RU199056U1 - DEVICE FOR CONTROLLING THE PROCESS OF ELECTRIC IMPEDANCE TOMOGRAPHY WHEN FREEZING BIOLOGICAL TISSUES - Google Patents

Abstract

The technical solution relates to medical equipment, namely to the means used in cryosurgery, and can be used for operations for the purpose of cryodestruction of biological tissues. The technical result is the expansion of the arsenal of technical means for a similar purpose. The device for controlling the process of electrical impedance tomography during freezing of biological tissues contains two control units, the first input of the analog multiplexer is connected to the control output of the first control unit, the second input of which is connected to the output of the first control unit through a series-connected signal transformer and a digital-to-analog converter. The analog multiplexer is connected to the second control unit through a series-connected differential amplifier and an analog-to-digital converter. Both control units are connected to the visualization system via a series-connected interface converter and a galvanic isolation unit.

Description

The present utility model relates to medical technology, namely, to the means used in cryosurgery, and can be used for operations for the cryodestruction of biological tissues.

Cryodestruction of skin pathologies, tissues of mucous membranes and cryodestruction of organs in open surgery (liver, pancreas, brain, etc.) is carried out with a wide range of diseases. The ability to partially visually observe the freezing process by the formation of an ice halo around the area of external contact between the cryoapplicator and the tissue leads to confidence that such control, combined with the surgeon's experience, is sufficient to obtain the planned result. Nevertheless, control of the depth of freezing during cryodestruction of skin pathologies and tissues of mucous membranes and organs is no less important. Due to the complex structure of these tissues, insufficient freezing to a given depth will cause a relapse of the disease, and excessively intense hypothermia will damage healthy tissues, worse healing and poor cosmetic effect.

For cryodestruction of pathologies of internal organs, control of the size of the freezing zone is extremely important and can be carried out with precision when using expensive visualization techniques by magnetic resonance imaging and computed tomography. Significantly lower accuracy is provided by the visualization of cryodestruction using ultrasound due to the presence of a shadow area created by the freezing zone [Abramovits, W. (2016). Monitorization Instrumentation with Ultrasound. Dermatological Cryosurgery and Cryotherapy, 137-138].

Known device for controlling measurements, storing and displaying information [patent RU 2719911 C1, publ. 04/23/2020] when freezing biological tissues using scattering spectroscopy. It is not clear from the description what is included in the device; however, the disadvantage of using scattering spectroscopy is the low accuracy of determining the boundaries and depth of cryodestruction.

Known device for controlling the process of electrical impedance tomography when freezing biological tissues [Edd J. F. et al. Imaging cryosurgery with EIT: tracking the ice front and post-thaw tissue viability // Physiological measurement. - 2008. - T. 29. - No. 8. - P. 899.], adopted as a prototype, consisting of a lock-in amplifier (Signal Recovery, Oak Ridge, TN; 7280BFP), a blocking amplifier, measuring equipment, a reference electrode, and a computer-controlled four-electrode impedance measurement circuit that can be connected to any four of the sixty electrodes in the array using a 4:60 analog multiplexer. The lock-in amplifier generates a sinusoidal voltage (1 kHz), which is then converted to direct current. This current is then applied to any pair of electrodes. To sample the resulting potential distribution within the body, the voltage difference between the other two electrodes is amplified and returned to a blocking amplifier, which demodulates it with respect to the applied current to obtain a voltage difference. Measuring equipment measures the impedance between any electrode and the reference electrode, determining the quality of the contact of the electrodes with biological tissue. The disadvantage of the device is the low accuracy of determining the boundaries and depth of cryodestruction.

The problem to be solved by the claimed technical solution is to create a device for controlling the process of electrical impedance tomography during freezing of biological tissues with increased noise immunity, as well as the accuracy of visualization of cryodestruction.

The technical result achieved by the implementation of the utility model consists in expanding the arsenal of technical means for a similar purpose.

The technical result is achieved by the fact that the device for controlling the process of electrical impedance tomography when freezing biological tissues contains two control units, the first input of an analog multiplexer is connected to the control output of the first control unit, the second input of which is connected through a series-connected signal transformer and a digital-to-analog converter to the output of the first unit management. The analog multiplexer is connected to the second control unit through a series-connected differential amplifier and an analog-to-digital converter. Both control units are connected to the visualization system via a series-connected interface converter and a galvanic isolation unit.

It is recommended to use RS232-USB as interface converter.

Galvanic isolation, carried out by the claimed technical solution, provides protection from external interference, as well as signal transcoding by the control unit in order to increase noise immunity and the formation of synchronizing signals increases the accuracy of data transmission and the accuracy of visualization of cryodestruction.

For a better understanding of the essence of the proposed technical solution, graphic materials that do not limit the essence are presented below, where:

FIG. 1 shows a block diagram of a device for controlling the process of electrical impedance tomography during freezing of biological tissues.

FIG. 2 shows a general view of the device in operation.

