RU2662900C1 - Public defibrillation system terminal - Google Patents

Abstract

FIELD: medicine.SUBSTANCE: invention relates to the medical equipment. Terminal of the public defibrillation system contains the equipment of an automatic external defibrillator (AED) located inside the protective casing. AED equipment is installed in the electrical insulating body of the AED and is equipped with electrodes for defibrillation. Electromechanical lock is integrated in the protective cover and is connected to the output of the lock control unit. Radiocommunication channel with the antenna system is connected with the AED equipment. Antenna system provides the radiation and reception of signals in the megahertz and gigahertz wave bands. Inside the terminal cover there is an uninterruptible power supply unit for the AED and a video surveillance and warning device. Video camera, loudspeaker, viewing screen and external microphone are connected to the outputs of the video surveillance and alert device. In the electrical insulating case of the AED there is a built-in connector, through which the AED equipment is connected to the radio communication channel and the uninterruptible power supply unit of the AED. Radio communication channel is made with two additional inputs/outputs, the first of which is connected to a video surveillance device and an alert, and the second one is connected to a lock control unit. Electromechanical lock is made with a remote door opening terminal of the terminal protective cover, which is connected to the output of the lock control unit.EFFECT: expansion of the range of technical means used to save patients from sudden cardiac arrest in out-of-hospital conditions with the involvement of volunteer non-professionals is achieved.4 cl, 4 dwg

Description

The invention relates to techniques for electric current therapy conducted through contact electrodes using a system for transmitting alarm signals to a central station about the need for immediate electrical defibrillation and the location of the alarm source. The proposed terminal of the system of public defibrillation is a combination of several specified products designed to perform interrelated operational functions, that is, it is a technical solution related to the complex.

As you know, one of the main causes of sudden cardiac arrest (VOS) are diseases of the circulatory system. According to statistics, annually approximately 0.2% of the population of our country dies from fibrillation of the ventricles of the heart and other cardiac pathologies leading to OSI. According to the World Health Organization, 30 deaths due to heart disease per week occur in 1 million people on the planet, half of which are from OSI. Currently, the most effective (of successfully mastered) method of restoring the patient’s normal heart rhythm is to supply a strong electric discharge to his body, which is able to almost immediately suppress the cardiac fibrillation and restore its normal discharge function.

This operation is performed using defibrillators, including automatic external defibrillators (AEDs). These include, for example, portable defibrillators AED of the ALTDEF ^® family (TU 9444-001-14154244-2014) serially produced by the Altonika group of companies. These AEDs automatically detect fibrillation of the ventricles of the heart for a time not exceeding 10-15 seconds. An electrocardiogram (ECG), information about the parameters of the discharges, and ambient sounds are recorded in the AED memory, which allows you to restore the sequence of actions while working with the device. Defibrillators of this type are intended for use both in outpatient and inpatient medical facilities, as well as ambulance teams. A type of voice prompts and graphic display are implemented in the ALTDEF ^® type IDA, which simplifies the operation of the device as much as possible and makes it accessible even to junior medical personnel and an indefinite number of people who are near the victim outside the hospital.

A large statistical database of medical data reliably indicates that the probability of a patient surviving after a heart attack directly depends on the time interval from the onset of the attack to the onset of resuscitation (hereinafter referred to as the response time). According to the European Resuscitation Council (ERC), the threshold response time for ventricular fibrillation is approximately 5 minutes. At the same time, the average response time of an ambulance in an urban environment is currently 4-5 times higher than the indicated value (http://mosgorzdrav.ru/ra).

In principle, two methods are possible to overcome this contradiction.

You can use a faster vehicle than an automobile, for example, an unmanned aerial vehicle, to deliver an AED to a victim of a heart attack. This option is described, for example, in the article "Medical quadrocopter", "Religion, science and life", 11/20/2014. In July this year At the Innoprom exhibition held in Yekaterinburg, the leadership of the Ministry of Industry and Trade and the president of our country demonstrated such a quadrocopter defibrillator developed by the Altonika group of companies and specialists from the Moscow Technological Institute (http://3dnews.ru). The impossibility of the wide practical implementation of this method is associated with the lack of the necessary rules and procedures governing the flights of unmanned aerial vehicles in the airspace of cities.

