RU2194490C1 - Method and device for evaluating functional state of an organism - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: method involves measuring biologically active points characteristics on auricle surface in known combinations during not longer than 2 s. 50 to 100 characteristic values are saved during this period. The collected data are used for determining energetic state of organism systems functionally bound to the biologically active point combinations and integrated characteristic of energetic state of the organism as a whole is determined. Pathologic deviations level is determined next to it for each organism system recording normal state, moderate disorder and severe disorder cases. Predominant deviations of systems level are also determined and functional state of the organism as a whole is determined. Biologically active points parameters are measured by means of device having probe provided with active and indifferent electrode coaxially mounted on the working end. The electrode are separated with insulation member and form measurement unit connected to data processing and control unit bus via preliminary amplifier, switchboard, full instrumental amplifier and analog-to-digital converter. Synchronization circuit which input is connected to quartz oscillator unit output is connected to the analog-to-digital converter. EFFECT: high accuracy of diagnosis and functional state evaluation. 10 cl, 3 dwg

Description

 The invention relates to medicine, in particular to assessing the functional state of the body according to the characteristics of biologically active points (BAP) of the auricle (UR), and can be used in diagnosing diseases and choosing a treatment method using traditional medicine methods.

 The human body as a biological object is an organized complex of functionally connected organs and systems, the interaction of which ensures vital activity in constantly changing, and often extreme, conditions. At the same time, the human body is a rich information system consisting of many sensors and receivers of information. In addition, each functional system of a living organism includes control, executive and controlling elements with a feedback system. It is natural to assume that the autonomous vital activity of the body is closely related to the environment, since biological systems are open, that is, between them and the environment there is a continuous exchange of matter, energy and information.

 It is known that one of the regulators of various physiological functions of the body is the surface of the skin. Irritation of its various reflexogenic zones can relieve pain and cramps, increase or decrease metabolic processes, accelerate or slow down the rhythm of cardiac activity, etc. The body reaction is different depending on the site of irritation, which is due to many factors, in particular the specificity of the nervous system, which adapts organism to the conditions of a real situation. It is skin zones of various physiological activity that are used to diagnose and treat many diseases with reflexology (RT) methods.

 The surface of the skin of a living organism contains a significant number of reflexogenic zones that carry the finest information about all processes in the internal organs and their condition and receive information from the environment that allows the body to adequately respond to changing external conditions. Such reflexogenic zones are commonly called the “biologically active zone” or “biologically active point”. Their unique feature is the ability to simultaneously combine the functions of a multidimensional information sensor and a receiver of signals of various physical nature. The variability of the signals at the input and output of the BAT is the rationale for the creation of expert systems in reflexology, including diagnostic methods, therapeutic effects and prevention.

Auricular diagnosis and therapy are an integral part of RT. It is well known that due to the close ties of auricular afferents (V, VII, IX, X pairs of cranial nerves) and C _II- C _III nerves of the cervical plexus with other afferent projections of the brain and their wide overlap at the stem and thalamo-cortical levels, auricular reflexes can spread to any visceral-endocrine, sensorimotor and psychoemotional reactions of the body, contributing to their normalization. It is also known that in the "projection" exteroceptive zones of the urinary system, when the function of the corresponding organs is impaired, strictly local changes in the adaptive-trophic and pain nature can occur, which are of significant signaling value.

 The known method of multifactorial auricular diagnosis (MFAD) [1], considered as a prototype, which provides a comprehensive analysis of three indicators: electrical conductivity, pain sensitivity and morphological manifestations in the auricular points of the auricle (assessment of three factors). To assess the electrical conductivity, an alternating current of low intensity is used, which makes it possible to measure the impedance (total reactance) at the points of UR. When evaluating 130 indicators (right and left SD), the deviation of the measuring device’s arrow from the normal values of electrical conductivity is taken into account and the results are interpreted as a low, pronounced, and high probability of a disease.

 Assessment of pain sensitivity is carried out manually with a probe with a pressure sensor, the results of 130 indicators are recorded on the patient’s chart and are interpreted as “painless point” and “painful point”. Assessment of morphological changes in SD is carried out visually. The morphological elements in the MFAP technique are described 5: spot, nodule, tubercle, vesicle, pust. Identified changes are recorded in the patient card.

