RU2033785C1 - Method and device for determining characteristic parameters when diagnosing pregnancy and diseases of female genitals - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: characteristic parameters of measured temporal functions are determined for complete, active and resistive potentials at anode and cathode modes at specific parameters of effect onto biologically active points device has passive and active electrodes, switches, stabilized current source, buffer amplifier, pulse-width modulator, matching unit, solving unit, conversion unit which has galvanic decoupling, reference voltage unit, polarity commutation unit, control generator, interrupter and indicator. EFFECT: improved efficiency; improved reliability of examination. 2 cl, 2 cl, 3 dwg

Description

 The invention relates to medicine and medical equipment and can be used for electropunctural diagnosis of pregnancy and diseases of the female genital area.

 The known method, which is the closest in essence to the proposed one, is based on measuring the electrical parameters of the skin at acupuncture points when the object is stabilized by direct current of negative polarity with a force of 8 + 10% μA and recording time intervals from the moment the exposure begins, during which a transition the process of establishing skin polarization potentials, in this case, with the size of the interval until the end of a sharp change in potential within 7.30 s and in the presence of changes potential signs at the beginning of the interval diagnose pregnancy, with an interval value of 40.75 s diagnose a benign neoplasm with a slow growth, with an interval value of 75.95 s a benign neoplasm with a rapid growth, with an interval of more than 100. 105 s diagnose a malignant neoplasm, and with an interval of 30.40 s or in the presence of an extremum in the value of the potential, the inflammatory process is diagnosed (Auth. N 1158197, CL A 61 H 39/00, 1981).

 The disadvantage of this method is the relatively low diagnostic accuracy.

 The technical result of the method is to increase the accuracy of diagnosis.

 To this end, in a method based on measuring the electric potentials of biologically active points of a patient when exposed to a stabilized current, the effect is carried out by a pulsed current of positive and negative polarity with a stable amplitude, which correspond to the anode and cathode modes, respectively, while, as the measured potentials in both modes use the full, active and resistive potentials, according to the time and amplitude characteristics of which they will later judge the diagnosis.

 In addition, the required technical result is achieved by the entire newly introduced set of features, which are not found in the scientific and technical literature. Therefore, the proposal meets the requirement of inventive step.

 At the same time, the description provides detailed recommendations on the implementation of the operations of the method, and also presents the device with which it is implemented in clinical practice. Therefore, the proposal meets the requirement of industrial applicability.

 Also known is a device that is closest in technical essence to the proposed one, containing a voltage source, a search and pre-excitation circuit, an amplitude indicator, an active and passive electrodes, a polarity switching unit connected in series to a voltage source, a constant current source and a switching unit connected to an amplitude indicator, passive and active electrodes, a time indicator and a pre-excitation switching unit, while The pre-excitation switching unit is connected to the active and passive electrodes, the amplitude indicator, the polarity switching unit, and to the excitation circuit, and the time indicator is connected to a voltage source (Aut. St. N 1158197, class A 61 N 39/00, 1981).

 The disadvantage of this technical solution is the relatively low diagnostic safety.

 The required technical result is to increase the accuracy of diagnosis and to increase the safety of diagnosis.

 The required technical result is achieved by the fact that in a device containing passive and active electrodes, the input terminals of which are connected to the patient, a stabilized current source, an indicator, the first and second switches, as well as a series-connected reference voltage unit and a polarity switching unit, a series-connected buffer an amplifier whose input is connected to the output of a stabilized current source, a pulse-width modulator, a galvanic isolation unit, an interface unit, and a decider , a conversion unit with galvanic isolation, the reference and clock inputs of which are connected respectively to the reference and clock outputs of the interface unit, the clock output is connected to the clock input of a pulse-width modulator, and the potential output is connected to the input of the reference voltage block, the corresponding output of which is connected to the reference input a pulse-width modulator signal, a control generator and a chopper connected in series, the signal input of which is connected to the output of the polarity switching unit, and in the output is connected to the input of the reference voltage of the stabilized current source, while the output terminals of the passive and active electrodes are connected to the input terminals of the first switch, the output terminals of which are connected to the corresponding inputs of the stabilized current source, the output of the polarity switching unit and the input of the second switch, the indicator through the second switch connected to the output of the buffer amplifier.

