RU2800849C1 - Primary measurement information pickup device for electrical impedance tomography systems - Google Patents

Abstract

FIELD: medical equipment.

SUBSTANCE: invention is intended for monitoring and evaluating the functional state of the lungs of a biological object for use in electrical impedance tomography and allows to obtain primary measurement information for dynamic visualization of the processes of ventilation and perfusion of the lungs, as well as personalization of artificial lung ventilation modes. The primary measuring information pickup device for electrical impedance tomography systems consists of disposable and reusable parts. The disposable part is presented in the form of a fabric elastic electrode belt, on which fabric non-metallic conductive electrodes are located. The electrode cables of the disposable part are located on the belt with the possibility of stretching the fabric elastic electrode belt in the direction of the long axis under the action of an external force. The plurality of electrodes are electrically connected to the plurality of electrode cables, wherein the number of electrode cables of the disposable portion is equal to the number of non-metallic conductive electrodes. The reusable part is a continuation of the disposable and is connected to it through the output connector.

EFFECT: obtaining a primary measurement information pickup device for electrical impedance tomography systems.

1 cl, 5 dwg

Description

The claimed technical solution relates to the field of medical technology and can be used to monitor and evaluate the functional state of the lungs of a biological object, and allows you to obtain primary measurement information for dynamic visualization of the processes of ventilation and perfusion of the lungs, as well as personalization of artificial lung ventilation (ALV) modes.

Electrical impedance tomography (EIT) is a method for visualizing the internal structures of an object under study, based on assessing the change in the conduction field in the plane of the electrode system (ES) when a low-amplitude high-frequency current is injected through the object (according to a given algorithm) while simultaneously recording the emerging potential differences.

To take primary measurement information for electrical impedance tomography systems, an electrode system is used, which is applied along the perimeter of the chest. To assess the change in the conduction field of the object, a current source is connected to a pair of electrodes and a low-amplitude high-frequency current is injected. Simultaneously with the electrodes that are not currently injected, the emerging potential differences are recorded. Next, the current source is connected to the next pair of electrodes and the potential difference is taken from other measuring electrodes. Such measurements are repeated until the data acquisition process is stopped by the user. The obtained measurement information is transmitted to the processing device, where the inverse problem is solved and its results are visualized in the electrode system overlay plane.

There are currently two main types of electrode systems:

- disposable;

- reusable;

There are two types of disposable electrode systems:

1) adhesive-based electrodes are located on the body of a biological object

2) the electrode system is tissue, including tissue electrodes attached to a carrier object (electrode belt), which has extensibility and, in turn, is located on the body of a biological object.

Reusable electrode systems consist of metal electrodes attached to a carrier object (electrode belt), which has extensibility and, in turn, is located on the body of a biological object.

Electrode systems have disadvantages.

Disadvantages of adhesive-based electrode systems:

- overall dimensions do not allow their use on all biological objects;

- the constancy of the distance between the electrodes is not observed, which leads to measurement errors and artifacts.

Disadvantages of metal electrode systems:

- are reusable, made of materials that require sterilization, cleaning, disinfection;

- the materials currently used for the manufacture of electrodes are hard, hard, cause discomfort during prolonged wear, contribute to the formation of bedsores (wounds), the electrodes do not fit snugly against the body;

- Difficulty in preparation for use. A minimum of two people are required to connect this electrode system;

- high manufacturing cost.

Tissue electrode systems solve all the problems presented above. In clinical practice, it is important to reliably and quickly connect the device to bedridden patients, tight contact between the body and each electrode, equal distance and uniform stretching between the electrodes to obtain an image on the EIT device without artifacts, compliance with sanitary and hygienic requirements, small overall dimensions, low manufacturing cost.

Known electrode tape for collecting electrical impedance tomography data [patent CN211213147 (U), IPC A61B 5/053, published 11.08.2020].

The utility model represents an electrode strip for collecting electrical impedance tomography data. In this case, the metal conductive films (electrodes) are evenly distributed in the direction of the length of the rubber binding belt and come out of it, and the electrode cables are connected to the metal conductive films (electrodes). At one end of the rubber tie strap, a plurality of clamping holes are provided, and at the other end, there are protrusions of the buckle clamped in the clamping holes. The number of conductive rubber blocks is equal to the number of metal conductive connectors.