 All 130 points are distributed across 11 systems (respiratory, cardiovascular system, digestive, musculoskeletal system, urinary, sexual, endocrine, immune, psycho-neurological status, ENT organs, eyesight), in each of which 3 are analyzed up to 11 points.

 After all indicators are found and described by three factors, a conclusion is made with subsequent verification and follow-up.

 The disadvantage of this method is that the initial value for determining the physiological limits of the norm is taken for all the same, without taking into account the fact that the resistance of the skin at the points of SD in different people is significantly different.

 The prototype method is quite time-consuming, given that it takes up to 15 s to measure one SD point, then it takes about 2 hours to complete a survey on three factors and enter the indicators into a map.

The disadvantage of this method is that for the measurement requires the observance of a large number of restrictions, for example: humidity 70-80%, t _nom 20-22 ^o C, clothing made from natural fabrics, the absence of devices and means generating electromagnetic fields, and many others., which is practically impossible to implement.

 The disadvantages of the method can also include the use of a large number of points (130), some of which (15, 16, 51) are difficult to access for visual and algesimetric studies or are of no value for diagnosis (24a, 24b, 10), or are almost never used in RT.

 A significant drawback of the method is that the measurement of electric skin resistance and the determination of pain sensitivity are carried out sequentially at the same points, which significantly distorts the indicators, and in fact one of these diagnostic methods is a medical procedure (acupressure, percutaneous electropuncture), preceding the subsequent diagnosis .

 The diagnosis of any method of reflexology is based on the principle of instrumental assessment of the state of biologically active points (BAT). Theoretically, each BAP differs from the surrounding skin by a whole complex of physical quantities (for example, resistance, conductivity, electromagnetic field, temperature, oxygen absorption activity, etc.), but practically only one indicator is used - the resistance value.

 Closest to the claimed is a device [2], containing a precision current source connected to the active electrode and through a measured resistance (area of the skin) with a passive electrode. A passive electrode is a gilded metal plate placed on the surface of the skin of the body, most often on the back of the palm. The active electrode is made according to the standard scheme adopted in most industrially produced devices [3]: a cylindrical conductor placed in the body of their insulating material.

 The active electrode is connected to the input of the amplifier, the output of which is connected to the inputs of a comparator made by a two-threshold and controlled, the other two inputs of which are connected to the outputs of the high and low levels of the reference voltage source. The outputs of the comparator are connected to the inputs of the control unit, the outputs of which are connected respectively with the inputs - outputs of the storage device through the information processing unit.

 Before measurement, preparation of the examined area in each BAP is done by wetting the skin with alcohol to degrease and cleanse it. The active electrode is moved over the skin in the area of the desired BAP until a light appears and the sound signal stops accompanying the point search process. When the active electrode enters the BAP, the measurement circuit closes, because the input impedance of the amplifier is calculated taking into account the maximum value in the BAP (350-400 kOhm). The steady-state voltage value in the measured BAT through the control unit enters the information processing unit, and the average value of the measured value, taking into account the error of the measuring device, is stored. A programmable voltage value is supplied to the control input of the comparator, which is generated by the control unit according to a predetermined algorithm, for example, by the method of successive approximations. The comparator compares the voltage values supplied to its inputs, and generates a signal at the output equal to the measured voltage.

 When working with the device does not take into account the nature of the transients that occur in the zone "BAT - active electrode". As the studies show, transients are clearly non-linear and reflect the pathology of the state of a specific BAT, i.e. their character is to a greater extent a consequence of physiological characteristics and, to a lesser extent, a consequence of the technical characteristics of the measuring device. Therefore, the option of fixing the result after a certain time interval (the so-called delay time) is not optimal and often leads to a significant error in the result, especially in the case when the desired value is determined as the arithmetic mean of N values.

