RU172071U1 - Device for transmitting biophysiological signals - Google Patents

Abstract

This utility model relates to the field of electrical engineering used in medicine and can be used to transmit electrical signals taken from the body of a biological object (human or animal) to a recording device. A device for transmitting biophysiological signals containing a cable and contacts connected to it, and the cable includes a sheath, inside which the conductors are located, and on its outer side at a distance from each other there are contacts made with the possibility of placing on the surface of the body of the biological object, each contact electrically connected to the corresponding conductor, and the cable sections located between the contacts are made with the possibility of elastic deformation. Effect: increase reliability by reducing tearing forces on the contacts during patient movements. 4 C.p. f-ls, 5 ill.

Description

This utility model relates to the field of electrical engineering used in medicine and can be used to transmit electrical signals taken from the body of a biological object (human or animal) to a recording device.

Known conductor ECG system [US 6891379 B2, "EKG WIRING SYSTEM", G01R 27/04, publ. May 10, 2005], in essence, a device for transmitting biophysiological signals, such as an electrocardiological signal, consisting of a cable and a connector for connecting to a recording device. The cable contains a sheath, inside of which are many coaxial conductors that are electrically connected to the connector. On the outer side of the shell at a distance from each other there are many contacts made with the possibility of placing on the surface of the body of a biological object. The contacts on the body are placed by connecting with electrodes that are attached directly to the skin. Each contact is electrically connected to a corresponding conductor.

This known device is selected as a prototype, as it has the largest number of essential features that match the essential features of the claimed utility model. However, this prototype has a significant drawback, namely, low reliability due to the influence of vibration of the electrodes, and the possible sagging or pulling of the cable sections between the contacts during the movement of the biological object. Vibration of the electrodes creates the so-called "bounce" of the signal, i.e. increased noise and extraneous artifacts in the ECG signal. Noise and artifacts, in turn, can lead to incorrect interpretation of the ECG signal, which can cause diagnostic errors or the need to reject the examination result and repeat it. Cable tension during body movement can lead to separation of the electrodes from the body or cable contacts from the electrodes. Sagging cable allows it to catch on clothes and with further movement also leads to breakage of electrodes or contacts. In addition, it is necessary to select the dimensions of the cable sections between the contacts depending on the size of the patient’s body, which necessitates the use of a large number of cable lengths for biological objects of different sizes (height, weight). It is worth noting the discomfort for the patient due to the need to limit freedom of movement when tensioning cable sections between the electrodes.

In different patients, the body has significantly different sizes, in particular, the distances between the locations of the electrodes in different patients can vary several times. The ideal solution to use an individual cable for each patient in practice is not applied due to the high cost. Therefore, it is necessary to use a cable having an excess length between the electrodes. But this solution has disadvantages. A monitoring cable is used to register biophysiological signals in the course of normal human life. Therefore, freely hanging sections of the cable during movement, during sleep, during physical exertion can lead to vibration of the electrodes, which leads to a deterioration in the quality of the ECG signal due to the appearance of noise and artifacts. A large amount of noise and artifacts degrades the quality of biophysiological signals and can lead to errors and inaccuracies in diagnosis. On the other hand, even if you choose a cable with a length of sections exactly equal to the distance between the installation places (the cable is installed without sagging, which reduces the amount of noise and artifacts), another disadvantage arises. The movement of the chest changes its geometric dimensions, which, when the cable is stretched, can lead to the breakdown of the electrodes and also cause patient discomfort.

The objective of this utility model is to create a new device for transmitting biophysiological cyganals with the achievement of the following technical result: increasing reliability by reducing tearing forces on contacts during patient movements.

The problem is solved due to the fact that in the known device for transmitting biophysiological signals containing a cable and contacts connected to it, the cable includes a sheath, inside which the conductors are located, and on its outer side, contacts made with the ability to place a biological object on the surface of the body, each contact is electrically connected to the corresponding conductor, according to this utility model, cable sections located between the contacts, Execute to elastically deform.

