RU2518338C1 - Method for assessing functional reserves of human body - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: method involves collecting expired breath condensate (expirate), preparing a biological sensor - luminescent lyophilised bacteria Ecolume, adding expirate 0.5 cm³ to the biological sensor 0.5 cm³, exposing for 15 minutes, measuring a luminescence intensity of a mixture of the bacterial suspension and condensate for 1000 s, recording its maximum ("Иоп", imp/sec), comparing this value to an analogous parameter "Ик", imp/sec derived by introducing an equal amount of distilled water into a bioluminometer tray instead of condensate, specifying the coefficient K as a relation of "Иоп/Ик", additionally determining an estimated biological age (EBA, years) of a person being tested, calculating a relation of the biological and chronological (CA) ages - EBA/CA, and if K>1 (high level of oxygen radicals) with EBA/CA>1, insufficient functional reserves of the human body are stated; if K≤1 (productive antioxidant systems) and EBA/CA≤1, an optimum level is stated; K≤1, EBA/CA>1 show an inconclusive assessment result, antioxidant balance monitoring and an in-depth functional study.

EFFECT: method enables avoiding the fragmented nature of the assessment, determining a degree of the body stress and effective directions of therapeutic and preventive measures to create conditions for up-coming transition of the body functioning.

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Description

FIELD OF THE INVENTION

The invention relates to preventive medicine and laboratory diagnostics, is intended to identify functional reserves in a screening epidemiological examination of large contingents of workers.

It can be used individually to establish mechanisms and the degree of tension in the body when choosing therapeutic measures.

The method includes determining the indicator of oxidative status (K) from the fixed maximum values of the luminescence intensity of the biosensor - lyophilized bacteria "Ekolyum" (Iop, Ikontr), formed in 1000 seconds of reaction with the addition of 0.5 cm ^{3 of the} activator - human expirate and distilled water into the cells of the bioluminometer , finding the coefficient K (Iop / Ikontr), additional establishment of the calculated biological (RBV) and calendar (KB) ages by pulse blood pressure indicators, mmHg (difference between diastolic and systolic blood pressure), breath holding time (sec), static balancing (sec) of body weight (kg), subjective health assessment (questionnaire data), establishing the RBV value according to the above indicators and calculating based on the population model obtained by the multiple linear regression method [10], finding the RBV / CV ratio, the values of which make a conclusion about the functional reserves of the human body:

K> 1, RBV / KB> 1 - insufficient functional reserves of the body

K≤1, RBV / KV≤1 - the optimal level of functional reserves of the body

To> 1, RBV / KB close to 1 - preservation of the functional reserves of the body, the feasibility of correcting the antioxidant balance, dynamic observation

K≤1, RBV / HF> 1 - the uncertainty of the evaluation result, monitoring the antioxidant balance, in-depth functional examination.

In conclusion, according to the last position, the depth of the RBV deviations from KB is important for choosing the volume of examination.

An urgent problem of biology and medicine is the study of the body's response to the effects of adverse environmental factors, leading to the restructuring of functional systems and a decrease in adaptive potential, which can lead to an acceleration in the rate of formation of pathological conditions [1-4].

It is known that the mechanisms of increasing the body's resistance to acting factors (hypoxia, stress, physical and emotional stress, chemical pollution of the environment) are periodically repeated generation of reactive oxygen species, the result of which is the induction of the synthesis of protective systems. The protective action is based on a change in the physiological relationship between the level of free radical oxidation and antioxidant protection, the need to ensure a certain level of human activity due to self-regulation processes is closely related to the body's ability to adapt, its stability under the negative impact of the environment. Moreover, deviations in oxidative status are one of the leading mechanisms for the formation of a number of severe pathologies, early aging, and a decrease in the country's labor potential, which determines the performance requirements and the accuracy of diagnostic methods for assessing the body's functional reserves.

The purpose of the present invention is to overcome the shortcomings of existing methods and create a methodological approach, the distinguishing feature of which is the combination of chemiluminescence indicators of a non-invasive biological medium (expirate) as a marker of general oxidative processes in the body with an integral index value reflecting a retrospective characteristic of human physiological reserves.