Another well-known method of reducing response time is the installation of a sufficiently large number of boxes with inside AEDs in places of possible crowding - at stadiums, airports, subways, hypermarkets and even in house entrances. This area is known as the “publicly available (early) defibrillation program.”

The practice of operating "public defibrillation" systems abroad has shown, however, that their main drawback is the problem of patient identification (verification), i.e. confirmation that a person in a critical situation (“fell on the street and lies”) did have an OSI and it is necessary to immediately carry out resuscitation with a defibrillator. In this regard, the statistics obtained in the UK are indicative - in a country in which the crucial importance of “public defibrillation” on the survival rate of people who have experienced OSI is recognized as an element of the state strategy, and research in this direction has been ongoing for more than 15 years. For example, in Hampshire County with a population of 1.76 million people, a retrospective review of all patients who survived after OSI was performed for one year. To establish the fact of using publicly available defibrillators, all emergency calls recorded for the specified period were considered. In addition, an inspection was undertaken of a system consisting of 673 terminals in the form of safety boxes with defibrillators inside, which were located in 278 places in the specified county. As a result, it was found that over the specified period of 1035 emergency calls, the caller reported that he had found the AED installation site only in 44 cases (4.25%) and only in 18 cases (1.74%) - about the successful removal of the AED from the box , in which he was stored, and using it until the ambulance arrived.

It was concluded that, despite the campaigns to raise awareness of the public and organizations about the availability of IDA, the volunteers used the latter only in a scanty number of cases before the ambulance arrived, which practically did not affect the situation with the survival of OSI victims in the prehospital period ( www.scardio.ru/news).

The problem is that in the used protective boxes, in which the AEDs were stored, there was no technical means capable of determining that with a person in a critical situation (“fell on the street and lies”), it is really necessary to immediately carry out resuscitation with a defibrillator. In fact, these boxes were used only as AED storage chambers and were not linked into a single system. At the same time, the AEDs were often inoperative at the right time (due to battery discharge and equipment defects).

At the same time, the European Resuscituation Council (ERC) Recommendations on Resuscitation Activities of the European Resuscitation Council, 3rd edition, edited by the President of the Russian National Resuscitation Council, Corresponding Member of the Russian Academy of Sciences Moroz VV, 2015, are known. which formulate the fundamental requirements for a public defibrillation system According to the document, all rescue measures for a victim in a public defibrillation system should be combined into a so-called "survival chain" consisting of contour in close to real time scale of interrelated actions: “early warning of specialists” - “immediate cardiopulmonary resuscitation (CPR) and automatic defibrillation” - “emergency medical care with the introduction of the necessary cardiotropic drugs.” The terminal of a publicly accessible defibrillation system should be an integral part this chain, which provides the opportunity for remote interaction of medical specialists who are in a remote emergency medical center, and volunteers who find themselves poison to the victims of the BOC. In this case, in any case, the ability of the IDA to fulfill its function of appointment must be guaranteed. The present invention is directed to the satisfaction of the aforementioned ERC requirements.

The idea of the invention is to install in the box used to store the IDA (hereinafter referred to as the IDA terminal) such a complex of technical equipment that would allow to remotely detect a fallen person, quickly notify nearby people about it, identify the condition of the victim and determine his location (by location near landmarks) for the possibility of targeted calling an ambulance.