 Analysis of the scientific and technical literature showed that prior to the filing date of the application, there were no devices with the indicated set of features. Consequently, the proposal meets the requirement of novelty.

 In addition, the required technical result is achieved by the entire newly introduced set of essential features, which are not found in the well-known literature. Therefore, the proposal meets the requirement of inventive step.

 Moreover, the device includes known elements and gives examples of the constructive implementation of newly introduced elements and all the necessary information for their implementation. Consequently, the proposal meets the requirement of industrial applicability.

 In FIG. 1 is an electrical block diagram of a device that implements the method; Figures 2 and 3 are timing diagrams explaining its operation.

 The device (Fig. 1) contains passive 1-1 and active 1-2 electrodes, the input terminals of which are connected to the patient 2, and the output terminals through the first switch 3 are connected to the corresponding inputs of the stabilized current source 4, the output of which is connected to the buffer amplifier in series 5, by a pulse-width modulator 6, a galvanic isolation unit 7, a conjugation unit 8, and a decision unit 9, the conversion unit 10 is connected in series with the galvanic isolation, the clock and reference inputs of which are connected to responsibly with the clock and potential inputs of the interface unit 8, the reference voltage unit 11 and the polarity switching unit 12, serially connected to the control generator 13 and the chopper 14, the signal input of which is connected to the output of the polarity switching unit 12, and the output is connected to the reference input of the stabilized current source 4 as well as series-connected switch 15, the input of which is connected to the output of the buffer amplifier 5, and indicator 16.

 The stabilized current source 4 can be made in the form of an operational amplifier (for example, on the KR140UD8 chip), in the feedback circuit of which a patient 2 is connected through passive and active electrodes. The galvanic isolation unit 7 can be made in the form of an optocoupler. The pairing unit 8 in a particular case can be made in the form of an eight-bit analog-to-digital converter with conversion of the pulse duration into an 8-bit binary code. A +12 V reference voltage can be supplied from the system backbone of the computer, which is used as a decision unit. The chopper 14 can be made in the form of a transistor switch, block 11 in the form of a stabilized voltage source of two polarities. The conversion unit 10 with galvanic isolation in a particular case can be made in the form of a 10 kHz frequency divider into two with transformer coupling at the input and a transformer voltage converter +12 V to +15 V. The microammeter M4256 or the like can be used as indicator 16, the remaining blocks are standard electronic blocks.

 The proposed method of differential diagnosis is implemented using the described device as follows.

 Work begins with a search mode for biologically active points and their preliminary excitation.

 The first switch 3 and the polarity switching unit 12 are set to a position in which a negative voltage is supplied to the active electrode 1-2 from the reference voltage unit 11. The signal from the output of the passive electrode 1-1 is fed to the input of the buffer amplifier 5.

 The switch 15 is set to the position at which the signal from the output of the buffer amplifier 5 is supplied to the input of the indicator 16. Patient 3 takes a passive electrode 1-1 in his hand. The active electrode 1-2 is applied to the skin of the patient in the area of the biologically active point. Indicator 16 shows the current flowing between the active 1-2 and passive 1-1 electrodes. By moving the active electrode 1-2 in the area where the biologically active point is located, the readings of indicator 16 are controlled and the point is localized to the maximum current.

 Then carry out correction with a duration of 7.10 s. For this, the polarity switching unit 12 and the second switch 15 are left in the same position. The first switch is set to the position where the output terminals of the passive 1-1 and active 1-2 electrodes are connected to the inputs of the source and stabilized current. In this case, a pulse signal with a frequency of 0.25 Hz is supplied to the control input of the interrupter 14 from the control generator 13, as a result of which a pulse current of negative polarity and stable amplitude acts on the biologically active point of patient 2. In this case, according to the readings of indicator 16, a transient mode with stabilization of the signal level is observed, which indicates the end of the correction.

