of specialists, which can lead to the omission of a significant deviation of working capacity in the process of activity. In addition, this method provides for the study of established indicators only in special conditions on stationary equipment before starting the main professional activity of the examined specialists. In addition, the presented informative indicators are relevant only for assessing the performance and functional status of specialists of a narrow profile - ship operators, and only using the same set of diagnostic research methods that cannot be applied directly when performing professional activities of a specialist.

The invention solves the problem of preventing erroneous actions, reducing the risk of loss of health and death in the process of activities of specialists in dangerous professions, such as military personnel, employees of the Ministry of Emergencies, ship specialists, employees of air and ground transport, specialists in the mining industry and others, and making decisions on the possibility of further implementation of these specialists tasks their activities, its optimization or deciding on the need for urgent medical care.

The technical result from the use of the proposed method is to increase the efficiency of operational monitoring of the functional state and assess the further performance of specialists in hazardous professions by increasing the reliability of the obtained data on deviations of physiological and psychophysiological parameters of specialists in the process of their activity.

The essence of the claimed method lies in the fact that they carry out continuous monitoring of the most significant physiological parameters of a person, not only the heart rate and blood pressure, as in the prototype method, but also the data obtained using electrocardiography, rheocardiography, thermometry, chest mechanography, polarography, viscometry, studies of biomechanics of movements, measurements of heat flux and other available data. Such data, depending on the specific extreme conditions of activity, may include, but not limited to, oxygen saturation (SaO ₂ ), blood viscosity, heart rate (HR), mean dynamic arterial pressure (SDD), respiratory rate (NPV) , the average skin temperature (SFTC), mean body temperature (CTT), a distal temperature gradient (DTG), the rectal temperature (T _p), the body temperature in the axilla (Tpodm) and other indicators.

Based on the obtained data, the integral functional state indicator (IPFS) of a specialist is calculated and his functional state is identified (ie evaluated) by comparing the obtained data with the individual optimal values of the same indicators obtained at the preliminary stage of the examination (the so-called “physiological passport” specialist). Next, they develop a draft decision on determining the possibility and choosing a mode for further continuation of the specialist's professional tasks.

The proposed method for monitoring the functional state of a person in extreme conditions of activity is based on the fact that maintaining the stability of the internal environment of the body is ensured by hierarchical regulatory processes aimed at maintaining homeostatic parameters within the reference values due to prompt, rapid compensatory shifts of physiological systems, such as circulatory systems, external respiration, gas transport function of blood, thermoregulation and others. Thus, the revealed impossibility of maintaining controlled parameters within evolutionarily specified limits indicates the insufficiency of developing adaptive changes and is the primary sign of the development of borderline functional states that can lead to a decrease in professional reliability. For such functional states, a moderately low or fluctuating level of direct performance criteria is characteristic, supported by the extremely pronounced tension of neurohumoral regulatory mechanisms and homeostatic physiological systems, which can be detected by evaluating indirect (physiological) criteria. In the case of an increase in the severity of health deviations from the norm, a dynamic mismatch arises between the functioning of various “quick response” systems (for example, the circulatory system, external respiration, blood, thermoregulation, and others), their regulation mechanisms, which is also clearly seen with continuous monitoring of physiological parameters and is a prognostic sign of the transition of borderline states into unacceptable.

The claimed method of monitoring the functional state of a person in extreme conditions involves the calculation of the integral indicator of the functional state (IPFS) of a specialist based on the use of several of the most informative physiological parameters that are easily controlled in real time. For the calculation of IPFS, the values of physiological parameters recorded during the course of a specialist’s professional activity are compared with the data obtained as a result of a similar examination performed by a specific specialist before the start of the work cycle in normal conditions of life. The final conclusion about the state of professional performance and the forecast of its dynamics is carried out on the basis of the analysis of the degree of deviation of the current IPFS from its initial level, and the selection of the current measured parameters may not be all, but only a part of the parameters measured at the preliminary stage.

