RU2556839C2 - Method for controlling functional state of patient's body - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention refers to medicine, functional diagnostics and can be used for preclinical, predoctoral examination, assessment of the functional state of body organs and systems, and pre-diagnosis. The method involves measuring electrical conductivity (EC) of 24 representing points of 12 symmetrical meridians, determining an arithmetic mean (AM) value of these measurements and specifying a corridor of permissible values for this patient, to which the derived values are compared in order to assess the functional state of the patient's body. That involves using the following criteria: a ratio of total ECs of Yin meridian points to total ECs of Yang meridian points, a ratio of total ECs of arm points to total ECs of leg points, a ratio of total ECs of left-side points to total ECs of right-side points. ECs are measured at voltages 5V, and/or 9V, and/or 12V. If the measurements are taken at 9V, the measured ECs are re-calculated by formula: I new=9/(29/I measured-0.1)*Coeff, (I); if the measurement process is performed at 12V, the measured values are re-calculated by formula: I new=9/(29/I measured-0.1)*Coeff, (I); and at 5V: I new=1 measured*Coeff, (III), wherein in (I), (II) and (III) respectively: I new is the re-calculated EC; I measured is the measured EC; Coeff is a correction coefficient taking into account a meridian conductivity heterogeneity. The re-calculated values are transformed into adjusted ones by formula: I adjusted=I new/I mean, wherein: I adjusted is the adjusted EC; I new is the non-adjusted re-calculated EC; I mean is the arithmetic mean value of all the 24 measurements. That is followed by delimiting an individual normal corridor for this patient depending on the preset diagnostic sensitivity S and a width of corridor of the permissible EC values Wpv. The Wpv represents a range of EC values measured in this patient, whereas the diagnostic sensitivity S is specified depending on selecting the patients with a certain disease. Delimiting the individual normal corridor for this patient is ensured by measuring intermediate coefficients for lower Kl and upper Ku corridor limits respectively: Kl=1-(1-S)*Wpv/2.1 and Ku=1+(1-Kl)*1.1. Lower L and upper U limits of the individual normal corridor are determined: L=Kl* I mean and U=Ku* I mean. That is followed by comparing I adjusted to the derived limits of the individual normal corridor.

EFFECT: method provides high accuracy of the individual diagnosis.

4 tbl, 2 ex

Description

The invention relates to medicine, in particular to functional diagnostics, and can be used to conduct preclinical pre-medical examination of patients, determine the functional state of organs and systems of the body and make a preliminary diagnosis with subsequent refinement and therapy.

The fact that the diagnosis of various human diseases can be made not only on the basis of organic changes in the body that are detected during various clinical examinations or clarification of patient complaints, but also on the basis of functional disorders, was discovered by R. Dubois in 1857. Then G.A. began to deal with the functional dependence of certain points on the human body with the systems of the body. Zakharyin - 1883; I.R. Tarkhanov - 1889; G. Ged - 1898; V.Yu. Chagovets - 1903; S. Weidman - 1956 and others. The points by which one can judge the function of one and the same system of the human body are mentally united in the lines of the “meridians”.

According to the electrical characteristics of the meridians, we can conclude about the state of organs and systems related to these meridians. Each meridian has many representative points (acupuncture points), the conductivity at which can completely characterize the state of the meridian. The most convenient points for measurements are located in the wrist joint and in the foot. When interpreting the measurement results, it is not so much the absolute values that are considered, but the ratios of these values. The methodology is structured in such a way that not only the functions of individual organs are studied, but also the totality of the functioning of organs in relation to each other, i.e. It considers a situation where all organs influence each other. In this case, it becomes possible to accurately make a functional diagnosis. The method allows the detection of diseases when they are not detected by clinical methods. Diagnostics using the measurement of electrical parameters of the skin (electrodermatometry), is currently considered one of the proven methods of functional diagnostics. A measuring electrode is used to study a representative acupuncture point on the right and left. The generally accepted concept is the “physiological corridor” (the corridor of permissible values), which is as follows. An optimally functioning organism is characterized not so much by “good” absolute values of physiological parameters as by their symmetry and minimal scatter of values. The permissible deviation from the average, fit into the "physiological corridor", is + 10%. Organs falling out of the corridor need therapy. Subsequently, the methods of electrodermatometry were repeatedly improved, more sensitive advanced instruments for measuring the electrical characteristics of meridians were created.