Possible development options for the main technical solution, namely, that

the cable is electrically connected on one side to a connector for connecting it to a recording device;

cable sections located between the contacts are made in the form of a “snake”;

cable sections located between the contacts are made in the form of rings shifted relative to each other;

cable sections located between the contacts are made in the form of a flexible spiral.

Thus, using the totality of the claimed features, it is possible to increase the reliability of the device for transmitting biophysiological signals due to the absence of tearing forces on the contacts during patient movements due to the same tension of the wire between the contacts due to the elastic deformation properties of the cable sections between the contacts. Due to the organization of the cable into elastic forms (snake, spiral, etc.), the number of freely hanging cable sections decreases. This reduces the risk of free areas being caught by clothing, by the patient’s hands, the probability of tearing off the electrodes is reduced, thereby increasing the reliability of monitoring. Cable versatility - the distance between the contacts is automatically adjusted in a wide range of patient torso sizes, so installing the cable on the patient is more convenient and faster and more comfortable for the patient due to freedom of movement due to the stretch of cable sections between the contacts.

The essence of the claimed utility model and the possibility of its practical implementation is illustrated by the description and drawings below.

In FIG. 1 shows a device for transmitting biophysiological signals, cable sections of which are made in the form of a “snake”.

In FIG. 2 shows a device for transmitting biophysiological signals, cable sections of which are made in the form of rings offset from each other.

In FIG. 3 shows a device for transmitting biophysiological signals, cable sections of which are made in the form of a spiral.

In FIG. 4 shows a cross section.

In FIG. 5 shows a device for transmitting biophysiological signals with a microcontroller unit.

The device (Fig. 1-5) for transmitting biophysiological signals contains a cable 1 and contacts 2 connected to it. Cable 1 includes a sheath 3, inside which conductors 4 are located, and on its outer side at a distance from each other there are contacts 2 made with the possibility of placement on the surface of the body of a biological object (not shown in the drawing), each contact 2 is electrically connected to a corresponding conductor 4. The contacts on the body are placed using a connection with electrodes (not shown in the drawing), which are fixed directly to the skin.

A device for transmitting biophysiological signals can be connected to a recording device (not shown in the drawing) via cable 1 directly or using connector 5, to which cable 1 is electrically connected on one side.

In this case, the sections of cable 1 located between the contacts 2 are made with the possibility of elastically deforming and can be a "snake" (Fig. 1), rings displaced relative to each other (Fig. 2) or spiral (Fig. 3). The magnitude of this elastic deformation of cable portions 1 is determined depending on the location parameters of the contacts on the body of the biological object (not shown in the drawing), namely the distance between the points on the body at which contacts 2 should be fixed for correct removal and transmission of biophysiological signals. The length of the conductors 4 is made so that the necessary elastic deformation of the cable 1 does not lead to excessive tearing forces on the electrodes.

In the case where the sections of the cable 1 between the contacts (electrodes) 2 are made in the form of a “snake”, the manufacturing process includes laying the cable 1 in a shape that has grooves corresponding to the final shape of the “snake”, heating the cable 1, for example using a hairdryer, to the thermoplastic state of the sheath, and the cooling of the cable 1. After cooling, the sections of cable 1 retain the shape of a “snake”. The number of “snake” waves and their height in the area between the contacts 2 is determined by the diameter of the cable 1 and the nominal distance between the contacts 2. For example, for the cable section 1 with a diameter of 3 mm and the nominal distance between the contacts 2 30 cm, the number of snake waves can be 7-8 pcs ., the wave height of the snake can be 4-5 cm.

In the case where the sections of the cable 1 between the contacts (electrodes) 2 are made in the form of a flexible spiral, the manufacturing process of the spiral includes winding the cable 1 onto the rod with grooves, heating, for example, a hairdryer, to the state of thermoplasticity, cooling the cable 1, after which the sections of the cable 1 keep the shape of a spiral. The diameter of the spiral and the number of rings are selected depending on the diameter of the cable 1 and the nominal distance between the contacts 2. For example, for cable 1 with a diameter of 3 mm and the nominal distance between the contacts 2 30 cm, the diameter of the spiral can be 2 cm, the number of turns is 15 pcs.