The calculation of IPFS is carried out by the method of multiple regression analysis, where IPFS acts as a dependent variable, and controlled physiological indicators - independent (controlled) variables. Moreover, the number of analyzed parameters n can vary depending on what specific extreme conditions it is planned to carry out professional activities, as well as the technical capabilities of recording devices. The general form of the multiple regression equation can be represented as follows:

where A is the free term of the equation calculated when performing the regression analysis procedure, with 0.9 ≤ A <1;

P ₁ , P ₂ , ... P _n - physiological and psychophysiological parameters (total number n) of the functional state, recorded under normal conditions (before starting work) and directly in the process of activity;

ΔP ₁ , ΔP ₂ , ... ΔP _n - absolute changes in the current values of the recorded parameters compared to normal conditions (before starting work);

k ₁ , k ₂ , ... k _n are the regression coefficients of the corresponding indicators, reflecting the degree of “contribution” of the parameter to the IPFS. The sign (+/-) before the regression coefficient is determined by the direction of the change in the physiological parameter.

Thus, the degree of deviation of the functional state is quantitatively determined by the change in independent variables associated with the influence of adverse factors in professional activity.

Based on the analysis of the categories of the main existing extreme environmental factors, the most informative indicators were selected that characterize the functioning of physiological systems of “quick response”. These are indicators such as heart rate, heart rate variability, respiratory rate, body temperature, heat flux, blood oxygen saturation, mean blood pressure, number of movements and a number of others, measured by electrocardiography, rheocardiography, thermometry, chest mechanography, polarography , viscometry, studies of biomechanics of movements and other accessible methods. In addition, if possible, the level of the subjective state (CSS) of a person is determined, which is also an informative parameter. CSS is determined by a 7-point scale, which can be represented as a 7-centimeter ruler, where 7 cm (points) corresponds to the most comfortable condition and vice versa.

As indicated above, the number of variables n that are included in the regression model depends on the number of parameters deviating beyond the reference values, i.e. the significance of the contribution of individual indicators and, as a consequence, of the calculated information ability and the level of reliability of the regression model.

Thus, the proposed method allows to evaluate the functional state of the body in connection with the conditions for the performance of activities, reflects the relationship of the work of various regulatory systems and allows you to identify the "contribution" of a separate regulatory system in violation of the functional state. Based on the calculation of the integral indicator and its deviation from the permissible value, a draft decision is formed on the possibility of continuing the activity by a specialist.

The method is as follows.

Preliminary, i.e. Before the start of the work cycle, the specialist’s condition is monitored in conditions of operative rest and individual variability of the studied parameters is determined, on the basis of which the individual “physiological passport” of the specialist is formed.

Then, the selected registered parameters are monitored directly in the process of real activity, for example, by placing appropriate sensors on the specialist’s body. Based on a comparison of the current values of all parameters with their individual optimal values from the “physiological passport”, an integral indicator of the functional state (IPFS) is calculated, the magnitude of which is used to evaluate the degree of deviation of the level of functional capabilities of the organism from its initial state.

Next, they make a conclusion about the current level of specialist performance and the admissibility of continuing further activities.

Moreover, if the deviation from the initial state of IPPS is less than 20%, then the performance level is determined to be high, if the deviation of IPPS corresponds to 20-30%, then the level of operability is defined as an acceptable state, if the deviation of IPPS is more than 30 and up to 40% as conditionally permissible condition, and when the IPPS deviates by 40% or more - as an unacceptable state of decompensation.

The claimed method is confirmed by the following examples, representing some options for assessing the functional state of a person performing professional tasks, for example, in conditions of low oxygen content in the environment (hypoxic conditions), in conditions of low and high air temperature. During the development of each of the regression models presented below, which make it possible to evaluate the functional state of the organism (FSO) of specialists, preliminary studies were carried out with the participation of representative samples of volunteer subjects. As an external (direct) criterion for the functional state of the body, the standardized test indicator PWC _{170 was used} . For indirect determination FSO used multivariate linear regression analysis, which involves the construction of models to calculate the quantitative value of the predicted (controlled dependent) feature (in particular, the indicator ₁₇₀ PWC) for others of quantitative values (explanatory independent) features (i.e., reactivity investigated functional indicators). To confirm the informational ability of the models presented below, in each of the cases, except for the indirect determination of the FSO, its direct determination was carried out using the PWC ₁₇₀ test.

Example 1. Assessment of the severity of the functional state in hypoxic conditions:

Subject I.A. (age 22 years) was in conditions of normobaric hypoxia (O ₂ concentration _of about 15%) and performed various loads for 10 hours. The results of the study of physiological functions before testing (under normal conditions) and immediately before the end of hypoxic exposure are presented in table 1.

where PWC ₁₇₀ is an indicator of a standardized test by physical activity - a direct criterion of the functional state of the body; CSS is the level of self-esteem of a condition determined on a 7-point scale; SaO ₂ - blood oxygen saturation; Heart rate - heart rate; SDD - mean dynamic blood pressure; NPV - respiratory rate.