So, in patent RU 2289388, publ. December 20, 2006, a method for acupuncture diagnostics and correction of the functional state of the body is disclosed, which includes measuring the electrical conductivity of the skin at 24 biologically active representative points (BART) of 12 paired meridians of acupuncture skin zones, compiling a normalized table of electrical conductivities, building an individual corridor. The conductivity assessment is carried out according to the direction of the output of values beyond the boundaries of the individual corridor. The boundaries of the individual corridor are determined by the formulas B = Ср · Кв + Δ ₁ and Н = Ср · Кн-Δ ₂ , where В is the upper boundary of the individual corridor, Ср is the average normalized conductivity of all meridians, Kv = 1.05 ... 1.2 - normalizing coefficient of the upper boundary of the individual corridor, Δ ₁ = 2 ... 5 - the tolerance value, compensating for measurement errors to determine the upper boundary of the individual corridor, N - the lower boundary of the individual corridor, Kn = 0.8 ... 0.95 - normalizing coefficient of the lower boundary of the individual corridor , delta = ₂ 2 ... 5 is the magnitude of the tolerance, ompensiruyuschego error of measurement to determine the lower limit of the individual corridor. Paired meridians are revealed in which one BART has an electrical conductivity that matches the individual corridor, and the other has an electrical conductivity greater than the upper or less than the lower boundary of the individual corridor. The diagnostic method improves its accuracy by determining the boundaries of the individual corridor of each person.

Patent RU 2137457 describes a method for determining the state of an organism, according to which the electrical conductivity of 24 points of twelve symmetric meridians is measured. Put the obtained values on the scales of the graph table. Pre-scale applied to the right and left sides of each column of the table. Connect the values to each other, obtaining a "diagnostic line". In the "physiological corridor" distinguish the center line. The state of the meridians is determined by the location of the "diagnostic line" relative to the boundaries of the "physiological corridor" and its center line. When it is located within the boundaries of the "physiological corridor" and parallel to the center line, the state of the meridian and its corresponding organs is defined as normal. When it is located along the borders of the "physiological corridor" or deviates from them and is parallel to the center line and if it is not parallel within the "physiological corridor" or beyond its borders, the state of the meridian and its organs is defined as pathological. The method allows for rapid diagnosis of the state of the body.

However, all the currently existing methods, being simple and not requiring significant time costs, do not take into account the individual parameters of the patients, and the boundaries of the normal range are constant, not taking into account the sensitivity with which diagnostics can be carried out.

Closest to the present invention is the rapid diagnostic method according to patent RU 2008887, which is also based on measurements of the electrical conductivity of skin parameters in the area of acupuncture points. When implementing the known method, the main and additional zones of possible deviations from the arithmetic mean value of all measurements are determined, the measured values are compared with the boundaries of the zones by summing the measured values from certain points, additional diagnostic criteria are determined, taking into account which, and also taking into account the measured values in relation to the borders judge possible pathological changes in the patient's body.

This method, like all those discussed above, does not take into account the sensitivity with which diagnostics can be carried out, and does not take into account the individual parameters of each patient to establish the width of the normal corridor.

The problem to which the present invention is directed is to conduct diagnostics with a given sensitivity and taking into account the individual corridor boundaries of the normal range.