The disadvantages of this technical solution are injury to skin areas, and if the belt is on the patient for a long time, bedsores (wounds) can form, electrode outlets can press and cause discomfort, in addition, there is a high level of artifacts (inaccuracies, distortions, errors) due to loose fit, affecting the accuracy of the resulting image.

Also known is an electrode tape for collecting electrical impedance tomography data [patent CN215839041 (U), IPC A61B5/0536, issued a patent on February 18, 2022], adopted as a prototype. The tape is made of fabric elastic with bent conductive wires (electrode cables) woven into it, forming a single whole with it in the form of an electrode tape, providing, when it is stretched in the direction of the long axis under the action of an external force, the transformation of the conductive wires from a bent shape into a linear one. The electrode strip contains a plurality of electrodes equidistant from each other, which are electrically connected to a plurality of conductive wires.

The disadvantages of the prototype is the hardness and rigidity of the electrode tape, due to the interweaving of conductive wires (electrode cables), which can cause discomfort when using the tape on the patient's body, and with prolonged bedside monitoring, it can contribute to the formation of bedsores (wounds), in addition, the elasticity of the tape is reduced due to the weaving of conductive wires directly into the fabric of the tape, as well as the location of the electrodes in it and their insufficiently tight fit to the body, which, in turn, reduces the quality of the primary measurement information.

The task to be solved by the claimed technical solution is to increase patient comfort, ensure sanitary and hygienic standards, obtain a more accurate image of the area of study of a biological object, reduce the cost of manufacturing the device, the ability to use the electrode system on biological objects with different parameters of the chest, the ability to connect electrode system by one person to a biological object.

The technical result achieved in solving the problem is to reduce the formation of bedsores (wounds) during long-term wearing of the device in clinical practice, the disposability of the device for removing primary measurement information, ensuring the tightest fit of the electrodes to the area of study of the biological object to reduce artifacts and interference, to reduce overall dimensions of the product, in particular electrodes, ease of use of the electrode system.

The technical result is provided by a device for picking up primary measurement information for electrical impedance tomography devices, consisting of two interconnected parts: disposable and reusable. The disposable part of the device consists of a fabric elastic electrode belt with a fixing clasp, non-metallic conductive electrodes, electrode cables of the disposable part. The fabric elastic electrode belt is made of two parts fastened together along the contour, and in the lower part of the belt there are one or more loose sections for the electrode cables of the disposable part to exit from the belt. On the outer side of the first part of the fabric elastic electrode belt, four or more non-metallic conductive electrodes are located and attached at an equal distance from each other, made of a fabric that conducts electric current.

Non-metallic conductive electrodes are electrically connected to the electrode cables of the disposable part, while the electrode cables of the disposable part are attached to the inner side of the first part of the fabric elastic electrode belt with the possibility of stretching the fabric elastic electrode belt in the direction of the long axis under the action of an external force, preventing breakage of the electrode cables.

Electrode cables of the disposable part, emerging from one or more loose sections of the lower part of the belt, are formed into one or more groups, each of which is placed in a thermal shrink tube and forms one or more cables of the disposable part, with the possibility of respectively connecting to one or more input connectors, at a distance sufficient to ensure ease of connection and prevent breakage when attaching a fabric elastic electrode belt to the area of study of a biological object, moreover, the number of electrode cables of the disposable part is equal to the number of non-metallic conductive electrodes.

The second part of the fabric elastic electrode belt protects the electrode cables of the disposable part from damage.

The reusable part of the device contains a cable of the reusable part, formed from electrode cables of the reusable part, located in a thermal shrink tube, a cable spiral entry, a connector for connecting to the EIT device, one or more output connectors. On the one hand, the cable of the reusable part through a cable spiral gland is connected to the connector for connecting to the EIT device, on the other hand, the cable of the reusable part is made with the possibility of forming one or more groups from the electrode cables of the reusable part, each of which is placed in a thermal shrink tube and forms one or more cables of the reusable part, with the possibility of respectively connecting to one or more output connectors, and the number of electrode cables of the reusable part is equal to the number of non-metallic conductive electrodes of the disposable part.

The reusable and disposable parts of the device are interconnected, respectively, by one or more input connectors and one or more output connectors.

