RU2376933C1 - System of electroimpedance oncology diagnostics - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: system of electroimpedance oncology diagnostics relates to medical equipment and can be used in oncology diagnostics of biological tissues of hollow and somatic organs, as well as human skin. System contains control unit, comparison unit, one of whose inlets is connected with outlet of read storage unit, and output is connected with inlet of unit of information log and display, system of impedance measurement, connected with active and passive electrodes, additionally contains microcontroller, one inlet of which is connected with outlet of system of impedance measurement, second inlet is connected with outlet of control unit, and outlet is connected with inlet of comparison unit, system of impedance measurement representing multi-frequency impedance metre. In one of particular forms of realisation of system of electroimpedance oncology diagnostics multi-frequency impedance metre includes connected to each other generator of signal in frequency range from 0.5 to 2000 kHz, sensors of current and voltage, divider of signal values, register memory.

EFFECT: invention allows to diagnose biotissues of various types and physiological states reliably and accurately, including cases when impact of external factors (electromagnetic interference, biotissue topology and its various clinical states), distorting values of examined (diagnosed) biotissue characterisrtics.

2 cl, 5 dwg

Description

The system of electrical impedance oncological diagnostics relates to medical equipment and can be used in oncological diagnostics of biological tissues of hollow and somatic organs, as well as human skin.

High rates of cancer morbidity and mortality are due, inter alia, to untimely diagnosis and treatment.

Currently, such methods of medical imaging as radiography, fluoroscopy, ultrasound diagnostics, thermography, X-ray computed tomography, NMR diagnostics, and diagnostics using radioisotopes are used to diagnose volumetric formations, especially small sizes, and their nosological affiliation. However, the diagnostic results by known methods and devices, especially with minimal manifestation of violations of the shaping processes and their functions, are distorted by significant errors due to the presence of a wide variety of forms of malignant tumors, inflammatory processes in tissues, artifacts, etc. At the same time, the clinician often deals with strictly regulated diagnostic "tools" that are oriented and allow one to obtain integral information about the state of the function or the state of the result of the aggregate vital activity of many cells, tissues, and sometimes organs.

An exception to this, a fairly general rule, are cytological and histological diagnostic methods, in which the researcher is guided by the actual morphological characteristics of the cellular and tissue levels. However, morphological analysis requires the removal of the necessary substrate from the body, and this procedure can be successful only in the case of targeted surgical intervention, i.e. the method is not only invasive, but, in terms of the totality of actions (searching for the "source" of the process, taking material under conditions of punctured puncture or by biopsy), is far from 100% reliable. Unfortunately, even cytological screening gives the number of errors in the diagnostic procedure up to 30%.

In such a situation, the search for new, highly sensitive and minimally invasive methods for diagnosing the state of tissues, which not only identify the early manifestations of the pathological focus, but also possibly precede the morphological analysis during vital (intravital) diagnostics, is of undoubted relevance. The most promising in this regard can be considered methods and devices using high-frequency current.

The closest analogue of the claimed invention is an impedance electrosurgical apparatus (RU 2204351, ⁷ АВВ 18/12 dated 05/20/2003), which allows to evaluate the structure of biological tissue during surgical intervention. This apparatus contains a control unit, a controlled power supply unit, high and low frequency generators connected through the first and second current sensors, first and second voltage sensors and impedance calculation blocks at high and low frequencies to the active and passive electrodes. The impedance calculation units are connected to the Tarusov polarization calculation unit connected via a comparison unit to the monitor. The second input of the comparison unit is connected to a read-only memory device. The electrosurgical apparatus determines the impedance values of the biological tissue at frequencies of 2 kHz and 440 kHz, calculates the polarization coefficient Kp of the biological tissue, which is equal to the ratio of the impedance values. By comparing the calculated value of the polarization coefficient Kp with the given values determined experimentally and corresponding to the healthy or pathological state of the biological tissue, the values of Kp are used to identify the physiological state of the diagnosed biological tissue, after which the electrosurgical device generates an electrosurgical power corresponding to the obtained characteristics.

The disadvantage of the impedance electrosurgical apparatus (RU 2204351) is the low degree of accuracy in diagnosing various structures and physiological conditions of biological tissues. This is due to the fact that the measurement range of the electrical characteristics produced by this device is not wide enough (testing of biological tissues is carried out at two frequencies). And also because the use of only two frequencies for testing biological tissues increases the likelihood of obtaining distorted (erroneous) impedances of the biological tissue and, accordingly, the polarization coefficient Kp, in the case when there is an influence of external factors (electromagnetic interference, biological tissue topology and its various clinical status, etc.). This further reduces the reliability of identification and diagnosis of biological tissues.