As follows from the data presented, as a result of being in the given conditions, judging by the dynamics of the PWC ₁₇₀ indicator, which is a direct criterion for assessing the level of functional capabilities of the organism, the test subject showed a decrease in working capacity by 29.7% compared to the initial state (normoxia).

Next, the IPFS was calculated by the formula (2):

Thus, the calculation of IPFS carried out according to the proposed equation of the regression model showed that the value of this indicator is 0.704 rel. (or 70.4%), corresponds to a decrease in the level of performance by 29.6% from the initial level. The high information capacity of the developed model is confirmed by an insignificant (about 0.1%) deviation of the indicators determined by the two methods used.

Conclusion: Since the obtained IPFS deviation value falls into the range of 20-30%, the degree of decrease in the functional capabilities of the body can be considered an acceptable state, which allows us to determine the possibility of the subject being further in the given conditions and performing his professional activity. However, given the approximation of the IPFS to critical values, it is desirable to reduce the intensity of work and provide the subject with rest.

Example 2. Assessment of the level of functional capabilities of the human body performing activities in conditions of low ambient temperature:

Subject M.N. (age 22 years) in clothes with thermal insulation of 1 clo was in a heat chamber under conditions of operational rest at an ambient temperature of -12 ° C for 70 min. The results of the study of physiological functions under ordinary conditions before the start of testing (2 days) and immediately while in hypothermia (65-70 minutes of testing) are presented in table 2.

where PWC ₁₇₀ is an indicator of a standardized sample with physical activity; SVTK - weighted average skin temperature, ° С; CTT - average body temperature, ° C; DTG - distal temperature gradient, ° С; Heart rate - heart rate, beats / min; T _p - rectal temperature, ° C.

As follows from the data presented, as a result of being in the given conditions, based on the dynamics of the direct criterion of UVBO - the PWC ₁₇₀ indicator, the test subject showed a decrease in working capacity by 45.6% compared with the initial state.

Next, the IPFS was calculated by the formula (2):

Thus, the calculation of IPFS, carried out according to the proposed equation of the regression model, showed that the value of this indicator is 0.539 relative units (or 53.9%), corresponds to a decrease in the level of performance by 46.1% from the initial level, which is insignificant (only 0.5%) different from the direct determination of the level of functional reserves, confirming the high information ability of the developed model.

Conclusion: Since the obtained IPFS deviation value exceeds 40%, the degree of decrease in the functional capabilities of the organism should be considered an unacceptable state of decompensation, which indicates the need to terminate the test subject under specified conditions and carry out professional activities.

Example 3. Assessment of the functional capabilities of the human body performing activities in conditions of elevated ambient temperature:

Subject B.C. (age 35 years) in clothes with thermal insulation of 1 Clos was in a heat chamber and performed light physical work (walking on a treadmill at a speed of 4.5 km / h) for 40 minutes at an ambient temperature of + 42 ° С. The results of the study of physiological functions in thermocomfort conditions before the start of the test (2 days) and directly while in the heating microclimate (40-45th test minutes) are presented in table 3.

where PWC ₁₇₀ is an indicator of a standardized sample with physical activity; CSS is the level of self-esteem of the state; Tpodm. - body temperature in the armpit; Heart rate - heart rate; SDD - mean dynamic blood pressure; NPV - respiratory rate.

As follows from the data presented, resulting host under predetermined conditions, based on the dynamics of direct test the functional state of the organism - PWC indicator _170, the subject's health decreased by 25% compared with the initial state (termokomfortnymi conditions).

Next, the IPFS was calculated by the formula (3):

Thus, the calculation of IPFS, carried out according to the proposed equation of the regression model, showed that the value of this indicator is 0.735 rel. (or 73.5%), corresponds to a decrease in the level of performance by 26.5% from the initial level, which is insignificant (only 1.5%) differs from the direct determination of the level of functional reserves, confirming the high information ability of the developed model.

Conclusion: Due to the fact that the obtained IPFS deviation falls within the range of 20-30%, the degree of reduction in the functional capabilities of the body can be considered permissible, which allows us to allow the subject to continue to stay in the given conditions and carry out professional activities. However, given the approximation of the IPFS to critical values, a transition to thermal comfort conditions and the provision of rest are desirable.