The essence of the claimed solution is illustrated in the figures, where in Fig. 1 shows a device for retrieving primary measurement information for EIT systems, with a minimum number of non-metallic conductive electrodes and a minimum number of electrode cables formed into one group, in Fig. 2 shows a device for retrieving primary measurement information for EIT systems, containing more than four non-metallic conductive electrodes and the corresponding number of electrode cables formed into one group, in FIG. 3 shows a device for picking up primary measuring information for EIT systems, containing more than four non-metallic conductive electrodes and a corresponding number of electrode cables formed into more than one group, FIG. 4 shows the location on the patient of the primary measurement information pickup device for EIT systems containing more than four electrode cables formed into one group, in FIG. 5 shows the location on the patient of the primary measurement information pickup device for EIT systems containing more than four electrode cables, formed into more than one group.

The primary measuring information pickup device for electrical impedance tomography devices consists of two interconnected parts: disposable and reusable.

The disposable part of the device consists of a fabric elastic electrode belt 1 with a fixing fastener 2, non-metallic conductive electrodes 3, electrode cables 4 of the disposable part. The fabric elastic electrode belt 1 is made of two parts fastened together along the contour, and in the lower part of the belt there are one or more loose sections 5 for the electrode cables 4 of the disposable part to exit the belt. On the outer side of the first part of the fabric elastic electrode belt 1 at an equal distance from each other are located and attached mechanically, for example, using a thread 6, non-metallic conductive electrodes 3 in the amount of four or more, made of fabric that conducts electric current, for example, carbon (carbon) fabric.

Non-metallic conductive electrodes 3 are electrically connected to the electrode cables 4 of the disposable part using a metallized conductive thread 7, by twisting it with the electrode cables 4 of the disposable part, while the electrode cables 4 of the disposable part are attached by thread 8 to the inside of the first part of the fabric elastic electrode belt 1 with a possibility that provides stretching of the fabric elastic electrode belt 1 in the direction of the long axis under the action of an external force, preventing breakage of the electrode cables.

The electrode cables 4 of the disposable part, emerging from one or more loose sections 5 of the lower part of the belt, are formed into one or more groups, each of which is placed in a thermal shrink tube (not shown in Fig.) and forms one or more cables 9 of the disposable part , with the ability to respectively connect to one or more input connectors 10, at a distance sufficient to ensure ease of connection and prevent breakage when attaching the fabric elastic electrode belt 1 to the area of study of the biological object, and the number of electrode cables 4 of the disposable part is equal to the number of non-metallic conductive electrodes 3 .

The second part of the fabric elastic electrode belt 1 protects the electrode cables 4 of the disposable part from damage.

The reusable part of the device contains a cable 11 of the reusable part, formed from electrode cables 12 of the reusable part, located in a thermal shrink tube (not shown in the figure), a cable spiral entry 13, a connector 14 for connecting to the EIT device, one or more output connectors 15, on the one hand, the cable 11 of the reusable part through the cable spiral gland 13 is connected to the connector 14 for connecting to the EIT device, on the other hand, the cable 11 of the reusable part is configured to form one or more groups from the electrode cables 12 of the reusable part, each of which is placed in a thermal shrink tube (not shown in Fig.) and forms one or more cables 11 of the reusable part, with the possibility of respectively connecting to one or more output connectors 15, and the number of electrode cables 12 of the reusable part is equal to the number of non-metallic conductive electrodes 3 of the disposable part.

The reusable and disposable parts of the device are interconnected, respectively, by one or more input connector 10 and one or more output connector 15.

Consider the operation of the device.

Example of work No. 1 (see Fig. 1): fabric elastic electrode belt 1 of the disposable part of the device for picking up primary measuring information for EIT systems, contains 4 pieces of non-metallic conductive electrodes 3 attached to the fabric elastic electrode belt 1 using thread 6, input connector 10. Non-metallic conductive electrodes 3 are electrically connected to the electrode cables 4 of the disposable part using a metallized conductive thread 7, and the number of electrode cables 4 of the disposable part is equal to the number of non-metallic conductive electrodes 3. The electrode cables 4 of the disposable part are attached to the fabric elastic electrode belt 1 using thread 8, and in the lower part of the fabric elastic electrode belt 1 there is one unfastened section 5 for the electrode cables 4 of the disposable part to exit from it, formed into one group, which is placed in a thermal shrink tube (not shown in Fig.) and forms a cable 9 of a disposable part connected to the input connector 10, and the reusable part contains the output connector 15, the electrode cables 12 of the reusable part in the amount equal to the number of non-metallic conductive electrodes 3 of the disposable part of the device, and the electrode cables 12 of the reusable part are formed into one group, which is placed in a heat shrink tube (in fig. not shown) and forms a cable 11 of the reusable part connected to the output connector 15.

