RU2102006C1 - Method and device for evaluating biological tissues state - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: method involves simultaneously using stabilized electric measurement current of high and low frequency for acting upon biological tissue. To do it, device has high and low frequency filters introduced into the general device circuit, adder, negative feedback rectifier and low frequency filter of negative feedback. Alternating frequency voltage source has two adjustable generators of high and low frequency. EFFECT: enhanced accuracy of diagnostic examinations; simplified design. 2 cl, 1 dwg

Description

 The invention relates to the field of medicine and medical technology, in particular, to means for determining the state of biological objects by conductometric methods.

 Known methods and devices for determining the state of biological tissues and fluids by measuring the absolute electrical resistance module (A.S. N 1367938, A.S. N 1821135, Pat. RF N 2033078, A.F. Aleinikov et al. Portable conductometer "Tonus -2 ". Control and diagnostics of agricultural facilities. Collection of scientific tr. Novosibirsk. 1981. P. 16-22). In most technical solutions, the reliability of the information obtained as a result of measurements is significantly reduced due to the difference in the measurement time.

 A device for measuring the looseness of epithelial tissue of the gastrointestinal tract based on the determination of the module of the total electrical resistance of the epithelial tissue (US Pat. RF N 2026004, class A 61 B, 5/05).

 However, this device allows you to obtain information about the state of biological tissue by the degree of difference between the modules of the total electrical resistance, measured alternately at low and high frequencies, which does not provide reliable information about the unchanged state of the studied tissue site. In addition, the device does not automatically measure such an information conductometric indicator as the polarizability coefficient of biological tissue. Moreover, the circuit includes a device for protecting the patient from electric shock, which, in all probability, is caused by the use of a power source. The need for a protection device greatly complicates the electronic circuit of the meter.

 This technical solution was made by us as a prototype device.

 A known method of measuring the absolute electrical resistance of biological tissue at low and high frequencies, spaced no less than an order of magnitude, calculates the polarization coefficient based on the ratio of resistance values at different frequencies. For the criterion for assessing the state of biological tissue, take the digital result of the ratio of the impedance modules at low and high frequencies. (Yu.V. Tornuev et al. Electrical impedance of biological tissues. M. 1990. S. 36-38, 46-48). However, this method does not allow to obtain reliable information about the unchanged state of the biological tissue by alternately measuring the total electrical resistance of the biological tissue at different frequencies.

 This decision was made by us for the prototype of the claimed method.

 The aim of the invention is to increase the reliability of information about the state of biological tissue by eliminating the time interval between the moments of measurement and miniaturization of the structure.

 The drawing shows a block diagram of a device.

 This goal is achieved by measuring the absolute electrical resistance of the biological tissue at high and low frequencies, spaced no less than an order of magnitude, and the total voltage of the alternating current is applied to the studied area, i.e., the biological tissue is affected simultaneously by the measuring current of high and low frequencies, and the digital result of the ratio of the impedance modules at low and high frequencies is taken as the evaluation criterion.

 The inventive device includes voltage sources of variable frequency, electrodes, current stabilizer, amplifier, high and low frequency detectors, the outputs of which are connected respectively to the inputs of the voltage ratio converter, made in the form of an analog-to-digital converter (ADC), the output of which is connected to the input of a digital indicator, and autonomous power supply. In addition, two low and high frequency filters, an adder, a negative feedback rectifier and a low frequency filter of negative feedback, are introduced into the device. The voltage source of variable frequency is made in the form of two controlled generators of low and high frequency, respectively, the outputs of which are connected to the inputs of the mixer, the output of which is connected to the control inputs of the low and high frequency generators through a rectifier and a low-frequency filter of negative feedback, and through the measuring current stabilizer connected to the first electrode, the amplifier output through low and high frequency filters, respectively, connected to the inputs of the low and high frequency detectors, while stroke amplifier connected to the first electrode and the second electrode is connected to a common bus device.

 The claimed method is implemented by this device. Electrodes are superimposed on the test site, the measurement tissue is exposed to the biological tissue of the test area, the absolute electrical resistance moduli at low and high frequencies are measured, separated by at least an order of magnitude, the polarization coefficient is determined and the state of biological tissues is evaluated, and the measurement signal is used stabilized measuring current at the same time high and low frequency.

