RU2214789C1 - Method for determining functional state of organism - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: method involves measuring electric skin conductivity in 24 representative acupuncture points of 12 symmetric meridians and calculated arithmetic mean. Measurement values are transformed to dimensionless units by dividing each measurement by the arithmetic mean. Relations are determined that bind measurement results as top/down, left/right, yin/yang. Knowledge base is built in advance, the knowledge base comprising disease database. The base is built by selecting disease parameters of influence that statistically stable related to a disease and their confidence intervals and calculated values of hypodiagnosis reliabilities (Dhypo) and hyperdiagnosis reliabilities (Dhyper). Confidence intervals being equal to 0.13-1.39 in the point No 2, 0.15-1.52 in the point No 3, 1.07-5.5 in the point No 11, 0.13-0.86 in the point No 14, 0.99-0.93 in the point No 22, yin/yang relations being equal to 0.42-2.43, left/right being equal to 0.5-1.52, top/down being equal to 1.12-1.68, with mean equal to 3.5-66, Dhypo being equal to 0.95, Dhyper being equal to 0.98, changed functional state related to osteochondrosis of lumbosacral vertebral column segment is to be diagnosed. EFFECT: high objectivity level of the obtained results.

Description

 The invention relates to medicine, namely to reflexology, to methods of electro-puncture diagnostics on the electrical conductivity of the skin at biologically active points (BAP).

 There is a method of determining the state of the body by electropuncture diagnostics according to R. Voll (NL Lupichev, Electropuncture diagnostics, homeopathy and the phenomenon of long-range action, Moscow, NPK "Irius", 1990, pp. 13-17), including measurement using the device R. Voll indicators of electrical conductivity of the main diagnostic points located on the back and palmar surfaces of the hands and back and side surfaces of the feet and corresponding to 12 old and 8 new meridians. According to the deviation of the obtained indicators from the norm, the state of organs and systems is diagnosed. Moreover, values within the range of 50-65 units are taken as the norm. instrument scale. Values above normal reflect a state of hyperfunction or inflammation. Values below the norm reflect the state of hypofunction, degeneration. However, the known method is laborious. The interpretation of the results of the study depends only on the qualifications of the doctor. It allows only to judge the nature of pathological processes in a particular organ or system of organs. But it does not make it possible to determine the functional state of organs, to reveal hidden processes, to predict the state of health.

 A known method for determining the state of the body of Nakatani (DM Tabeeva, Guide to acupuncture, Moscow, Medicine, 1960, pp. 560-561). The essence of the method is that they measure the electrical conductivity in the projection area of representative points, 6 on each limb, corresponding to 12 meridians (24 zones). The measurement results are entered into a special Ryo-do-Raku-R chart, compiled by Nakatani, taking into account the average conductivity of Ryo-do-Raku in healthy people, with colored pencils in the form of short horizontal lines. Then the conductivity values of 24 representative points are summed up and dividing this number by 24, an average value is obtained, which is laid down on the two extreme graphs R of the table, connected by a horizontal line, deviating from which by 0.7 cm up and down, two more horizontal lines are drawn and get a strip width of 1.4 cm, which represents physiological boundaries. When Ryo-do-Raku deviates from these boundaries, it is considered pathological. If the Ryo-do-Raku value is above the physiological limit, the state of its redundancy is judged, and if lower, the insufficiency is judged. If all the values of the electrical conductivity of the measured points are within physiological boundaries or slightly extend beyond it, consider that the function of the autonomic nervous system is well balanced, normal. Pathological values are compared with the tables of their correspondence to the symptoms by which this or that diagnosis is made. However, this method has a number of disadvantages. First of all, it is based on the concept of "norm" or "functional corridor", which were built on the basis of a survey of abstractly "healthy" people who, as you know, are not in nature. Its implementation does not take into account the age, gender, regional and professional affiliation of the subject. There is no compensation for the methodological measurement error, depending on environmental conditions. The formulations of the diagnoses are oriented to the subsequent reflexology and are a more or less successful translation of the complex concepts of oriental medicine into the modern medical language. Adding each new diagnosis is possible only by an expert doctor who is equally deeply versed in both eastern and modern (western) medicine, and is subjective in nature. It is impossible to somehow strictly evaluate the reliability of the diagnosis, although everyone understands that no diagnostic report can be guaranteed 100%.