The proposed method for monitoring the functional state of the patient’s body includes:

conductivity measurement of 24 representative points of 12 symmetric meridians, determination of the arithmetic mean value of these measurements with the establishment of a corridor of acceptable values for a given patient, based on the results of comparison with which the obtained values of indicators judge the functional state of the patient’s body, using the following indicators: ratio of the sum of the values of electrical conductivity of Yin meridians points to the sum of the conductivity points of the Yang meridians, the ratio of the sum of the conductivity values points on the feet, the ratio of conductivity values of points measured on the left side of the body, to the sum of the values of the electrical conductivity of points measured on the right side of the body,

the patient’s conductivity is measured at voltages of 5 V and / or 9 V and / or 12 V, and when using the patient’s data obtained when measuring at 9 V, the measured conductivity values of the above representative points are recalculated by the formula:

I new = 9 / (29 / I measurement-0.1) * Coeff. (I)

when using patient data obtained during measurements at a voltage of 12 V, the measured values of the electrical conductivity of said representative points are recalculated by the formula:

I new = 12 / (29 / I meas-0.1) * Coeff. (Ii)

when using data obtained during measurements at a voltage of 5 V:

I new = I measured * Coeff, (III)

where in (I), (II) and (III), respectively:

I new - recalculated value of electrical conductivity,

I measured - the measured value of electrical conductivity,

Coeff - the value of the correction coefficient, taking into account the heterogeneity of the conductivity along the meridians, in accordance with table 1 below.

further recalculated values are translated into the given values by the formula:

I lead = I new / I Wed,

Where:

I cited is the reduced value of electrical conductivity,

I new - recalculated without reduction the value of electrical conductivity,

I cf - the arithmetic mean of all 24 measurements taken,

then, the boundaries of the individual norm corridor for a given patient are determined depending on the given sensitivity of the diagnostic diagnostics and the width of the corridor of acceptable values of the conductivity conductivity, the conductivity is the variation in the conductivity values measured in this patient, and the sensitivity of the diagnostics is chosen depending on the available sample of patients with this disease, and the values of the boundaries of the individual normal range for this patient are determined as follows:

- first, intermediate coefficients are calculated for the lower Кн and upper Кв corridor boundaries, respectively:

Kn = 1- (1-Chv) * Shdp / 2,1;

Qu = 1 + (1-Kn) * 1.1;

- and the actual lower H and upper B boundaries of the individual normal range are calculated:

H = Kn * I cf .;

B = Kv * I avg;

- a comparison is made of I cited with the obtained boundaries of the individual normal range.

The technical result is enhanced due to the fact that 24 reduced conductivity values, the arithmetic average of all 24 converted conductivity values, the ratio of the sum of the Yin meridians to the sum of the Yang meridians, the ratio of the sum of the values of the electrical conductivity of the hands to the sum of the values of the electrical conductivity of the legs are taken as parameters for assessing the functional state, the ratio of the sum of the conductivity values measured on the left side of the body to the ratio of the sum of the conductivity values of Eren on the right side of the body. When making a conclusion on the standing of the meridians, data on the age and gender of the patient are used. To increase the accuracy of diagnosis, the patient’s body temperature, systolic and diastolic pressure, weight, as well as parameters of a clinical blood test are taken into account. The specificity of the diagnosis is determined, which is the proportion of patients diagnosed with an express diagnosis of a disease that is not detected by the methods of classical medicine.

The method is based on the fact that there is a correlation between the conductivity of direct current at certain points on the arms and legs of a person and his functional state. The conductivity during the implementation of the method is measured using a special device - the so-called sensor, which has a safe open circuit voltage (with open electrodes) of 5 V, and a short circuit current (with closed electrodes) of 37 μA. To measure the conductivity, the device disclosed in the patent for invention RU 2142251 or the patent for utility model RU 79405 can be used. For measurement, 6 points are used on each arm and leg (Fig. 1). The accepted way of traversing points is as follows:

1) 6 points on the right hand (points H1-H6),

2) 6 points on the right foot (points F1-F6),

3) 6 points on the left hand (points H1-H6),

4) 6 points on the left foot (points F1-F6).

Table 1 shows the numbers of meridians, their accepted names, eastern affiliation with Yin / Yang and the points at which measurements are made.