As you know, such complexes of technical means are used in regional systems of warning and emergency response (RSES) of natural and man-made character. One of them is described, for example, in patent RU No. 2482544, G08B 13/196, H04N 7/18. It includes scanning video cameras with the ability to obtain a circular picture, pan, tilt and zoom, as well as software that allows face control (face recognition) and recognition based on behavioral characteristics in order to assess the behavior of individual subjects in viewing area. The device also includes a hazard detection and recognition unit, a display unit with a viewing screen (screen for visual monitoring), for example, with a flat-panel liquid crystal monitor, one or more hazard detection and / or environmental monitoring sensors combined with a display unit . The device also contains a logical system for processing information from sensors and generating appropriate messages for the public through loud radio broadcasting and display on the display screen, a communication unit connected to a standard network that transmits information related to the detected danger and responds to commands ( instructions) coming from a remote location and causing the display of relevant information. The recorded video information is analyzed and then used to take appropriate security measures, if necessary. This device is housed in a vandal-resistant casing and is an emergency warning column, permanently installed in places of possible crowding.

The main purpose of the device described above is to work as part of a regional emergency warning system (EMERCOM), that is, in the situation prevailing in a certain territory as a result of an accident, natural hazard, catastrophe, natural or other disaster that could entail or entailed numerous casualties. This device is not intended for use as a resuscitation tool to save a specific person who was injured as a result of OSI, however, a number of design solutions used in it can be used to solve the problem described above.

As for the closest analogue of the invention, based on the main function of the purpose of the proposed complex, it is "Portable automated external defibrillator" described in the patent for utility model RU No. 169266, A61N 1/39, as well as in the design and operational documentation of the applicant company , for example, in the "Technical conditions for" Defibrillator automatic small-sized "ALT-DEF", TU 9444-001-14154244-2015, 03/02/2015.

According to the indicated documents, along with the equipment traditional for the AED, which allows performing the resuscitation function, the indicated device also contains a radio communication channel, which allows for the exchange of information between the AED and the remote emergency care unit in the gigahertz (GHz) and megahertz (MHz) wavelength ranges. This feature of this AND model is a prerequisite for using it as the closest analogue of the alleged invention.

The closest analogue contains a control unit and a high voltage unit connected to each other, including a power source equipped with a generated energy control unit and two current buses, between which a high-voltage defibrillation pulse generating unit is connected, therapeutic buses connecting the high-voltage outputs of the high-voltage unit with defibrillation electrodes as well as built-in microphone, speaker, graphic display. At the same time, the control unit contains a programmable microcontroller with an ECG module through which communication with the high-voltage defibrillation pulse generating unit and with the memory unit is carried out. The video output of the programmable microcontroller is connected to the graphic display input, the communication outputs of the programmable microcontroller are connected to the radio communication channel, and one of the control outputs is connected to the input of the generated energy control unit. The microphone is connected to the audio input of the programmable microcontroller, the audio output of which is connected to the speaker. The video output of the programmable microcontroller is connected to the input of the graphic display.

All the aforementioned AED structural elements are housed in a case that is convenient for carrying and made of lightweight electrical insulating material, such as plastic, and provide the possibility of autonomous use of the AED as a portable resuscitation device. During storage and transportation, the AEDs are placed in a protective casing from which it can be easily removed for use for its intended purpose. For the use of AEDs in community-based conditions in places of possible crowding, this device is placed in a vandal-resistant safety casing (box, cabinet, etc.) marked with the corresponding distinctive marking and equipped with an electromechanical lock (vademec.ru/news/2018/01/17, cardi-on.ru) for protection against unauthorized entry. However, when trying to use the closest analogue as a terminal for a system of publicly available defibrillation, the same disadvantages appear that were identified by the example of practical results of using the geographically distributed network of AED boxes in the UK (www.scardio.ru/news).

The results of the analysis of these shortcomings formed the basis of the aforementioned 3rd edition of the “ERC Recommendations for Resuscitation Activities”, which implies the main requirements for the AED terminal of the system of public defibrillation, as an integral part of the survival chain. They are as follows:

- providing automatic detection of the fact of a person falling at a place of crowding;

- Attracting to the person lying the attention of people around them to "force" them to provide first aid;

- Establishment of a remote exchange of information between volunteers and a specialist located in the emergency room, immediate dispatch of an emergency vehicle to the scene of the accident;

- providing automatic admission of the volunteer to the IDA (the possibility of prompt removal of the device from the protective casing and autonomous use);

- Absolute guarantees of the performance of the AED (battery charge, absence of defects in the nodes of the device);

- legal protection of volunteers in case of an adverse outcome of resuscitation measures.