 After that, they switch to two consecutive measurement modes.

 In the first mode (anode), the switching unit 12 is transferred to a position in which a signal of positive polarity is supplied to the signal input of the chopper 14. From the control generator 13, a signal is supplied with a frequency of 0.25 Hz with a pulse duration of 3.7 s. Turns on the decisive unit 9, made in the form of a computer with a special program.

 Depending on the condition of the patient at a stable current generated by source 4, the voltage level at its output will change. After amplifying this voltage in the buffer amplifier 5, the signal is fed to the input of a pulse-width modulator 6, in which pulses are formed, the width of which is proportional to the current amplitude of the input signal. Thanks to block 7, galvanic isolation of the circuits is ensured, which ensures the safety of the device. In block 8, the interface converts the signal with pulse width modulation into a digital 8-bit code. The duration of the first mode is several tens of seconds, usually 40.120 s.

 In the second (cathode) mode, also lasting about 40.120 s, the polarity switching unit 12 is brought into a state in which a negative voltage is applied to the signal input of the chopper 14. All other processes proceed similarly to the previous stage.

 Typical signals at the output of the conjugation unit 8 in analogue equivalent for the first and second modes are presented in Fig. 2, a and 2, b, respectively. Their processing in the decisive block 9 is carried out using a special program that is included before the start of the measurement phase.

 The following decisive rule is implemented in the program.

 The computer records the samples of the signals in both measurement modes and processes them. The average level (trend) of the signal is determined, which is indicated as the full potential (PP). The value of the potential is determined at the time when the current is zero, which is indicated as the active potential (AP). And finally, the absolute value of the difference between the total and active potentials is determined, which is designated as resistive potential (RP).

The values of the indicated potentials are processed and the following characteristics are determined:
kinetically singular point (COT) time, i.e. the time interval until the maximum (right) of the first derivative of the active potential in the cathode mode is reached;
the value of the derivative of RP in the anode mode;
asymptotic value of AP in the anode mode;
asymptotic value of PP in the anode mode;
asymptotic value of RP in the anode mode;
relative maximum value of RP in the anode mode;
time to reach the maximum RP value in the anode mode;
asymptotic value of PP in the cathode mode;
asymptotic value of AP in the cathode mode;
CAT lift rate;
the severity of CAT.

 Based on these characteristics, using the conjunct enumeration method implemented in the developed Consilium system, the decision rules used for diagnostics are built.

 The "Consilium" provides for two modes of operation.

 The first is the accumulation of data, a comprehensive analysis of them, the "training" of the system, the construction of decisive classification rules and their testing on the examination material.

 The second mode is for the practical use of ready-made decision rules for the diagnosis of the studied diseases (or conditions) in specific patients.

 The decisive rule obtained at the end of the learning process is fixed and subsequently applied to all possible objects of the diagnostic material. As a result, the “Concilium” provides the doctor with the opportunity to make a reasonable judgment about whether a particular patient belongs to one of the fixed classes of states, focusing on the decisive rules received by the system.

α_iφ_i(x)-

, где
θ(Z)

φ_i (x) есть все возможные конъюнкции длины не более, заданные на дискретных координатах пространства исходных признаков. Конъюнкции φ_i(x) нескольких характеристик признаков принимают значение на тех и только тех объектах, которые имеют одновременно все входящие в нее характеристики.The Concilium system implements a conjunction enumeration method (IPC), according to which the decision rule F * (x) is searched among the class of functions F (x) defined in the form
F (x) =

α _i φ _i (x) -

where
θ (Z)

φ _i (x) is all possible conjunctions of length at most given on discrete coordinates of the space of the original features. The conjunctions φ _i (x) of several characteristics of signs take on value on those and only those objects that have all the characteristics included in it at the same time.