There is a method of determining the functional state of the body (A.T. Neborsky, Normative characteristics of the electrocutaneous conductivity profile of healthy men and women. J. "Human Physiology", 1985, v.2, N 4, pp. 654-664). The method consists in measuring the electrical conductivity of the skin at the points of 24 acupuncture skin zones (ACZ) on the upper and lower extremities. The obtained values are applied to the corresponding meridians of the axis of the polar diagram, and a profile of electric skin conductivity (PEP) is built. As a general integral indicator, the average values of electrodermal conductivity are used for all 24 AKZs. The difference between the maximum and minimum values of the probes assesses the uniformity of the distribution of electric skin conductivity in the zones. For the normative functional range, the so-called "functional corridor", take a zone equal to the double quadratic deviation from the average value of the electrodermal conductivity (EP) for each individual ACZ (EP = 2 μA). Based on all 24 AKZs, normative diagnostic probes are built taking into account seasonal, gender and age differences. Diagnostic assessment is carried out by comparing the probe with the corresponding regulatory probe. The coincidence of 16-24 of the 24 magnitudes of EP according to the defining profile of the EKZ is defined as the absence of differences. Going beyond the upper limit of 16 out of 24 values is estimated as an increase in the overall electrical conductivity of the skin, and beyond the lower boundary as a decrease in the electrical conductivity of the skin, and the state of the body is defined as hyperfunctional or hypofunctional, respectively. The disadvantages of this method include the fact that it is based on the concept of "norm" or "functional corridor", which were built on the basis of a survey of abstractly "healthy" people who, as you know, are not in nature. To eliminate methodical measurement error correction depending on the results of measurements on the environment were constructed various "functional corridors" for the 4 ^x different seasons (summer, fall, winter, spring), that only approximates the real picture: for example, March 1 is is it spring or winter, if there is snow on the street? The formulations of the diagnoses are oriented to the subsequent reflexology and are a more or less successful translation of the complex concepts of oriental medicine into the modern medical language. Adding each new diagnosis is possible only by an expert doctor who is equally deeply versed in both eastern and modern (western) medicine, and is subjective in nature. It is impossible to somehow strictly evaluate the reliability of the diagnosis, although everyone understands that no diagnostic report can be guaranteed 100%.

 There is a known method for determining the state of an organism according to the patent of the Russian Federation 2137457, according to which the skin’s electrical conductivity is also measured at 24 points of 12 meridians, the so-called physiological corridor is built taking into account the average value obtained as a result of the measurement, a diagnostic line is obtained, a central line is identified in the physiological corridor, state determination Meridians and their corresponding organs and functional systems are carried out by the location of the diagnostic line relative to the physiological corridor. When the diagnostic line is located within the corridor and parallel to its central line, the state of the meridian and its corresponding organs and systems is determined to be normal, and when the diagnostic line is located along one of the boundaries of the physiological corridor or when deviated from them and parallel to the central line, as well as in non-parallel its location relative to the central line within the physiological corridor or beyond its borders, the state of the meridian is defined as pathological, moreover, than the deviation is, the pathological process is more pronounced.

 This method has all the disadvantages of the previous method, and the diagnostic criteria are of a qualitative and even more subjective nature.