In the arsenal of existing means of medical (resuscitation) purpose, there are no such terminals yet. The technical problem solved by the present invention consists, therefore, in expanding the arsenal of technical means used to save patients from OSI in an out-of-hospital setting with the involvement of lay volunteers, and the expected technical result consists in realizing this purpose.

To achieve the specified technical result, in the closest analogue containing the AED equipment located inside the protective casing, installed in a portable electrical insulating casing and equipped with defibrillation electrodes, an electromechanical lock built into the protective casing, and also a radio communication channel connected to the AED equipment with an antenna system providing radiation and receiving signals in the GHz and MHz wave bands, an uninterruptible power supply unit and a video surveillance and warning device are installed, to the output with which cameras, a loudspeaker, a viewing screen and an external microphone are connected, and a detachable connector is built into the AED housing, through which the AED equipment is connected to a radio communication channel and an uninterruptible power supply unit, while the lock control unit is configured to remotely control it using a radio communication channel, while the radio communication channel is made with two additional inputs / outputs, the first of which is connected to a video surveillance and notification device, and the second to a bl lock control eye.

Alternatively, the AED equipment contains an ECG module and a memory unit associated with a programmable microcontroller, as well as a high voltage unit configured to connect through a built-in socket for defibrillation electrodes. In addition, a microphone, speaker and graphic display are integrated into the AED housing, while the audio input and audio output of the programmable microcontroller are connected, respectively, to the microphone and speaker, and the video output of the programmable microcontroller is connected to the graphic display input, the ECG module is connected between the measurement input / output of the unit high voltage and measuring output / input of a programmable microcontroller, the control output of which is connected to the control input of the high voltage unit, while nye inputs / outputs and inputs / outputs programmable power management microcontroller connected to the appropriate terminals detachable connector.

Alternatively, the video surveillance and notification device includes a video processor unit, the input of which is connected to the output of the video monitoring unit, configured to receive a video stream from video cameras and transmit commands to control video cameras to connect, rotate and focus, as well as a loud notification unit, the output of which is connected to a loudspeaker , a display unit, the output of which is connected to the viewing screen, an external microphone and a logical system, the first input / output of which is a communication input / output ohm of the video surveillance and notification device, which serves to communicate with the first additional output / input of the radio communication channel, the second input is connected to the output of the video processor unit, the third input is connected to an external microphone, and the second, third and fourth outputs are connected, respectively, to the control input of the video surveillance unit and with the inputs, respectively, of the loud warning unit and the display unit, the outputs of which are the outputs of the video surveillance and notification device, serving to connect, respectively, loudly govoritelya and viewing screen.

Alternatively, the radio communication channel contains an antenna system connected to a block of radio modems of standard networks (Wi-Fi, GSM / GPRS, Internet) and with a narrow-band transceiver of the GHz and MHz wave bands, as well as an interface configured to exchange information with a video surveillance and notification device , lock control unit and detachable connector.

The essence of the proposed technical solution is illustrated by the drawings shown in FIG. fourteen.

In FIG. 1 is a structural diagram of the considered terminal of a public defibrillation system.

In FIG. 2 shows a block diagram of a possible embodiment of an AND apparatus.

In FIG. 3 shows a block diagram of a possible embodiment of a video surveillance and warning device.

In FIG. 4 shows a block diagram of a possible embodiment of a radio communication channel.