FIG. 3 shows a device with connected electrodes to the research object.

The device (Fig. 1, Fig. 2, Fig. 3) consists of two control units (which include microcontrollers) 1 (Fig. 1) and 2, a digital-to-analog converter (DAC) 3 is connected to the control outputs of the control unit 1 and a digital input of an analog multiplexer 4. A signal transformer 5 is connected to the control output of the DAC 3, the outputs of which are connected to an analog multiplexer 4, which is connected through a series-connected differential amplifier 6 and an analog-to-digital converter (ADC) 7 to the control unit 2. Control units 1 and 2 are connected to the visualization system 8 through a series-connected interface converter 9 (for example, RS232-USB) and a galvanic isolation unit (GR) 10. Terminals 11 (Fig. 1) of the analog multiplexer 4 are made with the possibility of connecting electrodes E ₁ -E _n ( Fig. 3).

The utility model works as follows. Control unit 1 selects one of the current channels by transmitting a digital signal with the channel number of the analog multiplexer 4 from the control output of the control unit 1 to the digital input of the analog multiplexer 4. Then the measuring channels are selected by transmitting a digital signal with the channel numbers of the analog multiplexer 4 from the control output of the control unit 1 to the digital input of the analog multiplexer 4. Control unit 1 transmits the digital signal to the digital input of the DAC 3, where it is converted into an analog signal with a given voltage level at the output of the DAC 3. The generated signal is fed to the signal transformer 5, the output of which is linearly dependent on the value input signal. Depending on the selected current channel of the analog multiplexer 4 by the control unit 1, the current signal is supplied to the electrode connected directly to the biological object (Fig. 3). The applied current passes through the study area, creating an electric field in it, the potential difference of which is recorded by the measuring electrodes, which correspond to the selected measuring channels assigned by the control unit 1. The signal from the measuring electrodes, passing through the analog multiplexer, is fed to the input of the differential amplifier 6. Differential amplifier converts the difference between the input voltages into an amplified bipolar signal, which is fed to the input of the analog-to-digital converter 7. According to the signal from the control unit 2, a single analog-to-digital conversion is carried out and the output signal of the ADC 7 in the form of a digital signal is fed to the input of the control unit 2, thus forming one frame. Further, the control unit 1 selects other measuring channels with the same current channel, thus, the measurement cycle is repeated until measurements are taken from all measuring electrodes E ₁ -E _n - ₁ , as a result of which the entire set of frames forms one projection ... After all measurements have been made on one current channel, a new number of the current channel is selected by the control unit 1 and the measurement cycle is performed again for all measuring channels. With an increase in the area of the biological tissue under study, the number of electrodes connected to the device increases, respectively, and the number of cycles for selecting measuring channels and measurements also increases.

The control unit 2 accumulates projections according to the output signals of the ADC 7 and upon completion of the measurements, it re-encodes the signal in order to increase noise immunity and generates synchronizing signals for the visualization system. The control unit 2 transmits the recoded and synchronization signals to the visualization system 8 through the interface converter 9 (for example, USB - RS232) and the GR unit 10.

The example below illustrates but does not limit the utility model.

Example 1. After the contact of the cryoapplicator 12, which is at a temperature close to the temperature of liquid nitrogen (-196 ° C), and biological tissue (which was taken as a chicken breast) near the contact area, the temperature dropped sharply, which led to the formation of a temperature gradient propagating deep into the tissue, which can be characterized by isotherms of the freezing zone (figure 3). The surface of the isotherm corresponding to the freezing point of water was displaced into the tissue from the contact area within three minutes after the application of the cryoapplicator to the tissue. The device used a multiplexer FB-MUX / HS / DAIO / PA (1005329 Phoenix Contact) with three 6-channel digital and analog I / O modules. The frequency and current strength at the output of the signal transformer 5 were controlled in the range of 100 Hz - 1 MHz and 0.01-200 mA, respectively. The operating current at the output of the signal transformer 5 was 20 mA, and the frequency was 100 kHz. 30 electrodes were connected to terminals 11 of the analog multiplexer 4, to remove one projection, the measurement cycle was carried out 15 times, and to obtain all projections - 450 times.

During the implementation of the utility model, projections were obtained, which were transferred to the visualization system of the device, visualizing with high accuracy the boundaries and depth of cryodestruction.

Claims (2)

1. A device for controlling the process of electrical impedance tomography when freezing biological tissues, consisting of an analog multiplexer, characterized in that it additionally contains two control units, the first input of the analog multiplexer is connected to the control output of the first control unit, the second input of which is through a series-connected signal transformer and a digital-to-analog converter is connected to the output of the first control unit, while the analog multiplexer is connected to the second control unit through a series-connected differential amplifier and an analog-to-digital converter, and two control units are connected to the visualization system through a series-connected interface converter and a galvanic isolation unit. 2. The device according to claim 1, characterized in that RS232-USB is used as the interface converter.

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