In the case where the sections of the cable 1 between the contacts (electrodes) 2 are made in the form of one or several rings located approximately in the same plane parallel to each other with a shift, the manufacturing process is similar to manufacturing a “snake”, and the shape has grooves in the form of rings. The diameter of the rings and their number are selected depending on the diameter of the cable 1 and the nominal distance between the contacts 2. For example, for the cable section 1 with a diameter of 3 mm and a nominal distance between the contacts of 30 cm, the diameter of the rings can be 5-8 cm, the number of rings is 1-3 pcs . Such “flat” rings less interfere with the patient under clothes and can be attached to the body at individual points with a patch.

Example. When moving, the human body changes its geometric dimensions. For example, when inhaling, the volume of the chest increases, while exhaling, it decreases. When performing various physical exercises, individual muscles tighten and accordingly thicken, while relaxing they decrease in volume. Part of contacts 2 is established on the chest, which, when inhaling / exhaling, significantly changes linear dimensions. If the length of cable 1 between the contacts is exactly equal to the distance between the installation points on the body, then when these body sizes are changed, excessive voltage can lead to the breakdown of contacts 2, which can make a long (daily) recording defective. The cable 1, made in the form of a “snake”, allows the distance between the established contacts to be changed, and due to the elasticity of the “snake”, there are no strong forces at the contact attachment points. By decreasing the distance (for example, when exhaling) due to the springy properties, the “snake” reduces the length of the cable section 1, thereby preventing the cable 1 from sagging between the contacts 2 and the “bounce” of the signal resulting from this, which leads to an increase in the measurement accuracy.

Contacts 2 can be made in the form of electrodes for removing electrical potentials from the surface of the body of a biological object (not shown in the drawing) or in the form of contact attachment devices and electrical connections to electrodes for removing electrical potentials from the surface of the body of a biological object (not shown). The electrodes can be mounted on pneumatic suction cups (not shown in the drawing) or using a self-adhesive layer (not shown in the drawing). Contact fastening devices have a spring element (not shown in the drawing), which is worn on the metal part of the electrode.

Between the sheath 3 and the conductors 4, a common screen 6 can be placed, and each conductor 4 can be placed in an individual screen 7 (Fig. 4). In this case, part or all of the screens 7 can be made of conductive plastic material, for example, carbon-containing polypropylene, carbon-containing polyethylene, carbon-containing polyurethane. An individual screen 7 shunts currents from electrification arising from mechanical stresses on cable 1. In contrast to the used metal screens, a conductive plastic screen 7 reduces the weight of cable 1 and metal consumption, increases flexibility, and reduces the minimum bending radius of the cable. Metal screens are made on top of the insulation of the conductor, usually in the form of a spiral tape winding or in the form of a woven mesh of non-ferrous metals (for example, tinned copper). The use of conductive plastic eliminates the need for non-ferrous metals, thereby reducing the metal consumption of the cable. Having a comparable thickness, the weight of the plastic screen is also less than metal, which reduces the total weight of the cable. A plastic screen made in the form of a tube has less bending stiffness than spiral and wicker screens made of metal, which provides increased cable flexibility, in general, and, accordingly, the ability of the cable to bend without damage with a smaller radius, i.e. the minimum allowable bending radius of the cable is reduced.

At the time of defibrillator discharge, different electrodes located at different points in the patient’s body can have different potentials, which creates an electric current through the cable and through the recording device (recorder). And since the voltage and current strength of the defibrillator discharge are large, the discharge current can lead to the failure of the recording device. Therefore, overvoltage protection elements 8 can be introduced, for example, from a defibrillator discharge, each of which is electrically located between the corresponding conductor 4 and the common shield 6 or between the corresponding conductor 4 and its individual shield 7. Varistors can be used as overvoltage protection elements 8 suppressors, arresters, zener diodes, etc. The connection of the wires of all ECG channels with one common screen 6 or with individual screens 7 protects the ECG recorder from defibrillator discharges as follows. When a defibrillator is discharged, the current path between electrodes with different potentials passes from one electrode through the protection element 8 to the screen 6 of cable 1, then a limited section of the screen 6 passes away from the recorder to another electrode and closes to another electrode through another protection element 8. In this case, the current does not pass through the recording device. High voltage is also not supplied to the input of the recording device. There is an increase in the reliability of the measuring device due to the fact that when a defibrillator is discharged, the recorder connected to it is not exposed to high voltage, which can lead to failure of the recorder.