Fabric elastic electrode belt 1 of the disposable part of the primary measuring information pickup device for EIT systems with 4 pieces of non-metallic conductive electrodes 3 is applied to the chest of a biological object and secured with a fixing fastener 2. The disposable part of the device is connected to the reusable part by connecting the input connector 10 to the output connector 15, forming a continuous connection. Next, the primary measurement information pickup device for electrical impedance tomography systems is connected to the EIT device using a connector 14 through a spiral cable gland 13.

The dynamics of obtaining a tomographic slice of the object under study.

To assess the change in the conduction field of a biological object, a current source is connected to a pair of non-metallic conductive electrodes 3 and a low-amplitude high-frequency current is injected, while from the non-metallic conductive electrodes 3, which are not currently injected, primary measurement information is taken (data readout) in the form potential difference, at a fixed position of the current source.

The obtained measurement information is transmitted via the electrode cables 4 of the cable 9 of the disposable part and the electrode cables 12 of the cable 11 of the reusable part through the connector 14 to the EIT device for further processing and visualization of the data.

Next, the current source is connected to the next pair of non-metallic conductive electrodes 3 and data is taken in the form of a potential difference from other non-metallic conductive electrodes 3 that are not currently injected. Such measurements are repeated until the data acquisition process is stopped by the user. The obtained measurement information is transmitted via the electrode cables 4 of the cable 9 of the disposable part and the electrode cables 12 of the cable 11 of the reusable part through the connector 14 to the EIT device for further processing and visualization of data, where the inverse problem of reconstructing the conduction field and visualizing the results in the overlay plane of the primary removal device is solved. measuring information for EIT systems.

Example of work No. 2 (see Fig. 2): fabric elastic electrode belt 1 of the disposable part of the device for picking up primary measuring information for EIT systems, contains 16 pieces of non-metallic conductive electrodes 3 attached to the fabric elastic electrode belt 1 using thread 6, input connector 10. Non-metallic conductive electrodes 3 are electrically connected to the electrode cables 4 of the disposable part using a metallized conductive thread 7, and the number of electrode cables 4 of the disposable part is equal to the number of non-metallic conductive electrodes 3. The electrode cables 4 of the disposable part are attached to the fabric elastic electrode belt 1 using thread 8, and in the lower part of the fabric elastic electrode belt 1 there is one unfastened section 5 for the electrode cables 4 of the disposable part to exit from it, formed into one group, which is placed in a thermal shrink tube (not shown in Fig.) and forms a cable 9 of a disposable part connected to the input connector 10, and the reusable part contains the output connector 15, the electrode cables 12 of the reusable part in the amount equal to the number of non-metallic conductive electrodes 3 of the disposable part of the device, and the electrode cables 12 of the reusable part are formed into one group, which is placed in a heat shrink tube (in fig. not shown) and forms a cable 11 of the reusable part connected to the input connector 15. The fabric elastic electrode belt 1 of the disposable part of the primary measurement information pickup device for EIT systems with 16 pieces of non-metallic conductive electrodes 3 is placed on the chest of the biological object and secured with a fixing fastener 2 The disposable part of the device is connected to the reusable part by attaching the input connector 10 to the output connector 15, forming a continuous connection. Next, the primary measurement information pickup device for electrical impedance tomography systems is connected to the EIT device using a connector 14 through a spiral cable gland 13.

The dynamics of obtaining a tomographic slice of the object under study.

To assess the change in the conduction field of a biological object, a current source is connected to a pair of non-metallic conductive electrodes 3 and a low-amplitude high-frequency current is injected, while from the non-metallic conductive electrodes 3, which are not currently injected, primary measurement information is taken (data readout) in the form potential difference, at a fixed position of the current source.