The advantage of the developed method is a higher technical result due to the additional inclusion of the integral index of RBV / CV, which eliminates the fragmentary nature of the assessment, determines the degree of tension in the body and the effective directions of therapeutic and preventive measures to create conditions for the transition of its functioning to a higher level.

Background of the Related Art

In terms of the proximity of the technical nature of the known methods to the proposed, methods are considered that can be differentiated in their orientation to the application of functional methods to identify the state of one or more systems of the human body, including the use of stress tests.

Another group of non-invasive laboratory methods includes the study of biological media for the quantitative assessment of the overall functional state of the body according to the proposed criteria.

Methods are presented in which integrated assessments of an individual’s functional reserves are based on retrospective characteristics of an organism, obtaining predictive estimates of further life reserves.

There is a method of rapid analysis of the functional state of the human cardiovascular system and the nature of its regulation by the autonomic nervous system and other regulatory systems of homeostasis [6]. The invention is used for the diagnosis of cardiovascular diseases in a clinic, during operational medical monitoring of the health status of various population groups, as well as in medical prognostic studies in order to assess trends in the development of functional preclinical changes in the cardiovascular system and the likelihood of their going beyond acceptable limits. The disadvantage of this method is that it does not represent the possibility of a comprehensive assessment of the functional state of the body and does not reveal possible deviations from other systems (respiratory, oxygen transport, etc.).

The well-known "Method for assessing the functional state of the cardiovascular system", which is carried out by measuring blood pressure (BP) and registering a pulse wave during one respiratory cycle in order to determine the average duration of one cardiocycle and the pulse pressure rise time (t, ms) [7 , 8]. The method allows using the proposed empirical formulas in terms of "t", diastolic and pulse pressures to give an indicative estimate of the degree of severity of functional stress under the influence of physical activity (conventional unit). The disadvantage of this method is the low accuracy and information content.

There is a method for assessing the functional reserves of the human body [9, 12], including carrying out a load hypoxic test for 10 ± 0.1 minutes using depleted (up to 10-11%) oxygen hypoxic gas mixture, followed by 3 ± 0.1-minute reoxygenation while registering physiological parameters (respiratory rate and heart rate, blood pressure, oxygen saturation of arterial blood), finding the value of the coefficient of functional deviations, the values of which state the level functional reserves.

The disadvantage of this method is the orientation on the physiological parameters of only the cardiovascular system, which narrows the scope of its application for the purpose of a full diagnostic examination when establishing body reserves.

Technically close are methods [5, 11], aimed at assessing the functional state of the human body in terms of oxidative balance in the body as one of the most important aspects of homeostasis.

The methods include finding a criterion indicator for the ratio of the formation of oxygen radicals and the prooxidant system, the values of which correspond to different levels of the functioning of the body from reversible states to oxidative stress.

The closest in technical essence is the method of assessing the functional state of a person [11], based on the use of a biotest (chemiluminescence of lyophilized bacteria) and a non-invasive diagnostic biomedia (expirate) for screening assessment by a criterion indicator reflecting the oxidative balance of the biomedia and the organism as a whole.

The disadvantage of the methods is that the assessment of the functioning of the whole organism is carried out on the basis of quantitative dependencies of the parameters of one of the sides of homeostasis (oxidative status) in the current period of time and does not allow them to identify possible functional reserves in the upcoming human life cycle, i.e. to make a forecast and give reasonable recommendations for the correction of deviations in the state of health.

There is a method for screening an integrated assessment of the functional state of an organism [10], based on establishing the biological age (BV) of an individual based on the multiple linear regression method and a mathematical model based on a battery of tests reflecting the state of the cardiovascular and respiratory systems and subjective health assessment ( according to questionnaire survey), due biological age (DBV) for the conclusion on the degree of aging.

The disadvantages of the method can be attributed to the limited nature of the included indicators, which can, on the one hand, reflect and, on the other, significantly influence (in particular, antioxidant balance) on biological age when implementing targeted correction measures, such as antioxidant-nutritional support of the body.

Another disadvantage is the lack of an individual integral indicator characterizing the physiological reserves of a person.

Examples of the method

In the establishment of indicators of the calculated biological age (hereinafter - RBV), there are some gender differences in the indicators included in the calculation formula, which are reflected in the examples given. All indicators are obtained before the start of work.