Since the values are measured on these meridians both on the right and on the left, the total number of measured values is 24. Hereinafter, the measured parameters and a number of parameters obtained by calculation are called the meridian. The measurement order does not correspond to the serial numbers of the meridians. In this regard, the measurement results are assigned to the corresponding numbers of meridians.

The electrical conductivity values obtained using the sensor are converted in the conversion unit from the measured values of Hmeasure to new values of H new. This is done in order to take into account the transition of measurements at voltages of 12 and 9 V to the used safe voltage of 5 V. Recalculation is carried out according to the formula:

N new = 9 (12) / (29 / Measure-0,1) * Coeff;

where H new - recalculated value of electrical conductivity,

Meas. - the conductivity value measured by the sensor,

Coeff - the value of the corresponding coefficient from the table. one.

in the case of using the data accumulated during measurements at a voltage of 5 V, the mentioned values of electrical conductivity only multiply by the coefficient from the table. 1. Recalculation is necessary in order to take into account the heterogeneity of conductivity along the meridians and to use the data accumulated at previously used voltages. In the future, as the accumulation of new static data from the recount can be abandoned.

Based on the recalculated values of H, a basic set of parameters is determined that will be further used in assessing the functional state of the patient. The methodology for accounting parameters is described in the closest analogue of RU 2008887. These parameters are as follows:

1. Icp - arithmetic mean of all 24 values of the recalculated measurements

2. Yin - the sum of the values of the Yin meridians

3. Jan - the sum of the values of the yang meridians

4. top - the sum of the values of the meridians for the hands

5. bottom - the sum of the values of the meridians for the legs

6. right - the sum of the values of the right meridians for arms and legs

7. left - the sum of the values of the left meridians for arms and legs

8. yin / yang ratio

9. top to bottom ratio

10. left / right ratio

The recalculated values themselves are again recalculated into those given to compensate for the methodological measurement error associated with changes in skin moisture under various climatic conditions of the environment. Recalculation is carried out by dividing the values of I new on the value of I cf.

Recalculated parameter values are recalculated into those given by the formula:

I lead = I ′ new / Icp,

where I cited is the reduced value of electrical conductivity,

I ′ new is the conductivity value recounted without reduction,

Icp is the arithmetic mean of all 24 measurements taken.

A set of 24 given values and parameters of Yin / Yang, Top / Bottom, Left / Right, Gender, Age, Icp are a basic set of parameters that determine the presence of a disease. The conclusion on the presence or absence of diseases is carried out using the parameters specified in RU 2008887, or the parameters indicated above.

In some diagnostic algorithms, in addition to the specified basic parameters, to increase the accuracy of diagnosis, the human body temperature, systolic and diastolic pressure, weight, and values of the parameters of the clinical blood test can be taken into account.

The width of the corridor of permissible conductivity values of the SHDP is determined using data obtained as a result of repeated studies of the patient. SHDP is an individual characteristic of the patient. For example, in some patients, in the process of multiple examinations, the scatter in the values of electrical conductivity ranged from 0.1 * Icp to 3.1 * Icp. Consequently, for this patient, the width of the permissible ShDP corridor will be 3.1-0.1 = 3.0.

Next, individual boundaries of the normal range for each patient are determined depending on the given sensitivity of the diagnostic test and the width of the normal range of conductivity values.

Diagnostic sensitivity is understood to mean the proportion of patients identified by this diagnosis from the total number of patients with this disease. For example, the diagnosis revealed 8 patients with this disease. It is known that in this sample there are 10 patients with this disease. Therefore, the diagnostic sensitivity is Chv = 8/10 or 80%.