The obtained measurement information is transmitted via the electrode cables 4 of the cable 9 of the disposable part and the electrode cables 12 of the cable 11 of the reusable part through the connector 14 to the EIT device for further processing and visualization of the data.

Next, the current source is connected to the next pair of non-metallic conductive electrodes 3 and data is taken in the form of a potential difference from other non-metallic conductive electrodes 3 that are not currently injected. Such measurements are repeated until the data acquisition process is stopped by the user. The obtained measurement information is transmitted via the electrode cables 4 of the cable 9 of the disposable part and the electrode cables 12 of the cable 11 of the reusable part through the connector 14 to the EIT device for further processing and visualization of data, where the inverse problem of reconstructing the conduction field and visualizing the results in the overlay plane of the primary removal device is solved. measuring information for EIT systems.

Example of work No. 3 (see Fig. 3): fabric elastic electrode belt 1 of the disposable part of the device for picking up primary measuring information for EIT systems, contains 16 pieces of non-metallic conductive electrodes 3 attached to the fabric elastic electrode belt 1 using thread 6, input connector 10. Non-metallic conductive electrodes 3 are electrically connected to the electrode cables 4 of the disposable part using a metallized conductive thread 7, and the number of electrode cables 4 of the disposable part is equal to the number of non-metallic conductive electrodes 3. The electrode cables 4 of the disposable part are attached to the fabric elastic electrode belt 1 using thread 8, and in the lower part of the fabric elastic electrode belt 1 there are two loose sections 5 for the output of electrode cables 4 of the disposable part, formed into two groups, which are placed in thermal shrink tubes (not shown in Fig.) and form two cables 9 disposable part connected to two input connectors 10, and the reusable part contains two output connectors 15, electrode cables 12 of the reusable part in an amount equal to the number of non-metallic conductive electrodes 3 of the disposable part of the device, and the electrode cables 12 of the reusable part are formed into two groups, which are placed in thermal shrink tubes (Fig. not shown) and form two cables 11 of the reusable part. The fabric elastic electrode belt 1 of the disposable part of the primary measurement information pickup device for EIT systems with 16 pieces of non-metallic conductive electrodes 3 is placed on the chest of the biological object and secured with a fixing fastener 2. The disposable part of the device is connected to the reusable part by attaching two input connectors 10, respectively , to two output connectors 15, forming a continuous connection. Next, the primary measurement information pickup device for electrical impedance tomography systems is connected to the EIT device using a connector 14 through a spiral cable gland 13.

The dynamics of obtaining a tomographic slice of the object under study.

To assess the change in the conduction field of a biological object, a current source is connected to a pair of non-metallic conductive electrodes 3 and a low-amplitude high-frequency current is injected, while from the non-metallic conductive electrodes 3, which are not currently injected, primary measurement information is taken (data readout) in the form potential difference, at a fixed position of the current source.

The obtained measurement information is transmitted via the electrode cables 4 of the cable 9 of the disposable part and the electrode cables 12 of the cable 11 of the reusable part through the connector 14 to the EIT device for further processing and visualization of the data.

Next, the current source is connected to the next pair of non-metallic conductive electrodes 3 and data is taken in the form of a potential difference from other non-metallic conductive electrodes 3 that are not currently injected. Such measurements are repeated until the data acquisition process is stopped by the user. The obtained measurement information is transmitted via the electrode cables 4 of the cable 9 of the disposable part and the electrode cables 12 of the cable 11 of the reusable part through the connector 14 to the EIT device for further processing and visualization of data, where the inverse problem of reconstructing the conduction field and visualizing the results in the overlay plane of the primary removal device is solved. measuring information for EIT systems.