The task of the invention is to increase the accuracy of diagnosis of biological tissues of various types and physiological conditions.

The essence of the claimed invention lies in the fact that in the system of electrical impedance oncological diagnostics, containing a control unit, a comparison unit, one of the inputs of which is connected to the output of the permanent memory unit, and the output is connected to the input of the information recording and display unit, the impedance measurement system connected to the active and passive electrodes, an additional microcontroller is introduced, one input of which is connected to the output of the impedance measurement system, the second input is connected to the output of the control unit, and the output is connected nen with the input of the comparison unit, while the impedance measurement system is a multi-frequency impedance meter.

A multi-frequency impedance meter includes a signal generator interconnected in the frequency range from 0.5 to 2000 kHz, current and voltage sensors, a signal value divider, and a register memory.

Due to the fact that in the proposed system of electrical impedance oncology diagnostics, the impedance measurement system is a multi-frequency impedance meter, it becomes possible to measure the electrical impedance Z of the biological tissue at various frequencies f of the signal in a wide range and the formation of the functional dependence Z (f).

Introduction to the system of electrical impedance oncological diagnostics of a microcontroller connected to a multi-frequency impedance meter and to a control unit provides the calculation of the polarization coefficient Kp and the integral impedance Zs based on the measured values Z (f). Thus, each function Z (f) is characterized not by a single value of Kp, as in the case of a two-frequency measurement of the impedance produced by an electrosurgical apparatus - an analog, but by a whole set of Kp values, each of which more accurately characterizes a certain type of biological tissue in its specific physiological state. The calculation of the integral value of the impedance Zs allows, in the event of interference in the electrical system, to level out partial unreliable values of the impedance Z at certain frequencies, as well as to track the change in the values of Z (f) depending on the physiological state of the biological tissue in the studied area. In addition, in the event of various clinical conditions (bleeding, necrosis, etc.) during the study, when it makes sense to talk about changes in the electrophysical properties of biological tissues, it is possible that the doctor can correct the values calculated by the microcontroller from the control unit Kp and Zs. Thus, the probability of obtaining incorrect, erroneous values of Kp and Zs is further reduced, which means that the accuracy and reliability of the diagnosis of the type and physiological state of biological tissue are further enhanced.

Thus, a wider set of more accurate and reliable values of the characteristics of the studied (diagnosed) biological tissue is formed, which allows for a more accurate diagnosis of it, by subsequently comparing the obtained values of the partial Kp and Zs with the given known values entered into the read-only memory block, which determine the correspondence of the obtained electrical parameters to certain types and physiological states of biological tissue.

The essence of the claimed invention is illustrated by graphic images, in which Fig. 1 is a functional diagram of an electrical impedance oncology diagnostic system, Fig. 2 is a functional diagram of a multi-frequency impedance meter 2, which includes a signal generator interconnected in a frequency range from 0.5 to 2000 kHz, current and voltage sensors, a divider of signal values, register memory, figure 3 presents curves characterizing the frequency distribution of the electrical impedance of muscle tissue during two frequency-frequency (a) and multi-frequency (b) impedanometry, Fig. 4 shows curves characterizing the multifrequency electrical impedance measurement of a healthy biotissue of the wall of the small intestine in 2 experiments, Fig. 5 shows a block diagram of the microcontroller operation algorithm as part of the electrical impedance oncology diagnostic system.

The electrical impedance oncology diagnostic system (Fig. 1) contains an active electrode 1, a multi-frequency impedance meter 2, a microcontroller 3, a comparison unit 4, a read-only memory unit 5, a control unit 6, an information recording and display unit 7, a passive electrode 8. Moreover, the active electrode 1 is connected to one input-output of a multi-frequency impedance meter 2, a passive electrode 8 is connected to a second input-output of a multi-frequency impedance meter 2; one input of the microcontroller 3 is connected to the output of the multi-frequency impedance meter 2, the other input of the microcontroller 3 is connected to the output of the control unit 6, and the output of the microcontroller 3 is connected to the input of the comparison unit 4; the other input of the comparison unit 4 is connected to the output of the permanent memory unit 5, the output of the comparison unit 4 is connected to the input of the registration and information display unit 7.

The microcontroller circuit 3 can be implemented on the basis of a microcontroller from the F8051F35x family of Silicon Laboratories (with integrated ADC).

The unit for recording and displaying information 7 can be implemented as a computer.