 It should also be noted that in this device the measurement result significantly depends on the degree of pressure of the active electrode on the surface of the skin. It is not possible to ensure the constancy of this factor with the used structural solution of the electrodes, and the magnitude of the error of the measurement result is so large that it can be argued about the extremely low repeatability of the result. And finally, the values of the maximum BAP value used in the calculations (in this case, 350-400 kOhm) are often not true, since this value is a consequence not only of pathological processes in the body, but also a consequence of the psychoemotional state of a particular patient, time of day, climatic factors etc.), and therefore, has a rather wider range of possible, but not predicted values. Ignoring this factor inevitably leads to a distortion of the result of assessing the state of the organism as a whole, especially in the case when the general condition is estimated as a certain statistical quantity (coefficient of variation) that does not clearly reflect the essence of the physiological state (this is a simplified solution to an extremely complex problem).

 The essence of the invention lies in the fact that the assessment of the functional state of the body is carried out by registering data on the patient and objective indicators of his condition, measuring the characteristics of BAP located on the surface of the auricle in certain combinations thereof, each of which is functionally associated with one or more body systems.

 As systems, the totality of which with a sufficient degree of reliability reflects the state of a particular organism as a whole, the central nervous and autonomic systems and the mental sphere are considered; neuro-endocrine and immune systems; the cardiovascular system; bronchopulmonary system, skin and hair; ENT - organs; gastrointestinal tract; hepatobiliary system and organs of vision; genitourinary system; musculoskeletal system. The state of each of the systems is determined by the set of BAT, which have the maximum information content and accessibility for instrumental research.

 The BAT characteristic is measured for no more than 2 s and from 50 to 100 of their values are recorded; then, according to a certain algorithm, a single value of the BAT state is calculated, which is taken as true. The integrated characteristic of specific BAP combinations characterizes the level of the energy state of a particular system, and the aggregate value for all measured systems is the level of the energy state of the organism as a whole.

 The difference between the level of the state of the organism as a whole and the level of the state of a certain system characterizes the value of the pathological deviation of the system: the normal state of the system is characterized by a deviation of up to 10%, a moderate violation is 11% -40%, and a pronounced violation is a deviation above 40%. The semantic nature of the deviation is established in the form of a specific set of symptom complexes using specially designed tables; the set of symptom complexes is not only a consequence of the pathology of a particular system, but also takes into account the quantitative indicators of BAT aggregates related to a particular system.

 The syndrome complex describing the functional state of the body is determined by measuring and analyzing additional BAT, and the number and composition of such BAT is determined by special tables. The final decision on the eligibility of a particular proposed decision is made by the doctor, taking into account the totality of the accumulated information.

 Processing of measurement results, calculation of system parameters and development of control solutions in a form convenient for visual perception is carried out by a personal computer (IBM PC / AT).

 Figure 1 presents a General view (constructive solution) of the probe.

 In FIG. 2 is a structural diagram of a device including instrumental elements of the method that carry out pre-processing and signal generation.

 Figure 3 shows a typical characteristic of the measurement result of BAP.

 The proposed method for assessing the state of the body and the device for its implementation logically links the main aspects of medical activity: history - diagnosis of the disease - diagnosis - treatment process - monitoring the state of the body. The functional completeness of the development predetermines an effective solution to the listed (and a number of other) problems, and the principles laid down in the basis of its practical implementation provide a fairly convenient exchange of information between the doctor and the patient. In addition, the composition of the output document is fully consistent with the canons adopted in modern medical practice, which allows it to be considered legally complete.

 The proposed method is carried out using a device for assessing the functional state of the body, containing the active and indifferent electrodes (Fig. 1), separated by an insulating material and structurally made in the form of a single block placed at the end of the probe. Between the pre-amplifier (Fig. 2) and the information processing and control unit, a signal switch, a complete instrument amplifier and an analog-to-digital converter (ADC) are installed in series, the operation cycles of which are set by the synchronization circuit and the counter-timer. Stable operation of all units of the device is ensured by the presence of a crystal oscillator.

 To neutralize the main "destabilizing" factor when measuring the state of the BAT - the dependence of the result on the degree of pressure on the electrode - the design of the measuring element of the device - probe 7 (figure 1). Active 1 and indifferent 2 electrodes separated by insulator 3 are structurally combined in one block and are located at the end of the probe; in this case, during the measurement, the degree of pressure is perceived equally by both electrodes; therefore, the relative magnitude of their state (potential difference) practically remains unchanged. In addition, it is such a design of the electrodes that “shields” the BAP zone from the influence of external factors (for example, electromagnetic and X-ray radiation), and the rather short measurement time of the set of all points — no more than 5–8 min — makes it possible not to take into account errors caused by changes in climatic conditions indoors (temperature, humidity, pressure, convection). The ability not to take into account a number of "destabilizing" factors not only simplifies the measurement process, but also significantly increases the reliability and repeatability of the result.