Example 1

Patient M., 49 years old, profession - welder. Experience 33 years.

To evaluate the functional reserves of the body during the examination, an expirate (condensate of exhaled moisture) was collected for 20 minutes with unforced breathing. A sample was taken in a modernized Polezhaev absorber placed in a mixture of ice with sodium chloride for better condensation.

0.5 ml of distilled water was added to the Biotoke-10M bioluminometer cuvette containing 0.5 ml of prepared Ekolyum biosensor and after a 15-minute exposure the maximum value of chemiluminescence intensity was measured over a period of 1000 seconds (Ikontr), which amounted to 3211 imp / s In another cuvette, 0.5 ml of the test bioassay was added to 0.5 ml of the biosensor. Under similar conditions, the measurements recorded the maximum value of the intensity Iop = 2410 imp / sec.

The coefficient K = Iop / Ikontr was 0.75.

A decrease in the intensity of bacterial chemiluminescence indicates active antioxidant processes associated with a high level of protective reserves from the damaging effects of oxygen radicals.

Additionally, RBV is calculated according to indicators of systolic blood pressure (BPA, mmHg), diastolic blood pressure (ADD, mmHg), breath holding time on inhalation (HFA, sec), duration of static balancing (SB, sec) , body weight (MT, kg), subjective health assessment (POPs, points).

Obtaining indicators for determining RBV was carried out under the following conditions.

Blood pressure systolic (ADS) and diastolic (ADD) are measured according to the generally accepted method using the Riva-Rocci apparatus on the right hand, in the sitting position, three times with an interval of 5 minutes. The results of the measurement at which the blood pressure was the smallest value are taken into account. Pulse arterial pressure (ADP) is calculated as the difference between the blood pressure and blood pressure.

The duration of breath holding (sec) after a deep breath (HFA) is measured three times with an interval of 5 minutes using a stopwatch. The highest HFA value is taken into account.

Static balancing (SB) is determined when the subject is standing on his left leg, without shoes, eyes are closed, hands are lowered along the body (without preliminary training). The duration of the static balancing (sec) is measured using a stopwatch three times with an interval of 5 minutes. The best result is taken into account.

Body weight (MT) in light clothing, without shoes, on an empty stomach is determined using a medical scale.

A subjective health assessment (POP) was carried out using a questionnaire that included the following 29 questions on self-esteem of health and social aspects reflecting the patient's quality of life:

1. Do you have headaches? 2. Can you say that you easily wake up from any noise? 3. Do heart pains bother you? 4. Do you have pain in the liver? 5. Are you worried about joint pain? 6. Do you have pain in the lower back? 7. Do you think your vision has deteriorated in recent years? 8. Do you think your hearing has deteriorated in recent years? 9. Do constipation bother you? 10. Does a change in the weather affect your well-being? 11. Do you have dizziness? 12. Do you try to drink only bottled or filtered water? 13. Do you think that now you are as efficient as before? 14. Can you say that you began to cry easily? 15. Do you experience periods when you lose sleep due to unrest? 16. Do you think that it has become more difficult for you to concentrate now than in past years? 17. Do you feel weak memory, forgetfulness? 18. Do you feel burning, tingling, “crawling” in various parts of the body? 19. Do you have such periods when you feel joyfully excited, happy? 20. Do you experience tinnitus or ringing? 21. Do you have swelling on your legs? 22. Do you have to give up some dishes? 23. Do you have shortness of breath when walking fast? 24. Do you get tired of traveling by public transport? 25. Do you have to use any mineral water for medicinal purposes? 26. Do you have a bad taste in your mouth? 27. Is there enough income in your family? 28. Are you satisfied with your physical abilities? 29. Do you have good health?

Answers are analyzed (“Yes”, “No”), adverse ones are calculated (their number can range from 0 to 29), which are included in the formula for determining RBV.

The following data were obtained from the examined patient:

ADS, mmHg ADD, mmHg Sat, sec Body weight Pops points 131 89 2 70 fourteen

In this case, arterial pulse pressure (ADP) is calculated as the difference between arterial systolic and diastolic pressure and in this case is 131-89 = 42 mm Hg.