Multi-frequency impedance meter 2 includes interconnected signal generator in the frequency range from 0.5 to 2000 kHz, current and voltage sensors, a divider of signal values, register memory (figure 2).

The system of electrical impedance oncological diagnostics works as follows. In the case of the study of hollow or visceral somatic organs of the patient, respectively, endoscopic or laparoscopic systems (not shown in Fig.) Are used, through the instrumental (biopsy) channels of which the active electrode 1 is supplied to the surface of the test site. When examining open cavities and physiological surfaces (including skin), the active electrode 1 is supplied to the surface of the investigated area without the use of special supply systems. A passive electrode 8 is placed under the thigh of the patient under study (not shown in Fig.). The multi-frequency impedance meter 2 measures the electrical impedance Z of the biological tissue in the study area between the active electrode 1 and the passive electrode 8 in the frequency range from 0.5 to 2000 kHz supplied to the test site, resulting in a functional dependence (Fig. 3 (6)) :

.

.

The microcontroller 3, based on the values of Z (f), calculates the electrical parameters Z (f) using the formulas (Fig. 5):

particular polarization coefficients Кп for each ith value of Z (f):

;

;

and the integral impedance parameter Zs:

, где n - количество частот измерений.

where n is the number of measurement frequencies.

The curves depicted in Fig. 3 (a, b) characterizing the frequency distribution of the electrical impedance of the muscles with two-frequency (a) and multi-frequency (b) impedancemetry illustrate that with multi-frequency impedancemetry implemented in the electrical impedance oncology diagnostic system, the function Z (f) is not characterized one value of Kn, calculated on the basis of two values of the electrical impedance Zn and Zq, as in the case of a two-frequency measurement of impedance (figa), and a whole set of values of Kn, calculated on the basis of several values (Z _f1 , Z _f2 , ... Z _fn ), each and which more accurately we characterize the specific type of biological tissue in its particular physiological state.

As a result of interference in the system of electrical impedance oncology diagnostics, individual values of impedance Z corresponding to certain frequencies can be distorted (figure 4), and, therefore, the accuracy of diagnosis using private polarization coefficients Kp can be reduced. In this case, the calculated integral value Zs allows you to level out partial false values of the impedance Z at certain frequencies. So, using at least 5-6 reference frequencies for impedance measurements, when the impedance values are distorted on two of them, the degree of diagnostic accuracy by the integrated method will be quite high even when using impedance values corresponding to all frequencies as calculation data.

In the event that certain clinical conditions (bleeding, necrosis, etc.) occur during the study, when the electrophysical properties of biological tissues are likely to change, it is possible to adjust the values of Kp and Zs calculated by the microcontroller 3. To do this, the doctor conducting the study, during operation of the system using the controls (not shown in Fig.) Located on the control unit 6, introduces the correction factors Kp and Kz corresponding to the arising clinical conditions, taking into account which the microcontroller 3 corrects, respectively, Kp and Zs values:

;for each ith value of Z (f):

;

.

.

The values of Кп and Zs calculated and, if necessary, corrected by the microcontroller 3 are sent to the comparison unit 4, in which, by comparing the obtained values of Кп and Zs with the values established experimentally and entered into the database of the permanent memory unit 5, the type of biological tissue and its type are determined physiological state. The information recording and display unit 7 displays video information coming from the output of an endoscopic or laparoscopic video system (not shown in Fig.), In the form of an image of the studied area, as well as data on the types and physiological conditions of biological tissue in this area, obtained as a result of multi-frequency electrical impedance diagnostics .

Thus, the set of essential features of the claimed system of electrical impedance oncological diagnostics allows, by reducing the likelihood of obtaining inaccurate values of electrical parameters, to improve the accuracy of diagnosis of biological tissues of various types and physiological conditions.

Claims (2)

1. The system of electrical impedance oncology diagnostics, comprising a control unit, a comparison unit, one of the inputs of which is connected to the output of the read-only memory unit, and the output is connected to the input of the information recording and display unit, an impedance measurement system connected to the active and passive electrodes, characterized in that it additionally contains a microcontroller, one input of which is connected to the output of the impedance measurement system, the second input is connected to the output of the control unit, and the output is connected to the input of the comparison unit, however, the impedance measurement system is a multi-frequency impedance meter. 2. The system of electrical impedance oncological diagnostics according to claim 1, characterized in that the multi-frequency impedance meter includes interconnected signal generator in the frequency range from 0.5 to 2000 kHz, current and voltage sensors, a divider of signal values, register memory.

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