 It is known that with increasing frequency of the measuring current, the complex resistance of biological tissue decreases. This phenomenon, called resistance dispersion, is a property of a living cell, tissue and is due to the polarization of tissues. The death of a biological object excludes the dispersion of its resistance and, therefore, the ability of the tissue to polarize. At frequencies equal to 10 kHz and above, the bioobject has maximum electrical conductivity (B.N. Tarusov. Biophysics. M. Higher School. 1968). An increase in electrical conductivity occurs due to a decrease in the capacitive component of the complex resistance, i.e. at high frequencies, the active component of complex resistance predominates in the bioobject; at low frequencies, certain tissue structures or subcellular membranes prevent the direct transfer of carriers. The dispersion of resistance is explained by the presence of polarization phenomena in the biological object. When measuring at high frequencies, polarization phenomena do not occur. When the state of a biological object worsens, when the tissue dies, its ability to polarize decreases. It is polarization that carries information about the state of a biological object: the dispersion coefficient is determined by the ratio of the resistance measured at a low frequency to the resistance measured at a high frequency. But when alternately measuring the modules of the total electrical resistance at low and high frequencies, inevitably there is a loss ("failure") of information, leading to insufficient reliability of the result. Exposure to the summed AC voltage, consisting of high and low frequency voltages, avoids these information losses. Thus, the invention meets the criterion of "significant differences".

 A device for assessing the state of biological tissues consists of two voltage sources of variable frequency 1, 2, two electrodes 3a, 3b, test biological tissue 4, adder 5, negative feedback rectifier 6, low-pass filter 7, measuring current stabilizer 8, amplifier 9, filter High-frequency filter 10 and low-pass filter 11, high-frequency rectifier 12, low-frequency rectifier 13, voltage-ratio converter 14, made in the form of an analog-to-digital converter, digital indicator 15, autonomous power supply (not shown in the block diagram). To eliminate the time interval between the moments of measurements at high and low frequency, voltage sources are made in the form of two controlled generators of respectively high and low frequency 1, 2 and an adder 5, in the output voltage of which there are components of low-frequency and high-frequency AC voltage. To stabilize the amplitude of the output voltage of the adder 5 between the output of the adder 5 and the inputs of the generators 1, 2 included negative feedback (rectifier 6 and a low-pass filter 7). Negative feedback is necessary to stabilize the voltage of the adder 5 by influencing the output voltages of the high and low frequency generators. A low-frequency negative feedback filter is introduced to eliminate ripples present in the output voltage of the negative feedback rectifier 6. A stabilized current source 8 allows maintaining the value of the measuring current flowing through biological tissue that does not exceed the requirements of the international standard (IEC 601-1. Medical electrical products Part 1. VNIIMP. M. 1988. P. 66).

где N_пред верхняя граница диапазона измерений, N_изм - измеренное значение сопротивления.The method according to the invention is implemented as follows. Two electrodes 3a, 3b are superimposed on the studied area of the biological tissue at a fixed distance between them. From the output of the current stabilizer through the electrodes, the measuring signal enters the biological tissue 4 in the form of a sum of high and low frequency alternating current voltages. When the measuring current is exposed to high and low frequencies, the current penetrates both the cellular and intercellular structures of biological tissue. Since an alternating measuring current flows through the biological tissue, which does not depend on the value of its resistance, the voltage drop between the electrodes is proportional to the value of the absolute electrical resistance module. The functional state of biological tissue is evaluated by the ratio of the resistance measured at a low frequency to the resistance measured at a high frequency, i.e. by dispersion coefficient. Measurement range from 20 to 2000 OM with the main relative error

where N _before upper limit of the measuring range, N _MOD - measured resistance value.

где U_с выходное суммарное напряжение сумматора, K_с - коэффициент усиления сумматора.The combined AC voltage, consisting of a high frequency voltage and a low frequency voltage, avoids the loss of information in the interval between measurements and is expressed by the formula:

where U _{with the} output total voltage of the adder, K _with the gain of the adder.

The device operates as follows. From the output of a stable current source 8, through the electrodes 3a, 3b, the measuring signal continuously arrives at the biological tissue 4. Since an alternating current, independent of the value of its resistance, flows through the biological tissue, the voltage drop between the electrodes is proportional to the value of the absolute electrical resistance module. The voltage drop across the biological tissue is fed to the input of the amplifier 9, from the output of which it goes simultaneously to the inputs of the low-pass filter 11 and the high-pass filter 10. From the output of the filters 10, 11, alternating low and high-frequency voltages are fed to the inputs of the detectors 12, 13. At the output the detector of high frequency 12 generates a constant voltage proportional to the resistance Z _VCH (f = 200 kHz), the output of the detector low frequency 13 generates a constant voltage proportional to the resistance Z _LF (f = 2 kHz). From the outputs of the detectors, constant voltages are supplied to the inputs of the voltage ratio converter 14, made in the form of an analog-to-digital converter. At the output of the ADC 14, digital information is generated proportional to the ratio of the impedance modules at low and high frequencies, i.e. information on the polarizability coefficient of biological tissue by the formula:
KP biological tissue Z _LF / Z _rf.