 The closest analogue to the claimed method is a method for determining the state of the body of DIAKOMS (Kim V.M. et al. Electropuncture diagnostic method according to Nakatani and the computer complex for rapid diagnosis and health monitoring "DIAKOMS", Moscow, 1998, deposited manuscript D225782), according to which skin conductivity is also measured at 24 points of 12 meridians. Then, the results of electrometry are supplemented by anthropological parameters (gender, age, professional and regional affiliation) and compared with the “control groups” that are characteristic of a given disease in the database. Based on the analysis of the correlation between the obtained results of electrometry and the parameters of the "control group", a conclusion is made about the coincidence or mismatch of the results of electrometry with this "control group" and, therefore, the presence or absence of this disease in the patient.

The main disadvantages of this method are as follows:
There is no compensation for the methodological measurement error associated with environmental conditions.

 There is no mechanism for assessing the reliability of diagnosis.

 "Control groups" are based on the selection of patients with only this disease, which is extremely rare in nature.

 Only the sign of the correlation coefficient is taken into account. Correlation coefficients that are close to zero, but differing in sign, are considered completely different, although this difference can only be caused by the known error of the measuring device.

 The role of the subjective factor of an expert doctor, whether or not the patient belongs to the "control group", is significant.

From the analysis of the prior art it follows that none of the currently known methods:
does not give statistically valid results of the state of the body;
does not allow to evaluate the reliability of diagnostic evaluations;
does not provide consideration of environmental conditions;
It does not provide for the accounting of such important factors as gender, age, regional and professional affiliation, time of examination, genotype, etc .;
does not provide objectivity to the results;
does not contain a mechanism for self-learning and self-development.

 Thus, there is a need to improve the known methods for determining the functional state of the body and eliminate these disadvantages.

 The technical result achieved by using the present invention is to increase the reliability and validity of the studies and the conclusion or diagnosis made as a result of these studies.

 The technical result is achieved due to the fact that according to the method for determining the functional state of the body, including measuring electrical skin conductivity at 24 representative acupuncture points of 12 symmetric meridians, calculating its arithmetic mean value, presenting the measurement results in relative units by dividing each measured value by the arithmetic mean value and the subsequent state assessment, additionally calculate the relationship between the measurement results UP / NI W, LEFT / RIGHT, YIN / YAN, pre-form a knowledge base that includes "search images of diseases", formed on the basis of establishing the influencing parameters of the disease, statistically stable associated with it, and their confidence intervals and calculated values of the reliability of underdiagnosis (Hypo) and overdiagnosis (Dhyper) and at confidence intervals at point 2 equal to 0.13-1.39, at point 3 equal 0.15-1.52, at point 11 equal 1.07-5.5, at point 14 equal to 0.13-0.86, at point 22 - equal to 0.09-0.93, and with ratios YIN / YAN equal to 0.42-1.43, LEFT / RIGHT equal to 0.15-1 , 52, UP / NCD equal to 1.12-1.68, with an average of 3.5-66, Dgipo 0.95, Dgiper 0.98, a change in the functional state associated with osteochondrosis of the lumbosacral spine is diagnosed.

 The claimed method is as follows.

 A knowledge base has been formed, which includes extensive statistics, including reliable information on specific diseases. According to the invention, the electrical conductivity of 24 representative points of 12 symmetric meridians is measured using a MEDISKRIN device. A description of this device is given in the description of the patent of the Russian Federation 2142251. The measurements are made in arbitrary units directly proportional to the electrical conductivity. The scale of the MEDISKRIN device is graduated from 0 to 200 conventional units. There is an analytical formula for converting from arbitrary units to conductivity units (Siemens - Cm), which is not given here, since the conductivity units are not used in diagnostic algorithms.

For measurement, other instruments can also be used that ensure linear measurements of electrical conductivity in the entire range (from 1 • 10 ³ cm to 1 • 10 ⁷ cm), for example, AGNIS-BAT-02 and others.

 The arithmetic mean value of all 24 measurement results is calculated. All measurement results are converted from absolute values to relative units by dividing them by the obtained arithmetic mean value to compensate for methodological measurement errors, such as different environmental conditions, different measurement conditions, for example, different composition of saline solution and different degree of saturation with saline solution, etc.