 The electrical circuit arising in the "indifferent electrode - BAP - active electrode" section is characterized by a number of parameters, the most important of which is the current value, which indirectly reflects the physiological state of the BAT. However, the BAP is clearly a nonlinear element in the circuit, so one should assume the presence of reactance in the general case, and evaluate the measurement itself as a result with the presence of transients. An approximate typical characteristic of the measurement result of a specific BAP is presented in Fig. 3 (in the coordinates voltage – time). The duration of the period and the angular coefficients of each zone are not constant values, which indicates the physiological nature of the changes in the BAP. The greatest constancy of values is possessed only by a certain part of the characteristic (zone of a stable state); the average value of this interval is taken as the true value of the BAT state.

 In the case 4 of the measuring element of the device (probe), an additional BAT 5 zone indicator (LED) and an actuating element 6 (microswitch) are additionally placed, when the button is pressed, the signal is directly transmitted to the information processing and control unit located in the computer case. Such a constructive solution provides maximum convenience during the measurement.

The voltage between the electrodes applied to the surface of the skin (an area of not more than 3.5 mm ² ) is 1.1 V, and the current flowing through a specific area of the skin varies from 1.4 to 11.6 μA. The power supply device of the measuring device circuit is made in the form of a separate unit (battery), not galvanically connected to the power circuits of all other blocks. The amplifier of the output signal of the BAT state is a preamplifier 8, which does not contain inductive elements, which eliminates the possibility of extracurrents and the appearance of the effect of "breakdown" of the skin. The combination of these factors ensures absolute safety and completely eliminates the "pain" during the measurement.

 The operation of the measuring device is as follows. Electrodes 1, 2 "feel" the surface of the skin of the auricle in the proposed area of the BAP; at the same time, the input of the preamplifier 8 constantly receives a paraphase signal and the voltage difference between the electrodes 1, 2 is measured and then amplified. Structurally, the unit is a micropower precision operational amplifier with a sufficiently large gain, which is determined by the need to transmit the signal through sufficiently long connecting wires .

The BAT search method on the surface of the skin is based on the analysis of the potential value of each electrode. Of all the possible variants of relative positioning, in only one case, when the active 1 electrode is precisely located above the BAP projection, the potential value at the non-inverting input of the pre-amplifier 8 will be greater than at the inverting one by a certain amount (by the value of / + U _pit - 0.7 V / and more).

 When you press the button of the actuator 6 (microswitch), the signal about the state of the BAT through the signal switch 9 is fed to the input of a full instrumentation amplifier 10, which amplifies and generates a signal to the level of parameters that ensure stable operation of subsequent units of the device; An important property of the amplifier is the presence of circuits for the complete suppression of common mode noise and circuits that establish the most optimal signal-to-noise ratio.

 Next, the signal is fed to the input of an analog-to-digital converter (ADC) 11 of successive approximation with a conversion time of 1.6 μs. Sampling time 400 ns - the minimum necessary interval for sampling the signal with the necessary accuracy at maximum speeds - 2 μs. An analog signal is converted to digital with an accuracy of 1.22 mV / discharge.

The time required for signal conversion and analysis of the result is achieved by discrete organization of the measurement device using the counter-timer 13: the signal is read every 20 ms and 50 to 100 result values are recorded in the device memory. The coordinated operation of all the circuits included in the device is achieved by the synchronization circuit 14, I / O buses connected to the ADC 11. The clock frequency of the operation of both devices is set by a highly stable crystal oscillator with an accuracy of no worse than 10 ^-6 .

 The exchange of information between the input device blocks and the PC is carried out by the group of devices included in the information processing and control unit 15: input-output interface - address decoder - direct memory access circuit - interrupt processing circuit. Their functional purpose fully complies with the requirements for the implementation of the exchange protocol for PCs such as IBM PC / AT.