The inventive cable may contain at least one digital signal channel 9 (Fig. 4) connected to the connector 5 for data transmission, which allows you to connect to cable 1 at least one external digital unit (not shown) or an integrated digital unit 10 (Fig. 5) connected to the digital signal channel 9. This improves the functionality of cable 1, since the external digital unit (not shown in the drawing) and the integrated digital unit 10 represent a digital signal source and can be used as Motion sensor / position sensor, myographic, okulografichesky, pnevmografichesky sensor storage unit. In this case, the built-in digital unit 10 can be located in the connector 5, in the contact housing 2, separately on the conductor connected to the cable 1. Moreover, several digital units can be connected to one digital signal channel 9. The presence of sensors makes it possible to increase the accuracy of diagnostics by adding additional information parameters for assessing the state of a biological object. And the storage device can further improve the operational properties of the cable, since the storage device can contain an individual cable number 1, which allows the recording device to automatically place this number in the resulting record of monitoring results. When processing the recording, the presence of an individual number will allow you to judge the quality of the cable 1, determine the need for repair or replacement. Also, the storage unit may contain information about the number of monitoring cycles that were performed by this cable 1. This number is automatically modified by the registrar with each subsequent cycle. The number of cycles allows you to assess the condition of cable 1 and the degree of its wear, and also to make a forecast of the remaining resource of its work. Since the wear of cable 1 and, accordingly, the deterioration of signal quality occur gradually, this process may not always be obvious to the doctor. The forecast of cable resource 1 by the number of settings allows you to avoid situations of critical cable failure during monitoring and, thereby, the loss of a long (daily, multi-day) recording. The presence of such information in the storage unit makes it possible to automatically transfer it to the resulting monitor, and subsequently automatically process this data in information systems.

The inventive cable is used as follows.

Electrodes for biophysiological signals are placed on the patient’s body. These can be ECG electrodes, rheographic electrodes, holders of a motion / body position sensor, temperature sensor, etc. The arrangement of contacts 2 can be different depending on the purpose of the examination (monitoring), as a rule, the arrangement is determined by the applied medical technique. Placed electrodes through contacts 2 are connected to each other by cable 1, cable 1 is connected to the input of the recorder through connectors or through connector 5, thereby the electrodes and sensors placed on the body are electrically connected to the recorder. After the start of registration, the patient can remain in a medical institution or conduct normal life activities in normal living conditions for a given monitoring period (from several hours to several days). At the end of monitoring, the electrodes and sensors are removed from the patient's body. The information accumulated during the monitoring (recorded biophysiological signals, cable number 1, the number of cycles of its use) is transmitted to the information system for further processing in order to obtain diagnostically significant signs.

Claims (5)

1. A device for transmitting biophysiological signals containing a cable and contacts connected to it, and the cable includes a sheath, inside which the conductors are located, and on its outer side at a distance from each other, contacts are made that can be placed on the surface of the body of a biological object, each contact is electrically connected to a corresponding conductor, characterized in that the cable sections located between the contacts are made elastically deformed. 2. The device according to p. 1, characterized in that the cable on one side is electrically connected to a connector for connecting it to a recording device. 3. The device according to claim 1, characterized in that the cable sections located between the contacts are made in the form of a “snake”. 4. The device according to p. 1, characterized in that the cable sections located between the contacts are made in the form of rings offset from each other. 5. The device according to p. 1, characterized in that the cable sections located between the contacts are made in the form of a flexible spiral.

Images