 Our numerous studies have allowed us to evaluate various conditions of biological tissue by the polarizability coefficient within the following limits: with CP up to 1.8 malignant tumors, with CP 1.81-1.9 benign tumors, with CP 1.92-2.0 normal.

 Example 1. Patient S. 48 years. Examined on an outpatient basis. Gastroscopy in the antrum of the stomach from the side of lesser curvature revealed a flat ulcer defect up to 8 mm in size. The edges are not clear enough, the bottom is fibrinous, gastric wall infiltration with instrumental palpation is not determined. The pylorus is swollen, slightly deformed, its mucosa is hyperemic. Endoscopic diagnosis: antrum ulcer.

 The electrical resistance was measured at two opposite edges of the ulcer with the determination of the polarizability coefficient of the tissue: at point 1 KP 1.7, at point 2 KP 1.82. A biopsy was taken from the test points. At point 1 (KP = 1.7), malignant degeneration of the mucosa (granulating gastric cancer) was histologically revealed. At point 2 (KP = 1.82) chronic inflammation.

 Example 2. Patient B. 62. Conducted conventional gastroscopy. Visually: on an empty stomach in the lumen of the stomach a lot of muddy mucus. Exophytic, crest-like formation up to 2 cm in diameter was revealed by small curvature in the middle third of the stomach. The fabric is dense, bleeding, folds converge to the base of exophyte. When a biopsy is taken, the tissue is fragmented. With instrumental palpation, tissue stiffness is determined in the area up to 2 cm from the base of the tumor.

 The measurement of electrical resistance. When exposed to a measuring current of high and low frequency, the functional state of the stomach corresponds to the index KP = 1.8 malignant formation. The result is confirmed by endoscopic examination: exophytic cancer of the stomach 2A-2B degree.

 For comparison, the electrical resistance was measured by the prototype method: when separately measured, first at a high frequency (236 Ohms), then with an interval of 14-15 s at a low frequency (440 Ohms), KP = 440: 235 = 1.86, which corresponds to benign education.

 Example 3. Patient T. 64 g. Complains of a tumor in the neck. Objectively, palpation in the region of the left lobe of the thyroid gland reveals nodular formations.

 Clinical diagnosis: nodular goiter. The operation was performed. During surgery 3 nodes were identified in the left lobe of the thyroid gland with dimensions of 0.2-0.5 cm. The nodes are mobile, medium density.

 The electrical resistance was measured according to the technology claimed in the invention. As a result of measurements in 1 node KP = 1.83, in the 2nd KP = 1.9, in the third KP = 1.7.

 The results of impedanometry make it possible to establish a diagnosis of thyroid cancer. Histologically adenocarcinoma.

Claims (2)

 1. A method for assessing the state of biological tissues, including applying electrodes to the test site, exposure to it with a measuring signal, measuring the modules of hollow electrical resistances at low and high frequencies, separated by at least an order of magnitude, determining the polarization coefficient and evaluating the state biological tissue, characterized in that as a measuring signal using a stabilized measuring current at the same time high and low frequency.  2. A device for assessing the state of biological tissues, containing a variable frequency voltage source, electrodes, a measuring current stabilizer, an amplifier, high and low frequency detectors, the outputs of which are connected respectively to the inputs of the voltage ratio converter, made in the form of an analog-to-digital converter, the output of which is connected to digital indicator input, and an autonomous power source, characterized in that two filters of high and low frequencies, respectively, are introduced into it, an adder, a rectifier negative feedback and a low-frequency filter of negative feedback, and a variable frequency voltage source is made in the form of two controlled generators of respectively low and high frequency, the outputs of which are connected to the inputs of the adder, the output of which is connected to the control inputs through a rectifier and a low-frequency filter of negative feedback low and high frequency generators, and through a measuring current stabilizer connected to the first electrode, the amplifier output through low and high frequency filters with responsibly coupled to inputs of detectors low and high frequencies, the input of the amplifier is connected to the first electrode and the second electrode is connected to a common bus device.