For example, the necessary diagnostic sensitivity is set equal to 75%, and the values of the boundaries of the individual normal range are calculated. To do this, calculate the intermediate coefficients for the lower and upper boundaries, respectively:

Kn = 1- (1-Chv) * Shd / 2,1 = 1- (1-0,75) * 4,0 / 2,1 = 0,524

Qu = 1 + (1-Kn) * 1.1 = 1 + 0.476 * 1.1 = 1.524

Next, the boundaries themselves are calculated at the value of the correction interval Δn = 0

H1 = Kn * Icp = 0.524 * Icp

B1 = Sq * Icp = 1.524 * Icp

Thus, according to the presented methodology, it is possible analytically taking into account the sensitivity of FG and the permissible spread of electrodermatometry values - the width of the corridor Шд in relative units (reduced to the average value of electrodermatometry, to calculate the corridor limits of the norm individually for each patient. In the absence of retrospective data on a particular patient, the corridor width is acceptable values with a confidence of 98% can be taken equal to 4.5.

The calculations are based on the following.

If the corridor of the norm has zero width (i.e. Н1 = В1), then the results of all examinations of patients will be outside the norm, i.e. all patients will be identified as patients and Chv = 1.

If H1 = 0, and B1 = ∞, then all the survey results will be within the normal range for each of the n meridians, because all will be identified as healthy and Chv = 0.

The norm corridor has asymmetry relative to the average value, if the width of the norm corridor part from H1 to I cf is taken as 1, then the width of the norm corridor part from Cp to B1 is 1.1 (the total width of the norm corridor in this case is 2.1 relative units) .

The real mean of the values for different meridians differs by almost 60%.

To obtain a real middle for each of the n meridians, the correction interval Δn is added to the value of I cf. It is important to understand that the segment Δn can be both positive and negative.

At the initial stage, until statistics are accumulated, it is assumed that Δn = 0. In the future, the Δn value is specified as evidence of clinical material is accumulated.

Next, determine the specificity of the diagnosis. By the specificity of the Sspets diagnosis, we understand the proportion of patients identified by this diagnosis in whom this disease was not detected by classical methods, out of the total number of such patients.

For example, diagnostics revealed that in 65 patients this disease is absent. It is known that in this sample there are 100 patients for whom the presence of this disease has not been established by classical methods. Hence

Special = 65/100 or 65%.

The specificity is determined based on the static data for the diagnosis of Nakatani and the empirical formula:

Specialist = (1-Chv ² ) ^1/6

In recent years, based on statistical data, a set of diagnostic algorithms for various diseases has been formulated. In these algorithms, the simultaneous exit of a number of meridians beyond the limits of normal corridors (into hypo- or hyperfunction) is a clear sign of the presence of a disease.

Using the above method for determining the individual boundaries of the norm corridor, it is possible to determine the analytically exact boundaries of the segments of falling of the given values into the hypo- or hyperfunction:

Hypofunction segment from 0 to H1

Segment of hyperfunction from B1 to 4.5

Example 1

In the example, the total sample consisting of 75 patients with psoriasis and 9984 people in whom psoriasis is not detected is indicated. A total of 10059 patients. For all patients with psoriasis, Шд = 2.1, therefore, Кн = Чв, Кв = 1 + (1-Чв) * 1.1.

For various diagnostic sensitivities, the following calculated values are obtained, which are summarized in table 2.

in which each pair of Sensitivity and Specificity are associated with the upper (B1) and lower (HI) boundaries of the normal corridors. These boundaries are calculated in advance based on the expressions given in the description of the invention, namely:

Kn = 1- (1-Chv) * Shch / 2,1 = 1- (1-0,75) * 4,0 / 2,1 = 0,524

Qu = 1 + (1-Kn) * 1.1 = 1 + 0.476 * 1.1 = 1.524

H1 = Kn * Icp = 0.524 * Icp

B1 = Sq * Icp = 1.524 * Icp

where Icp = 1 (in reduced units, i.e., in values divided by Icp)

Therefore, the doctor does not need to consider the boundaries of HI and B1, it is enough for him to set the sensitivity of Chv, and he immediately on the basis of table. 2 will receive the desired boundaries of the normal range.