 The result of the synchronous action of all units of the device is the recording in the PC memory of a digital signal, which is the equivalent of the state of a specific BAT (or area of the skin). Further information processing is carried out directly by means of a personal computer with the help of a specially developed set of programs.

 The digital ports of the information processing and control unit 15 receive and send control commands resulting from the program. When a specific BAT is localized, a signal in the form of a voltage of +5 V is supplied to LED 5 located in the probe body, and if necessary, record the result (by pressing a button on the probe body) a similar signal is sent directly to the interrupt processing circuit. The voltage levels of these signals fully correspond to those in the PC, so no additional matching devices are required.

 The final stage of the work is the search for a “zone of stable state” (Fig. 3) and calculation of the overall result: each subsequent value of the result is compared with the previous one, and if 10-20 values are distinguished in a row, differing from each other by no more than 12% (value statistical error), then this series of values is taken as true; their averaged value is ultimately interpreted as the equivalent of the state of a specific BAP.

 The presence of a variable value of the read values (50-100) is explained by the fact that the presence of a "zone of a stable state" is a consequence of the physiological state of the BAT and, therefore, does not depend on the time factor. Therefore, the principle of sequential analysis of values was used: as soon as the "zone of stable state" is determined, the reading of information stops, which in the general case can correspond to a time interval from 1 to 2 s. The possible appearance of artifacts during measurement is limited to an interval of 100 values (which exactly corresponds to 2 s), since each process must have finite time ranges. If at the maximum number of values the “stable state zone” is not determined, an error signal will be voiced and a suggestion to repeat the measurements. In case of repeated unsuccessful measurement, the result is not recorded and further measurements of this BAP are not carried out, which avoids obtaining a clearly distorted result due to the possibility of the appearance of the effect of the “medical procedure” (acupressure, percutaneous electropuncture). The true state of the BAP in this case is calculated by the methods of mathematical statistics, taking into account the values of duplicate or functionally related BAP.

 Reflexotherapy refers to indirect methods of assessing the state of the body (as well as most other methods used in medicine), therefore, the establishment of quantitative and qualitative characteristics of the relationship between the values of the BAT group and the functional state of the body is the main and most difficult task.

 The human body is an organized complex of functionally connected cells, tissues, organs and systems. Therefore, from the point of view of computer science, each of these "levels of organization" has a certain amount and quality of information. Moreover, the dependence is quite simple: the "lower" the level of organization, the greater the amount of information it possesses (the amount of initial information in the analysis of the state of cells and tissues is an "astronomical value" and cannot be processed and estimated by modern means of computer technology). By its functional significance, any BAT is an indirect description of the state of the body at the level of organs and systems, and not at the level of cells and tissues. Moreover, the quantitative value of BAT is clearly an integrated quantity, i.e. It contains a set of information not only about a specific organ or system of the body, but also information about the physiological state of "adjacent" organs, the degree of their relationship, mutual influence in the presence of pathological processes, etc. Therefore, when developing an algorithm of a method (technique), one should proceed not from assessing the quantitative values of individual indicators [1, 2], but from the physiological foundations of the body.

 The method is implemented as a three-level system.

 1st level. Assessment of the general condition of the body, presented as a set of individual functional systems, based on instrumental measurements of BAT located on the surface of the auricle.

To implement the algorithm, a number of methods have been specially developed that regulate certain relationships between all elements of the method. The organism is represented as the combined functioning of 9 separate systems; in a number of systems, the relationship is due to compliance with oriental principles:
central nervous and autonomic systems.

mental sphere
neuro-endocrine and immune systems
the cardiovascular system
bronchopulmonary system
skin and hair
ENT organs
gastrointestinal tract
hepatobiliary system
organs of vision
genitourinary system
musculoskeletal system
Such a number of systems is the most optimal, taking into account not only the acceptable reliability of the final result, but also taking into account the possibilities of reflexology as a method of diagnosis and therapy.

 The state of each individual system is characterized by possible changes, the quantitative value of which is indirectly determined by the cumulative state of certain BAT. An individual list of such BATs has been developed for each of the systems, and their number is rigidly fixed, which provides certain conveniences in the practical use of the method.