A number of relationships between the measurement results are calculated, such as:
the ratio of UP / NCD (transverse asymmetry) is the ratio of the sum of the measurement results on the hands to the sum of the measurement results on neither legs, the ratio LEFT / RIGHT (asymmetry is lateral) is the ratio of the sum of the measurement results on the left arm and leg to the sum of the measurement results on the right arm and leg, YIN / YAN ratio - the ratio of the sum of the measurement results 1, 2, 3, 7, 8, 9, 13, 14, 15, 19, 20, 21 to the sum of the measurement results 4, 5, 6, 10, 11, 12, 16, 17, 18, 22, 23, 24.

 Next, a common set of initial parameters is formed, consisting of: measurement results in relative units, calculated ratios indicated above, anthropological parameters such as age, gender, regional affiliation, professional affiliation, exact time of the survey (accurate to minutes), genotype and a number of others, which are determined in the process of accumulating statistics and identifying parameters affecting the accuracy of diagnosis.

 The principle of diagnosis consists in comparing the set of initial parameters for a particular patient with the “Search images of diseases” stored in a computer knowledge base (Handbook). A "disease search image" is a collection of intervals of acceptable values for influencing parameters. The influencing parameters include those initial parameters that uniquely determine the disease. These are not only the results of electrometry in certain meridians, but also gender, age, regional affiliation, profession, genotype, etc. Influential parameters are determined by special methods of mathematical processing. Statistical information in the knowledge base must necessarily have clinical confirmation. The "search image" of a particular disease does not include the entire set of initial parameters, but only a part of them (a subset).

 Using the methods of mathematical statistics, criteria are formulated that allow one to select from the set of initial parameters only those (a subset of the influencing parameters) that are most closely and statistically stable associated with this particular disease. Criteria are formulated that allow for each of the influencing parameters for a particular disease to determine the intervals of their confidence values. The value of the confidence interval is built as a compromise between excessive and insufficient diagnostics. The wider the interval of confidence values, the more diseases that are absent in this patient will be diagnosed - excessive, or overdiagnosis. The narrower the confidence interval, the more diseases present in this patient will not be diagnosed - inadequate, or hypodiagnosis. The calculation of the corresponding values and criteria is carried out according to the program, which is registered with the Patent Office of the Russian Federation.

In fact, such a parameter, the value of the confidence interval of which is less than the entire range of values for this parameter, is influential. In the process of collecting statistics for a specific disease and determining the width of confidence intervals, two important statistical indicators are formed - the reliability of overdiagnosis (Dhyper) and the reliability of underdiagnosis (Dhypo). You can also enter a third indicator - generalized reliability, which is a product of overdiagnosis and underdiagnosis:
D = Dgipo • Dgiper. (1)
To illustrate the method for determining the reliability values of overdiagnosis and underdiagnosis, it is most convenient to consider the case when there are two influencing initial parameters A and B. Then the corresponding reliability will be equal to:
DgipoA = NBA / NБ DgiperA = 1-NZA / NZ, (2)
where N3 - the total number of patients in whom the disease is not clinically confirmed conditionally healthy;
NB - the total number of patients in whom the disease is clinically confirmed;
NBA - the number of patients in the confidence interval of the initial parameter A, provided that for all of them the values of the initial parameter B are in the confidence interval of parameter B;
NЗA is the number of conditionally healthy in the confidence interval of the initial parameter A, provided that for all of them the values of the initial parameter B are in the confidence interval of parameter B.

 The values of these confidence values are stored in the same knowledge base as the “Search images of diseases”, since they unambiguously correspond to confidence intervals of influencing parameters. This means that the reliability of the diagnosis is embedded in the diagnostic procedure, and is not determined by the measurement results. The values of confidence intervals in the knowledge base are constructed by maximizing the generalized reliability of D.