The calculation of IPFS is performed automatically using the software developed in the organization by substituting parameter values in real time.

The decision to include the indicator in the calculation of the integral indicator is made subject to deviations from the reference values. If the condition is not met, then the value of the parameter is equal to 0.

The proposed method, unlike the existing ones, has the following advantages.

Firstly, this method is a synchronous (as opposed to sequential in the prototype) registration of a number of physiological parameters that comprehensively reflect the functional state of a specialist, which can significantly increase the reliability of the information received.

Secondly, the presented method offers an assessment of the functional state of specialists in hazardous professions directly in the context of their performance, allowing to obtain reliable and reliable information about the current functional state in real time.

At the same time, a conclusion about the specialist’s working capacity is formed by comparing the current physiological parameters with both their individual values recorded in the optimal state (“physiological passport”) and the average norm.

In addition, the formation of the final conclusion about the risk of developing an unacceptable decrease in the specialist’s working capacity is based on the principle of identifying signs of dynamic mismatch between the recorded parameters of homeostatic “quick response” systems, which is the earliest prognostic sign of the formation of decompensation phenomena in the body.

Claims (11)

1. A method of monitoring the functional state of a person in extreme conditions of activity, including pre-registration and analysis of a number of physiological and psychophysiological parameters, on the basis of which a specialist’s “physiological passport” is compiled and an integral indicator of his working capacity is calculated, characterized in that the parameters of the specialist’s functional state are additionally recorded directly in the process of performing his professional tasks, then based on a comparison of current the values of all indicators with their individual optimal values from the “physiological passport” calculate the integral indicator of the functional state (IPFS), the value of which determines the degree of deviation of the specialist’s health from the optimal level, and if the specified deviation is less than 20%, then the level of health is determined as high if the deviation corresponds to 20-30%, then the level of performance is defined as an acceptable state, if the deviation corresponds to more than 30 and up to 40% - as conditionally Permissible state, and when a deviation efficiency by 40% or more - as the invalid state of decompensation. 2. The method according to p. 1, characterized in that the integral indicator of the functional state (IPFS) is calculated by the method of multiple regression analysis, while the number n of the analyzed parameters varies depending on what specific external conditions it is planned to carry out professional activities, as well as the technical capabilities of the means to control the parameters of the physiological state of a specialist, and the general form of the multiple regression equation for calculating IPFS is presented as follows: IPFS = A +/- k ₁ × ΔP ₁ +/- k ₂ × ΔP ₂ +/- ... +/- k _n × ΔP _n , where A is the free term of the equation; P ₁ , P ₂ , ... P _n - controlled physiological and psychophysiological parameters of the functional state (total number n); ΔP ₁ , ΔP ₂ , ... ΔP _n - absolute changes in the current values of the recorded parameters compared to their initial level; k ₁ , k ₂ , ... k _n are the regression coefficients of the corresponding indicators, reflecting the degree of “contribution” of the parameter to the IPFS. 3. The method according to claim 1, characterized in that the number of measured physiological and psychophysiological parameters includes data obtained using electrocardiography, rheocardiography, thermometry, chest mechanography, polarography, viscometry, studies of biomechanics of movements, measurement of heat flow, subjective status. 4. The method according to p. 3, characterized in that, depending on the specific extreme conditions of activity, as measured physiological and psychophysiological parameters, indicators such as blood oxygen saturation (SaO ₂ ), heart rate (HR), and average dynamic blood pressure are recorded (SDD), respiratory rate (CHDTS), average skin temperature (SFTC), mean body temperature (CTT), a distal temperature gradient (DTG), the rectal temperature (T _p), the body temperature falling in the underarm not (Tpodm). 5. The method according to p. 1, characterized in that the decision to include the indicator in the calculation of the integral indicator of the functional state is made provided that it deviates from the reference values, otherwise the parameter value is equated to 0. 6. The method according to p. 1, characterized in that the assessment of the functional state of a specialist in the conditions of his professional activity in real time is formed by comparing the current physiological parameters with their values from an individual "physiological passport", and the formation of a draft decision on the further use of a specialist carried out by identifying signs of dynamic mismatch between the controlled parameters of homeostatic systems "quick response" and subjective state.