 The number of BAT measured in each system is calculated on the basis of a number of fundamental considerations, the most important of which is to ensure the highest possible level of reliability of the result both in the case of possible erroneous actions and in the presence of artifacts. The desired result is calculated as the arithmetic mean of the values of several BAPs and is considered reliable only if at least 60% of the total number of all measured points of a particular system have deviations that differ from each other by no more than 20%.

 2nd level. Assessment of the degree of "pathology" of each of the functional systems based on a common (for a specific organism) integrated attribute.

 The method for determining the degree of deviation of a particular system (pathology of changes in the system) is based on the principles of representing the body as a single information system: regardless of the type of possible changes, any information appears only if its characteristic (instrumental, visual, etc.) differs from a certain level or species. Since the principle of instrumental assessment of the state of BAT is based, it is quite natural to take the value of the arithmetic mean of all measured points as the initial reference level, which will indirectly reflect the level of the energy state of the body at a certain point in time. The deviation of the quantitative value of a particular system from this level reflects the degree of pathology of this system. It should be noted that the quantitative value of the level of the energy state of the body does not necessarily characterize the “normal” (there are no pronounced changes) state; it can be a consequence of quite serious changes. Therefore, any comparison with this value does not establish the fact of a possible deviation from the "normal" state, but the fact of a deviation from the current state, that is, the fact of the presence of a "dominant" deviation. Such a construction of the logic of the method in many ways allows you to accurately determine the place of the cause (specific system) of the existing pathology, and not the place of the investigation, which helps to avoid a possible medical error in some cases.

 It is this principle of determining the “normal” state that is an essential distinguishing feature of the proposed method from all known ones, for example, [1, 2, 3], since the reference level is taken not as some fixed value of the “normal” state, but as a result of the physiological the state of the body at a particular point in time. Possible pathological changes in the body, changes in the psycho-emotional state, time of day, climatic conditions, measurement conditions, etc., of course, affect the quantitative characteristics of this quantity, but the result of the deviation (relative value) of any system from the "normal" state it is always the result of only one reason - pathological changes in the body.

 The quantitative value of the deviation of each of the systems is fixed in the form of a group attribute, which establishes the type of possible pathological changes. Quite convenient and informative is the principle of describing the state of each of the functional systems, in which all systems whose quantitative value does not differ by more than 10% from the value of the "normal" state are considered to have no deviations. Systems whose quantitative value differs from the "normal" state by 11% -40% are considered to have "moderate violations", and systems with a difference of more than 40% are interpreted as systems with "pronounced violations".

 The problem of choosing systems (one or two) having the maximum level of pathological deviation (the so-called "dominant systems) is solved by analyzing quantitative characteristics taking into account complaints of a particular patient and instrumental assessment data. A group symptom of a pathological change in the system describes fairly specific facts , allowing to judge not only about the degree of manifestation, but also about the nature of the functional disorder, for example: "Pronounced violations of the central mechanisms of mental adaptation with signs of neuro disorder ", which allows us to ultimately create a methodology for determining the nature of a particular syndrome complex.

 3rd level. Determination of the main and concomitant symptoms (symptom complexes) inherent in the patient at a real time.

 The method is based on detailing data on a group feature of pathological changes in the dominant system (one or two). For this purpose, a number of information materials have been specially developed that establish, with a certain degree of certainty, a direct relationship between a group trait and a certain set of syndrome complexes. The principle of multivariate analysis is practically used, the constituent elements of which are the entire totality of the information received and available, up to taking into account the history data.

 In some cases, to clarify the nature of a particular disease, an instrumental assessment (measurement) of additional BAT is required. The calculation of these points and the measurement path is carried out automatically, but in any case, these points are components of the total number of BAT used in this method.

 Given the fact that the methods used in the practical implementation of the method allow us to assess the general condition of the body and individual functional systems, the definition and description of specific syndrome complexes is advisory. Clarification of the type of disease is carried out by specific medical specialists using appropriate equipment and methods.

 The method implemented using computer graphics is as follows.

 At the initial stage, the minimum patient data is recorded: name, gender, gender, age and profession; gender is taken into account when determining the dominant syndrome (mainly with diseases of the genitourinary system), and age - when prescribing a treatment method. Then the main complaints of the patient are entered, instrumental measurement of heart rate and AD is carried out. In practice, this is the only information that can be entered from the computer keyboard.