The search for the decision rule is carried out by means of a complete enumeration of the conjunctions φ _i (x) with the subsequent selection of the diagnostically most valuable of them (from the point of view of recognition of classes A and B) based on specially established criteria.

, где Р_м и q_м частоты встречаемости объектом с -ой конъюнкцией соответственно в обоих классах, ε малый параметр.One of these criteria is a value characterizing the information content of the conjunctions in relation to the classification of objects and called the weight of the conjunctions. In practical calculations, the likelihood function was used to calculate the conjunction weight.
ω _μ = ln

, where P _m and q _{m are the} frequencies of occurrence by an object with the conjunction in both classes, respectively, ε is a small parameter.

(φ_i(x))

≥ Э_ω.It is assumed that nonzero coefficients α _i will have only those conjunctions φ _i (x) whose weight exceeds a given threshold value _{ω ω}

(φ _i (x))

≥ _{ω ω} .

One of the criteria for selecting a conjunction in a decisive set is a value determined by the number of training objects N _j characterized by this conjunction. The conjunction φ _i (x) can be included in the decisive set only if N (φ _i (x)) exceeds a predetermined threshold ED value (reliability standard). To select the least correlated conjunctions in the decisive set, the following restriction is introduced: each initial characteristic characteristic in the role of the determining one can enter no more than in the "k" conjunctions of the decisive set (k 1, 2, 3).

The selected set of algorithm parameters determines the decisive set of conjunctions. Thresholds n ₁ and n ₂ are set in the process of using the decisive set on the training material.

 The constructed decision rule is checked on control objects, and the control object is assigned to one of the distinguished classes either by “democratic voting” of A and B-conjunctions of the decisive set, or by voting with weights obtained by these conjunctions in the learning process.

The algorithm that implements the whole IPC for diagnostics is a complex of programs for sequential data processing and includes the following steps:
The first calculation of the basic set of parameters using the logical and arithmetic transformation of the original physical and electrophysiological data obtained at certain intervals; introduction and calculation of temporary derivative indicators reflecting the state of the body; the formation of "images" of biologically active points (BAP) of potentials in the form of graphic contours on the plane.

 The second construction of histograms, quantization of continuous BAP physiological signs and their derived characteristics and assigning numbers to gradations of these signs.

 The third representation of encoded data in matrix form, in the form of rasters, which can significantly reduce the machine time required for the operation of programs based on the IPC.

 The fourth work of the IPC algorithm itself is based on the training material, the search for the optimal set of parameters for constructing the decisive set, the determination of the decisive rule.

 Fifth verification of the resulting decision rule at control sites.

 Based on the use of the IPC, the diagnosis is carried out according to the following decisive rules.

 Characteristic small (negative) AP values in the anode mode indicate the presence of pregnancy.

 The diagnosis of "inflammatory process" is established if the time to reach the maximum RP value in the anode mode and the growth rate of the RP in the anode mode are more than the boundary values, and the asymptotic value of the PP in the anode mode or the asymptotic value of the RP in the anode mode is more than the boundary values. A similar diagnosis can be made in the case when the time to reach the maximum RP value in the anode mode is less than the boundary value, and the relative maximum value of the RP in the anode mode is greater than the boundary value, but the growth rate of the RP in the anode mode is not less than the boundary value.

 The diagnosis of benign neoplasm is made in the case when the time of CT is in the range of 30.55 s and at the same time the rate of rise of the CT and the severity of the CT are greater than the boundary values.

 The same diagnosis is made when the CT time is less than 55 s and at the same time the rate of rise of the CT is greater than the boundary value, the severity of the CT is less than the boundary value, but either the asymptotic value of the SC in the cathode mode or the asymptotic value of the AP in the cathode mode is more than the boundary values.