The values of ADP, SB, MT and POPs are included in the formula for calculating the biological age based on the population model obtained by the multiple linear regression method (10):

RBV = -1.463 + 0.415 • ADP-0.140 • SB + 0.248 • MT + 0.694 • POPs.

RBV = -1.463 + 0.415 • 42-0.140 • 2 + 0.248 • 70 + 0.694 • 14 = 42.80.

At the same time, the index of the calculated biological age (42.80 years) to the calendar (49 years) RBV / CV was 0.87, which is less than 1.

Thus, evaluation of the data on the comprehensive test K and RBV / KB allowed us to establish the presence of active antioxidant processes in this patient, a high level of protective mechanisms, and the presence of sufficient functional reserves.

Example 2

Patient P., 50 years old, profession - welder. Experience 32 years.

The study of the expirate, conducted by a method similar to that described in example 1, showed that Ikontr. = 1408, Iop. = 2416, K = 1.72, that is, significantly more than unity, which indicates the predominance of radical processes and the possible development of oxidative stress.

To evaluate RBV, the following data were obtained:

ADS, mmHg ADD, mmHg Sat, sec Body weight Pops points 156 94 10 90 23

Arterial pulse pressure (ADP) - 62 mmHg

Estimated biological age:

RBV = -1.463 + 0.415 • 62-0.140 • 10 + 0.248 • 90 + 0.694 • 23 = 61.15 years.

RBV / HF = 61.15 / 50 = 1.22.

In this case, the value of indicators K and RBV / KB more than 1 allows us to conclude that the functional reserves of the body are insufficient and that it is advisable to use therapeutic and preventive courses (antioxidant-nutritional support), as well as dynamic monitoring.

Example 3

Patient P., 47 years old, profession - sinker. Experience 24 years.

According to the study of condensate of alveolar moisture, the maximum values of the intensity of chemiluminescence were:

Ikontr = 6620 imp / s, Iop = 10614 imp / s.

The value of the coefficient K = 1.6 (more than 1), which indicates the predominance of the processes of radical formation and an insufficient level of antioxidant protection.

To establish RBV taking into account gender differences in a patient, systolic blood pressure (BPA, mmHg), breath holding time on inhalation (HFA, sec), duration of static balancing (SB, sec) were measured; subjective health assessment (POPs, points)

ADS, mmHg HFA, sec Sat, sec Pops points 143 23 3 12

The values of ADS, HFA, SB, POPs are included in the formula for calculating the biological age:

RBV = 26.985 + 0.215 • ADS-0.149 • HFA-0.151 • SB + 0.723 • POPs.

RBV = 26.985 + 0.215 • 143-0.149 • 23-0.151 • 3 + 0.723 • 12 = 62.53.

The ratio of RBV / HF was 62.53 / 47 = 1.33.

As in example 2, the values of indicators K and RBV / KB more than 1 allowed us to conclude that the functional reserves of this patient are insufficient. For the purposes of correcting the oxidative balance and reducing the biological age, targeted antioxidant and nutritional therapy and dynamic observation are recommended.

Example 4

Patient R., 50 years old, profession - sinker. Experience 22 years.

Assessment of the functional reserves of the body for the study of the chemiluminescence of the expirate showed that at the maximum values of Ikontr. = 4130 and Iop. = 5149. The coefficient K = 1.25, which indicates the predominance of prooxidant processes in the body, the lack of protection against the damaging effects of oxygen radicals.

Estimated biological age is calculated from the following data:

ADS, mmHg HFA, sec Sat, sec Pops points 122 33 fifteen 7

RBV = 26.985 + 0.215 • 122-0.149 • 33-0.151 • 15 + 0.723 • 7 = 51.09 years.

The ratio of RBV / HF was 51.09 / 50 = 1.02, which is close to 1.

Despite the fact that antioxidant balance disorders were noted, the RBV / HF indicator allows us to state the adequacy of the functional reserves of the body, but in the prognostic plan indicates the advisability of correcting the antioxidant function, which eliminates the possibility of a negative effect on biological age.