 Then proceed directly to measuring the state of the BAP. The number and composition of systems for measurement are selected by the doctor based on the nature of the situation and patient complaints. As a rule, during the initial examination, the state of all systems is assessed; with repeated examinations, it is possible to measure some of them, which allows us to establish the possible dynamics of changes in the body, which is a consequence of the use of various treatment methods.

 In the process of measurement on the computer screen displays all the necessary information about the measured system, the topology of the location of specific BAT on the surface of the auricle, the measurement sequence and the result of the action. The measurement process is accompanied by some additional information that does not distract the attention of the doctor, but is useful if you need to make a decision in case of an unusual situation. The total measurement time of all points of the systems (42 points) is on average 5-8 minutes.

 All further actions associated with the implementation of the method occur outside the field of view of the doctor and require only the adoption of an appropriate decision. The level of the energy state of the organism is calculated sequentially, the deviation of each of the measured systems is determined, and a group attribute of a description of a possible pathological deviation is formed. The resulting information in the form of a graphical representation of the state of each of the systems, a description of the type of deviation, previously recorded instrumental data and the main complaints of the patient are displayed on a computer screen. Based on all this information, the doctor makes an appropriate decision.

 Further, the selected solution is detailed in order to determine the dominant syndrom complex (one or two), for which the composition and quantity of BAT are necessary to preliminarily calculate to clarify the nature of the information. The determination of the signs of the disease is solely the prerogative of the doctor and is carried out by him on the basis of the totality of all the information (including the medical history), sequentially accumulated at all stages of the practical implementation of the algorithm.

 At the final stage, it is possible to prescribe a course of treatment using one or more traditional medicine methods: acupuncture, herbal medicine, homeopathy, allopathic therapy, the composition of the formulation of which for all diagnosed conditions is included in the information directory of the method. The total diagnostic time when using this method is not more than 15-20 minutes

 Example 1

 Patient T., age 52 years old, economist AD 135/90 mm Hg, heart rate 82 beats. / min

 Complaints of sharp pains in the ankle and right hip joints, aggravated by walking, flatulence, constipation, occasionally skin itching, fatigue, superficial sleep, decreased mood background.

 A computer study revealed severe disorders in the hepatobiliary and gastrointestinal systems, moderate disorders of the musculoskeletal system and central nervous system.

 In the process of testing additional points, as well as analyzing the patient’s complaints, a conclusion was made about “Violation of the state of the hepatobiliary system with the presence of possible calculi in the gallbladder”, “Violation of the function of the small and large intestine with signs of a destructive-inflammatory process”, “Violation of the central mechanisms of psycho Vegetative, neuroendocrine and vascular regulation "and" Violation of the function of the musculo-articular and bone-ligamentous apparatus with a predominance of destructive and inflammatory changes in the ankle and hip wound joints. "

 An examination by a gastroenterologist, neurologist, followed by ultrasound, REG, EEG, radiography of the hip and ankle joints is recommended.

 The method recommends a course of reflexology and homeopathy. Therapist's opinion (after ultrasound): cholelithiasis, chronic enterocolitis. Surgical intervention recommended.

 Conclusion of a neurologist (after REG, EEG): discirculatory encephalopathy. Recommended course of nootropil, vitamin therapy, homeopathy.

 An X-ray examination revealed destructive changes in both the hip and ankle joints.

 After resection of the gallbladder with removal of stones (filled 7/8 of the gallbladder) of size, the patient was observed by a homeopath, periodically treated with drugs "Edas-113, 111, 119, 402". Recommended nutrition corresponding to the blood group (A).

 Follow-up after 8 months: satisfactory condition, periodically observed by a gastroenterologist and neurologist. 2 courses of reflexology were conducted, aimed at normalizing the psycho-emotional state and relieving pain associated with joint disease.

 Example 2. Patient K., 35 years old, air traffic controller, AD 110/80 mm Hg, heart rate 68 beats / min.

 Complaints of constant aching pain in the lower thoracic spine for 1.5 years. Pain intensifies after psycho-emotional stress and heavy physical exertion. Increased irritability, fatigue, superficial sleep, and reduced ability to work are also noted.