The following notation is used in the drawings: 1 - AED equipment; 2 - AED building; 3 - video surveillance device and alerts; 4 - lock control unit; 5 - radio communication channel; 6 - uninterruptible power supply unit AED; 7 - a protective casing; 8 - detachable connector; 9 - video cameras; 10 - video surveillance unit; 11 - a block of video processors; 12 - logical system; 13 - interface; 14 - a block of radio modems of standard networks (Wi-Fi, GSM / GPRS, Internet); 15 - narrowband MHz transceiver band in; 16 - antenna system; 17 - loud warning unit; 18 - loudspeaker; 19 is a display unit; 20 - viewing screen; 21 - an external microphone; 22 - programmable microcontroller; 23 - block high voltage; 24 - speaker; 25 - electrodes for defibrillation; 26 - socket electrodes; 27 - ECG module; 28 - memory block; 29 - graphic display; 30 - microphone AED; 31 - electromechanical lock.

The considered terminal of the public defibrillation system contains (Fig. 1) the AED equipment 1 located inside the protective casing 7 and installed in the portable electrical insulating casing 2 of the AED, an electromechanical lock 31 connected to the output of the lock control unit 4 and connected to the apparatus 1 AED is a radio communication channel 5 with antenna system 16, which provides radiation and reception of signals in the GHz and MHz wavelength ranges. Inside the protective casing 7, an AED uninterruptible power supply unit 6 and a video surveillance and notification device 3 are also installed, the input of which is connected to an external microphone 21, and the outputs with the inputs of the video camera 9, loudspeaker 18 and viewing screen 20, and a detachable connector 8 is built into the housing 2 of the AED through which the AED equipment 1 is connected to the radio communication channel 5 and the uninterruptible power supply unit 6, while the radio communication channel 5 is made with two additional inputs / outputs, the first of which is connected to the output / input of the device va 3 surveillance and alarm systems, and the second - with output / input unit 4 lock control.

Shown in FIG. 2, the option of constructing the apparatus 1 of the AED includes a programmable microcontroller 22 and a high voltage block 23, configured to connect to it through a socket 26 of electrodes integrated into the casing 2 of the AED electrodes 25 for defibrillation, as well as a speaker 24 integrated into the casing 2 of the AED, microphone 30 AED and graphic display 29. AED equipment 1 also contains an ECG module 27 and a memory unit 28 associated with a programmable microcontroller 22, the audio input and output of which are connected, respectively, to the AED microphone 30 and speaker 24, and the video output d is connected to the input of the graphic display 29. In this case, the ECG module 27 is connected between the measuring input / output of the high voltage unit 23 and the measuring output / input of the programmable microcontroller 22, the additional input / output of which is connected by the output / input of the memory unit 28. The control output of the programmable microcontroller 22 is connected to the control input of the high voltage unit 23. The communication inputs / outputs and inputs / outputs of the power control of the programmable microcontroller 22 are connected to the corresponding contacts of the connector 8.

Shown in FIG. 3, a design diagram of a video surveillance and notification device 3 comprises a video surveillance unit 10 configured to receive a video stream from video cameras 9 and transmit commands to control these cameras to connect, rotate and focus to these video cameras, as well as video processor unit 11, a public address unit 17, the output of which is connected to the loudspeaker 18, a display unit 19, the output of which is connected to the viewing screen 20, an external microphone 21 and a logical system 12, the first input / output of which is a communication input / output video surveillance and warning devices 3, used to communicate with the first additional output / input of the radio communication channel 5, the second input is connected to the output of the video processor unit 11, an external microphone 21 is connected to the third input, and the second, third and fourth outputs are connected, respectively, to the control input video surveillance unit 10 and with inputs, respectively, of the speakerphone 17 and the display unit 19, the outputs of which are the outputs of the device, serving to connect, respectively, the loudspeaker 18 and Touch screen 20.

Shown in FIG. 4, the construction option of the radio communication channel 5 comprises an antenna system 16 connected to a block 14 of standard network radio modems (Wi-Fi, GSM / GPRS, Internet) and a narrow-band transceiver of 15 megahertz ranges, which are connected to an interface 13 configured for two-way information exchange with the device CCTV and alerts, 4 control lock and plug connector 8.