 A similar diagnosis can be made in the case when the CT time is more than 40.120 s, i.e. CT is absent, but the asymptotic value of the SC in the cathode mode and the asymptotic value of the AP in the cathode mode are greater than the boundary values.

 The diagnosis of “fast growth of neoplasms” is established on the basis of an analysis of characteristics in the cathode mode, when, in particular, the time of CT in the range of 50. 90 s and at the same time the rate of rise of the CT and the degree of manifestation of the CT are more than the boundary values. A similar diagnosis is made when the time of the CTL lies within 50.90 s, the severity of the CTL is less than the boundary value, but the asymptotic value of the SC in the cathode mode and the asymptotic value of the AP in the cathode mode are less than the boundary values.

 For the diagnosis of cancer suspicion, cathodic characteristics are used.

 Characteristic of this diagnosis is the situation when the time of CT is more than 85 s and at the same time the rate of rise of the CT and the degree of expression of the CT are greater than the boundary values.

 A similar diagnosis is made when the COT time is more than 85 s, if the COT rise rate or the degree of COT manifestation is less than the boundary values and the asymptotic value of the SC in the cathode mode or the asymptotic value of the AP in the cathode mode is less than the boundary values.

 These decisive rules have been used in medical practice and have confirmed their high reliability.

 Moreover, due to the use of galvanic isolation of the patient with units powered by high voltage, high diagnostic safety is ensured.

 The effect of increasing the reliability of diagnosis is ensured by using a much larger number of time characteristics and parameters for diagnosis than in the prototype method, as well as using a computer that processes information.

Claims (3)

 1. The method of determining the characteristic parameters in the diagnosis of pregnancy and diseases of the female genital area, which consists in measuring the electrical potentials of biological active points when exposed to a stabilized current, characterized in that the effect is carried out by current pulses of positive and negative polarity, which determine the anode and cathode exposure modes, respectively, the duration of which is chosen equal to 40 120 s, exposure is carried out with a frequency of 0.25 Hz with a pulse duration of 3.7 s, p and this uses the time functions of the full, active and resistive potentials in both modes as measured potentials, according to which the characteristic parameters are determined, which are the time interval until the maximum right first derivative of the active potential in the cathode mode reaches, the values of the first, second and third derivatives of the resistive potential in the anode mode, the asymptotic values of the active, full and resistive potentials in the anode mode, the ratio of the maximum value Nia resistive potential to the full potential in an anodic regime, the time to reach the maximum value in the anode potential of the resistive mode and the asymptotic values of the total and active cathode potentials mode.  2. A device for determining the characteristic parameters in the diagnosis of pregnancy and diseases of the female genital area, containing passive and active electrodes, the input terminals of which are designed to connect to the patient, a stabilized current source, indicator, first and second switches, as well as a series of reference voltages and polarity switching unit, characterized in that a buffer amplifier is connected in series to it, the input of which is connected to the output of the stabilizer source current, pulse-width modulator, galvanic isolation unit and interface unit, as well as decisive unit and conversion unit with galvanic isolation, the reference and clock inputs of which are connected respectively to the reference and clock outputs of the interface unit, the clock output is connected to the clock input of the pulse-width modulator, and the potential output with the input of the reference voltage block, the output of the signal of positive polarity which is connected to the input of the reference signal of the pulse-width modulator, as well as the control generator and the chopper are connected separately, the signal input of which is connected to the output of the polarity switching unit, and the output is connected to the input of the voltage reference of the stabilized current source, while the signal output of the interface unit is connected to the input of the decision unit, the output terminals of the passive and active electrodes are connected respectively to the first and second clamps of the first switch, the third, fourth, fifth and sixth clamps of which are connected respectively to the output of the polarity switching unit, the first and W ring clamps the constant current source and the first input of the second switch, a second input coupled to an output buffer amplifier, and the output to the input of the indicator.  3. The device according to p. 2, characterized in that the decision unit is made in the form of a computer.

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