Sensitivity (Chv) is set by the doctor. Depending on the tasks facing the doctor, whether it is an initial examination, medical examination or re-examination of the same patient, the doctor is given the sensitivity indicator, which, based on his experience, knowledge and the specific situation, will allow him to most optimally assess the patient's condition. For example, during the initial examination, the sensitivity is set at the level of 70-75%, so as not to deal with an excess of false patients. During repeated examinations, the sensitivity is increased to the level of 85-90% in order to more accurately monitor both the initial analysis and the patient observation process. When examining children, the sensitivity is selected maximum to 95%.

In a real sample, with a variation in the H1 boundary of the up / down indicator within the range of 0.96 from 0.69, the following data were obtained, which are summarized in Table 3. The data indicate that the difference between the calculated and real values does not exceed 5%.

Example 2. Patient P was examined, the data are summarized in table 4.

Using the collected data and the presented methodology, we can conclude that the studied patient, the data for which are summarized in table 4, with a sensitivity of at least 96% and specificity of at least 66%, is sick with psoriasis, since he has an up / down rate of 0.9.

The proposed method has the following advantages over existing today:

- provides the ability to analytically calculate the desired boundaries of the normal range (H1 and B1) based on a given diagnostic sensitivity,

- these boundaries are made individual for each specific patient, for this they accumulate the necessary statistical data on the measurements. These statistics allow you to determine the individual value of the SHDP for a given patient. Before the accumulation of static data, it is possible for all patients to use the obtained average value of Shd equal to 4.5.

Claims (1)

A method of monitoring the functional state of the patient’s body, including:
- measurement of electrical conductivity of 24 representative points of 12 symmetric meridians, determination of the arithmetic mean of these measurements with the establishment of a corridor of acceptable values for a given patient, based on the results of comparison with which the obtained values of indicators judge the functional state of the patient’s body, using indicators: the ratio of the sum of the values of electrical conductivity of Indian points meridians to the sum of the conductivity points of the Yang meridians, the ratio of the sum of the conductivity values and points on the hands to the sum of the points values of the electrical conductivity on the legs, the ratio of conductivity values of points measured on the left side of the body, to the sum of the values of the electrical conductivity of points measured on the right side of the body,
characterized in that
- the measurement of electrical conductivity in a patient is carried out at voltages of 5V, and / or 9V, and / or 12V,
and when using the patient data obtained during measurements at a voltage of 9 V, the measured values of the electrical conductivity of said representative points are recalculated by the formula:
I new = 9 / (29 / I measurement-0.1) * Coeff. (I)
when using patient data obtained during measurements at a voltage of 12 V, the measured values of the electrical conductivity of said representative points are recalculated by the formula:
I new = 12 / (29 / I meas-0.1) * Coeff. (Ii)
when using data obtained during measurements at a voltage of 5V:
I new = 1 measurement * Coeff, (III)
where in (I), (II) and (III), respectively:
I new - recalculated value of electrical conductivity,
I measured - the measured value of electrical conductivity,
Coeff - the value of the correction coefficient, taking into account the heterogeneity of conductivity along the meridians, in accordance with table 1, presented in the description,
further recalculated values are translated into the given values by the formula:
I lead = I new / I Wed,
Where:
I cited is the reduced value of electrical conductivity,
I new - recalculated without reduction the value of electrical conductivity,
I cf - the arithmetic mean of all 24 measurements taken,
then, the boundaries of the individual norm corridor for a given patient are determined depending on the given sensitivity of the diagnostic diagnostics and the width of the corridor of acceptable values of the conductivity conductivity, the conductivity is the variation in the conductivity values measured in this patient, and the sensitivity of the diagnostics is chosen depending on the available sample of patients with given disease
and the values of the boundaries of the individual normal range for this patient are determined as follows:
- first, intermediate coefficients for the lower Кн and upper Кв corridor boundaries are calculated respectively:
Kn = 1- (1-Chv) * Shdp / 2,1,
Qu = 1 + (1-Kn) * 1.1;
- and the actual lower H and upper B boundaries of the individual normal range are calculated:
H = Kn * I cf.
B = Kv * I avg;
- a comparison is made of I cited with the obtained boundaries of the individual normal range.