 The actual diagnosis is carried out by sequentially comparing the "Search images of each specific disease" from the knowledge base with many of the initial parameters of the diagnosed patient. If the set of initial parameters fell inside the confidence intervals for all the influencing parameters of this “search image”, this means that the patient is diagnosed with this disease, if at least one of the many initial parameters did not fall within the confidence interval, this disease is not detected. We can say that a patient who has not revealed a single disease is considered healthy, which most closely matches the WHO formulation.

 The knowledge base contains “disease search images” for about 150 major diseases for 12 functional systems (cardiovascular, musculoskeletal, genitourinary, endocrine, etc.). As clinically validated statistics accumulate, the list of diagnosed diseases can expand. In each region and with any doctor, "search images of the disease" can be specified, thereby increasing the reliability of diagnosis.

 It is advisable to use the method of forming a "search image of diseases" to form an "individual image of a person", i.e. his most stable and habitual state. This allows you to improve the quality of diagnosis by comparing the current state of the patient and his "individual image of a person." It is important to note that comparing a person with himself is always more reliable and accurate than comparing it with generalized “search images of the disease” obtained from large samples of different people. The most important thing is that the dynamics of changes in the state of a person during treatment is fairly accurately estimated. This is a very convenient "feedback", which allows you to make timely adjustments to the treatment process.

Example 1
Patient Sergey R., age 24 years, examination date 09/21/01 (anthropological parameters) was examined. Absolute values of measurement results (in cu) at 24 points: 8, 4, 7, 18, 7, 9, 7, 7, 13, 2, 13, 7, 10, 4, 4, 20, 6 , 8, 8, 13, 31, 4, 10, 15. The arithmetic mean value (AVERAGE) for all 24 results is 9.90 cu The measurement results in relative (divided by AVERAGE) are respectively: 0.81; 0.41; 0.72; 1.80; 0.68; 0.87; 0.75; 0.73; 1.38; 0.25; 1.35; 0.66; 1.05; 0.44; 0.44; 2.02; 0.59; 0.81; 0.79; 1.36; 3.14; 0.36; 1.05; 1.54. Relations: YIN / YAN = 1.01; LEFT / RIGHT = 0.80; UP / DOWN - 1.31. Using the proposed method diagnosed and clinically confirmed "Osteochondrosis of the lumbosacral spine." For this diagnosis, the influencing parameters and their confidence intervals are as follows: 2 = [0.13-1.39]; 3 = [0.15-1.52]; 11 = [1.07-5.5]; 14 = [0.13-0.86]; 22 = [0.09-0.93]; YIN / YAN = [0.42-1.43]; LEFT / RIGHT = [0.15-1.52]; TOP / LOW = [1.12-1.68]; AVERAGE = [3,5-66]. Hypo = 0.95; Dgiper = 0.98.

 Thus, the claimed method for determining the functional state of the body allows you to automate and computerize the processing of examination results and provides a diagnosis of a specific disease or functional abnormality.

Claims (1)

 A method for determining the functional state of an organism, including measuring electrical skin conductivity at 24 representative acupuncture points of 12 symmetric meridians, calculating its arithmetic mean value, presenting the measurement results in relative units by dividing each measured value by an arithmetic mean value and then evaluating the condition, which is further calculated correlation between measurement results top / bottom, left / right, yin / yang, pre-forms They form a knowledge base including “search images of diseases”, formed on the basis of establishing the influencing parameters of the disease, statistically stably associated with it and their confidence intervals and the calculated values of the reliability of underdiagnosis (Dhypo) and overdiagnosis (Dhyper) and at confidence intervals at point 2 equal to 0.13-1.39, at point 3 equal 0.15-1.52, at point 11 equal 1.07-5.5, at point 14 equal 0.13-0.86, at point 22 - equal to 0.09-0.93, and with yin / yang ratios equal to 0.42-1.43, left / right - equal to 0.15-1.52, top / bottom - equal to 1.12-1, 68, with an average of th 3,5-66, Dgipo 0.95, 0.98 Dgiper diagnose changes in the functional status associated with osteochondrosis of the lumbosacral spine.