Example of work No. 4 (see Fig. 2): fabric elastic electrode belt 1 of the disposable part of the device for picking up primary measuring information for EIT systems, contains 32 pieces of non-metallic conductive electrodes 3 attached to the fabric elastic electrode belt 1 using thread 6, input connector 10. Non-metallic conductive electrodes 3 are electrically connected to the electrode cables 4 of the disposable part using a metallized conductive thread 7, and the number of electrode cables 4 of the disposable part is equal to the number of non-metallic conductive electrodes 3. The electrode cables 4 of the disposable part are attached to the fabric elastic electrode belt 1 using thread 8, and in the lower part of the fabric elastic electrode belt 1 there is one unfastened section 5 for the electrode cables 4 of the disposable part to exit from it, formed into one group, which is placed in a thermal shrink tube (not shown in Fig.) and forms a cable 9 of a disposable part connected to the input connector 10, and the reusable part contains the output connector 15, the electrode cables 12 of the reusable part in the amount equal to the number of non-metallic conductive electrodes 3 of the disposable part of the device, and the electrode cables 12 of the reusable part are formed into one group, which is placed in a heat shrink tube (in fig. not shown) and forms a cable 11 of the reusable part connected to the input connector 15. The fabric elastic electrode belt 1 of the disposable part of the primary measurement information pickup device for EIT systems with 32 pieces of non-metallic conductive electrodes 3 is applied to the chest of a biological object and secured with a fixing fastener 2 The disposable part of the device is connected to the reusable part by attaching the input connector 10 to the output connector 15, forming a continuous connection. Next, the primary measurement information pickup device for electrical impedance tomography systems is connected to the EIT device using a connector 14 through a spiral cable gland 13.

The dynamics of obtaining a tomographic slice of the object under study.

To assess the change in the conduction field of a biological object, a current source is connected to a pair of non-metallic conductive electrodes 3 and a low-amplitude high-frequency current is injected, while from the non-metallic conductive electrodes 3, which are not currently injected, primary measurement information is taken (data readout) in the form potential difference, at a fixed position of the current source.

The obtained measurement information is transmitted via the electrode cables 4 of the cable 9 of the disposable part and the electrode cables 12 of the cable 11 of the reusable part through the connector 14 to the EIT device for further processing and visualization of the data.

Next, the current source is connected to the next pair of non-metallic conductive electrodes 3 and data is taken in the form of a potential difference from other non-metallic conductive electrodes 3 that are not currently injected. Such measurements are repeated until the data acquisition process is stopped by the user. The obtained measurement information is transmitted via the electrode cables 4 of the cable 9 of the disposable part and the electrode cables 12 of the cable 11 of the reusable part through the connector 14 to the EIT device for further processing and visualization of data, where the inverse problem of reconstructing the conduction field and visualizing the results in the overlay plane of the primary removal device is solved. measuring information for EIT systems.

Example of work No. 5 (see Fig. 3): fabric elastic electrode belt 1 of the disposable part of the device for picking up primary measuring information for EIT systems, contains 32 pieces of non-metallic conductive electrodes 3 attached to the fabric elastic electrode belt 1 using thread 6, input connector 10. Non-metallic conductive electrodes 3 are electrically connected to the electrode cables 4 of the disposable part using a metallized conductive thread 7, and the number of electrode cables 4 of the disposable part is equal to the number of non-metallic conductive electrodes 3. The electrode cables 4 of the disposable part are attached to the fabric elastic electrode belt 1 using thread 8, and in the lower part of the fabric elastic electrode belt 1 there are two loose sections 5 for the output of electrode cables 4 of the disposable part, formed into two groups, which are placed in thermal shrink tubes (not shown in Fig.) and form two cables 9 disposable part connected to two input connectors 10, and the reusable part contains two output connectors 15, electrode cables 12 of the reusable part in an amount equal to the number of non-metallic conductive electrodes 3 of the disposable part of the device, and the electrode cables 12 of the reusable part are formed into two groups, which are placed in thermal shrink tubes (Fig. not shown) and form two cables 11 of the reusable part. The fabric elastic electrode belt 1 of the disposable part of the primary measurement information pickup device for EIT systems with 32 pieces of non-metallic conductive electrodes 3 is placed on the chest of the biological object and secured with a fixing fastener 2. The disposable part of the device is connected to the reusable part by attaching two input connectors 10, respectively , to two output connectors 15, forming a continuous connection. Next, the primary measurement information pickup device for electrical impedance tomography systems is connected to the EIT device using a connector 14 through a spiral cable gland 13.

The dynamics of obtaining a tomographic slice of the object under study.

To assess the change in the conduction field of a biological object, a current source is connected to a pair of non-metallic conductive electrodes 3 and a low-amplitude high-frequency current is injected, while from the non-metallic conductive electrodes 3, which are not currently injected, primary measurement information is taken (data readout) in the form potential difference, at a fixed position of the current source.