 A computer study revealed pronounced changes in the gastrointestinal tract and moderate disorders in the neuroendocrine, immune systems. In other systems, no changes were detected at the time of the examination.

 In the process of testing additional points, as well as analyzing the patient’s complaints, a conclusion was made about "Violation of the gastrointestinal function with signs of a destructive and inflammatory process in the duodenum (expressed) and" Violation of the function of endocrine glands with signs of secondary immunodeficiency (moderate). Consultation of a gastroenterologist and immunologist is recommended.

 A gastroscopic study revealed an ulcer in the area of the duodenum in the acute stage. The method recommends a complex of RT, homeopathy, herbal medicine, nutrition, which are selected individually.

 In a subsequent patient, preventive courses of RT and homeopathy were carried out, aimed at preventing exacerbation of duodenal ulcer and increasing immunity.

Sources of information
1. Meiserov E.E., Koroleva M.V. Auricular diagnosis in clinical reflexology. - Moscow. 2000. Methodical recommendations; 31 sec (prototype method)
2. RU 2029493, 1995 (prototype device)
3. Krivokon V.I., Titov VB Biocorrection. Devices and systems. Moscow. 1995.

Claims (10)

 1. A method for assessing the functional state of the body, including recording data about the patient and objective indicators of his condition, measuring the characteristics of biologically active points located on the surface of the auricle in certain combinations thereof, each of which is functionally associated with one or more body systems, analysis of the integrated characteristic the energy level of the state of the organism as a whole, characterized in that the characteristic of each biologically active point is measured over a period of e 2 s and at the same time fix from 50 to 100 of their values, determine the level of the energy state of at least one of the systems from them, determine the integrated characteristic of the energy level of the state of the organism as a whole, after which the level of pathological deviations of each of the body systems is determined by the magnitude of the deviation of the level of their energy state from the integrated characteristics of the energy level of the state of the organism, while the normal state is characterized by a deviation of up to 10%, moderate changes - 11-40 % and expressed changes with a deviation above 40%, measure the characteristics and analyze them for additional biologically active points to clarify the nature of pathological deviations, identify the prevailing deviation of the level of systems in the form of at least one syndrome complex and evaluate the functional state of the body.  2. The method according to PP. 1 and 2, characterized in that the central nervous and vegetative system and the mental sphere are considered as body systems; neuro-endocrine and immune systems; cardiovascular system; broncho-pulmonary system, skin and hair; ENT organs; gastrointestinal tract; hepatobiliary system and organs of vision; genitourinary system; musculoskeletal system.  3. The method according to any one of the preceding paragraphs, characterized in that the set of biologically active points (BAP) include points with maximum information content and accessibility for instrumental research.  4. The method according to PP. 1-3, characterized in that pre-determine the maximum number of measured biologically active points.  5. The method according to any one of the preceding paragraphs, characterized in that the integrated characteristic of the energy level of the state of the organism as a whole is determined by methods of mathematical statistics.  6. The method according to any one of the preceding paragraphs, characterized in that the determination and analysis of the energy level of the systems and the integrated characteristics of the energy level of the state of the organism is carried out programmatically, by computer, with the output of their results on the display screen in the form convenient for visual perception.  7. The method according to p. 6, characterized in that the evaluation results on the display screen additionally contain a forecast of the patient’s condition, recommended consultations and suggestions on methods of treating the disease.  8. A device for assessing the functional state of an organism, comprising a measuring unit including a precision direct current source connected to an active and indifferent electrodes connected to a pre-amplifier, an information processing and control unit and a light indicator, characterized in that the active and indifferent electrodes are installed coaxially , at the working end of the probe and are separated by an insulator, between the preamplifier and the information processing and control unit, comm Tatorey full scale amplifier, and an analog-digital converter, which further input-output circuit is connected to the synchronization input of which via a counter-timer connected to the output of the quartz oscillator.  9. The device according to claim 8, characterized in that the light indicator is installed on the probe body and is connected to the control and information processing unit via data buses.  10. The device according to paragraphs. 8 and 9, characterized in that a computer is used as the information processing and control unit.

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