The lack of antioxidant protection of the body in the absence of pronounced differences in the values of RBV from KB allows us to conclude that it is necessary to monitor the patient dynamically in order to identify subsequent possible deviations in the state of health and prescribe timely correction measures to prevent the development of irreversible changes, oxidative stress, which can lead to negative consequences, including an increase in RBV.

Example 5

Patient L., 62 years old, profession - geologist. Experience 26 years.

According to the results of studying the expiratory chemiluminescence intensity, the coefficient K = 0.57 was established (at Ikontr = 5044 and IOP = 2900), which allows us to ascertain the predominance of antioxidant processes associated with a high level of protective reserves from the damaging effect of oxygen radicals.

The determination of RBV was carried out analogously to examples 3 and 4.

ADS, mmHg HFA, sec. Sat, sec Pops points 133 28 13 10

Estimated biological age:

RBV = 26.985 + 0.215 • 133-0.149 • 28-0.151 • 13 + 0.723 • 10 = 56.67 years.

The ratio of RBV / HF was 56.67 / 62 = 0.91.

In this case, K <1 and RBV / KB <1, which indicates sufficient productivity of the antioxidant system and the optimal functional reserves of the patient's body.

Example 6

Patient N., 39 years old, profession - operator of the greenhouse complex. Experience 12 years.

The following results were obtained to assess the functional reserves of the body. According to the results of a study of the expiratory chemiluminescence intensity Ikontr. = 2626, Iop. = 2521, the coefficient value K = 0.96 (less than 1), which allows us to state the optimality of the oxidative balance.

However, the definition of RBV, conducted similarly to the previous examples, showed a value of 45.30 years:

ADS, mmHg HFA, sec Sat, sec Pops points 132 52 four 2

Estimated biological age:

RBV = 26.985 + 0.215 • 132-0.149 • 52-0.151 • 20 + 0.723 • 2 = 45.30 years.

The ratio of RBV / HF was 45.30 / 39 = 1.16 (more than 1).

In this case, K≤1 and RBV / KB> 1, which indicates the uncertainty of the evaluation result, the need to monitor the antioxidant balance, as well as an in-depth functional examination of this patient

The above examples demonstrate the practical application of the proposed method for screening the assessment of the functional reserves of the body, which is important for the purposes of preventive medicine in resolving issues related to the conditions of production and the state of health of workers, preventing the formation of persistent pathologies that can adversely affect the country's labor potential.

Bibliography

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3. Korneev N.V., Davydova T.V. Functional stress tests in cardiology // M., MEDICA., 2007.-287 p.

4. Malov Yu.S. Adaptation and health. Clinical medicine №12.-2001. S.61-63.

5. Description of the invention to patent RU No. 2206891 C1 “Method for assessing the antioxidant balance of the human body” published on 06/20/2003. Authors: Yudina TV, Rakitsky AN, Egorova MV

6. Description of the invention to patent RU No. 2268639 C1 “Method for the pulsometric evaluation of the functional state and nature of the autonomic regulation of the human cardiovascular system”, published April 14, 2004. Authors: Nesterov VP, Burdygin A.I. Nesterov S. AT.

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Claims (1)

A method of evaluating the functional reserve of the human body, comprising a condensate collecting exhaled moisture (ekspirata) preparing the biosensor - lifilizirovannyh luminescent bacteria "Ekolyum", adding to 0.5 cm ³ biosensor ekspirata 0.5 cm ^3, 15 minute exposure, the luminescence intensity measurement mixture suspension of bacteria and condensate for 1000 s, fixing its maximum level (IOP, imp / s), comparing this value with the same parameter Ic, imp / s, obtained when a bioluminometer was introduced into the cuvette instead of disti condensate water in an equal volume, the establishment of the coefficient K as the Iop / Ik ratio, characterized in that it further determines the estimated biological age (RBV, years) of the subject, find the ratio of the calculated biological and calendar (KB) ages - RBV / KV, and at K> 1 (high level of formation of oxygen radicals) with simultaneous RBV / KB> 1 conclude that the functional reserves of the human body are insufficient, at K≤1 (productive antioxidant systems) and RBV / KB≤1 they determine their optimal level, at K≤1, RBV / KV> 1 - the uncertainty of the evaluation result, monitoring the antioxidant balance, in-depth functional examination.