The obtained measurement information is transmitted via the electrode cables 4 of the cable 9 of the disposable part and the electrode cables 12 of the cable 11 of the reusable part through the connector 14 to the EIT device for further processing and visualization of the data.

Next, the current source is connected to the next pair of non-metallic conductive electrodes 3 and data is taken in the form of a potential difference from other non-metallic conductive electrodes 3 that are not currently injected. Such measurements are repeated until the data acquisition process is stopped by the user. The obtained measurement information is transmitted via the electrode cables 4 of the cable 9 of the disposable part and the electrode cables 12 of the cable 11 of the reusable part through the connector 14 to the EIT device for further processing and visualization of data, where the inverse problem of reconstructing the conduction field and visualizing the results in the overlay plane of the primary removal device is solved. measuring information for EIT systems.

Based on the primary measurement information obtained using the claimed invention, during the EIT procedure, analysis and visualization of data is performed, carried out by standard electronic units that can be implemented on the basis of a personal computer (PC), with specialized software based on algorithms for processing and constructing two-dimensional images . The PC performs the functions of processing, reconstruction, visualization, archiving, storage and transmission of experimental information.

When using electrodes 3 in the amount of four or more, as well as input connectors 10 of the disposable part in the amount of one or more, output connectors 15 of the reusable part in the amount of one or more, electrode cables 4 coming out of one or more loose sections 5 of the lower part of the belt, formed into one or more groups, each of which is placed in a thermal shrink tube (not shown in Fig.) and forming one or more cables 9 and electrode cables 12 of one or more groups, each of which is placed in a thermal shrink tube (on the Fig. not shown) and forms one or more cables 11, the same technical result is achieved.

Declared technical solution:

- has resistance to artifacts (interference) due to the tight fit of non-metallic conductive electrodes to the biological object, as well as their uniform location due to the tissue electrode belt, which is evenly stretched on the body of the biological object, made of elastic material;

- has ease of maintenance due to the presence of a disposable and reusable part of the device;

- ensures the reliability of fastening to the fabric elastic belt of non-metallic electrodes made of conductive fabric, and also provides ease of use of the device by reducing the overall dimensions of the electrodes;

- reduces the formation of bedsores (wounds) during long-term wearing of the device in clinical practice through the use of materials made of fabric, fabric elastic electrode belt and non-metallic conductive electrodes;

- allows you to ensure sanitary and hygienic standards through the use of a disposable part of the device for removing primary measuring information located on the body of a biological object.

Claims (1)

A device for picking up primary measurement information for electrical impedance tomography devices, consisting of a fabric elastic electrode belt with a fixing clasp, electrode cables, electrodes, characterized in that it consists of disposable and reusable parts connected to each other, moreover, the disposable part consists of a fabric elastic electrode belt with a fixing fastener, electrodes and electrode cables of a disposable part, one or more input connectors, while the electrodes are made of non-metallic conductive, and the fabric elastic electrode belt is made of two parts fastened together along the contour, and one or more loose sections are located in the lower part of the belt to exit the disposable part electrode cables from the belt, on the outer side of the first part of the fabric elastic electrode belt, four or more non-metallic conductive electrodes are located and attached at an equal distance from each other, electrically connected to the electrode cables of the disposable part, while the electrode cables of the disposable part attached to the inner side of the first part of the fabric elastic electrode belt with the possibility of stretching the fabric elastic electrode belt in the direction of the long axis under the action of an external force, the electrode cables of the disposable part extending from one or more loose sections of the lower part of the belt are formed into one or more groups , forming one or more cables of the disposable part, with the possibility of correspondingly connecting to one or more input connectors, wherein the number of electrode cables of the disposable part is equal to the number of non-metallic conductive electrodes, and the reusable part of the device contains a reusable part cable formed from electrode cables of the reusable part, a connector for connection to the EIT device, one or more output connectors, on the one hand, the cable of the reusable part is connected to the connector for connection to the EIT device, on the other hand, the cable of the reusable part is configured to form one or more groups from the electrode cables of the reusable part, each of which forms one or more cables of the reusable part, with the possibility of corresponding connection to one or more output connectors, and the number of electrode cables of the reusable part is equal to the number of non-metallic conductive electrodes of the disposable part, and the reusable and disposable parts are interconnected, respectively, by one or more input connectors and one or more outlets.