A part of the terminal elements integrated into the AED housing 2 (speaker 24, an electrode socket 26, a graphic display 29 and an AED microphone 30) and a part of the equipment elements located inside the AED (high voltage block 23, ECG module 27 and memory block 28) are standard equipment defibrillator "ALTDEF ^® ", commercially available by the applicant. The features of the terminal in comparison with the specified serial AED are the following:

1 Added detachable connector 8, which is built into the plastic housing 2 of the AED so that it is possible to quickly disconnect the equipment 1 of the AED from other terminal elements located inside the protective casing 7, for the purpose of subsequent autonomous use of the equipment 1 of the AED for its intended purpose (as a resuscitation appliance).

2 The radio communication channel 5 is installed not inside the AED housing 2, but inside the protective casing 7. At the same time, the antenna system 16 is mounted in the specified protective casing 7 to allow free reception and emission of radio signals in the GHz and MHz wavelength ranges. The narrow-band transceiver of the 15 MHz range is implemented in accordance with RU patent No. 2216463 used in the security alarm systems RS-202, Concierge and others (www.altonika.ru). Radio networks of standard networks are used in public radio networks - Wi-Fi, GSM / GPRS and Internet.

A video surveillance and notification device 3 included in the terminal under consideration, comprising a video surveillance unit 10 connected to video cameras 9, a video processor unit 11, a public address unit 17 with a speaker 18, a display unit 19 with a viewing screen 20 and an external microphone 21 are standard elements of the terminals used in RSChS, including as part of the device described in the aforementioned patent for invention RU No. 2482544.

Thus, all the components of the proposed terminal of a system of publicly available defibrillation can be implemented using already used in practice structural units available on the electronic market, therefore, the industrial applicability of the claimed complex is beyond doubt.

The considered terminal of the system of public defibrillation (Fig. 1) is a complex consisting of information and executive parts designed to perform interrelated operational functions for implementing the above-described concept of public defibrillation. The indicated complex plays a connecting role in the "survival chain" between medical specialists and volunteers who accidentally find themselves next to a person who has suffered from OSI.

This role is implemented using the following sequence of operations.

In the standby mode of operation of the complex, its components - the executive link - hardware 1 AED located inside the housing 2 AED (Fig. 2), and the information part, which includes the device 3 video surveillance and notification (Fig. 3), block 4 control lock , the radio communication channel 5 (Fig. 4) and the uninterruptible power supply unit 6 of the AED, from which the AED equipment 1 is supplied in this mode and its battery is recharged (not shown in the drawings), are inside the camera formed by a vandal-resistant protective casing 7, yuschimsya outer sheath terminal. The shape and design features of this shell depend on the intended installation location of the terminal. The specified shell may be in the form of a box or column, designed for installation and operation in street conditions or inside such geographically distributed objects as the subway, railway station, airport, etc. The strength of the material selected for the manufacture of the protective casing 7, the type of fastening and the degree of its resistance to mechanical and climatic influences depend on the specific installation site or suspension of the terminal. The connection of the equipment 1 of the AED with other parts of the complex located inside the protective casing 7 is provided using a detachable connector 8, one part of which is built into the casing 2 of the AED, and the other is inside the protective casing 7.

In the response mode, one part of the detachable connector 8 is separated from the other, the AED equipment 1 is removed from the internal chamber and used offline for its intended purpose - to resuscitate a victim of OSI by passing a high voltage current through his heart. Power supply of equipment 1 of the AED is carried out autonomously at this stage - from its own battery.

In standby mode, the device 3 video surveillance and alerts (Fig. 3) using cameras 9 provides a panoramic image of a given area. The video stream from the output of the video surveillance unit 10 enters the video processor unit 11, in which the images are pre-processed by compressing the frequency band and converting it to the format necessary for subsequent transmission via radio communication channel 5 to the remote terminals - to the situation center and / or to the control panels of various services , including on the emergency medical console.

In block 11 of video processors, video analytics algorithms are used to detect various anomalies in the behavior of people, for example, falling detector video detector algorithms used in CCTV systems - CCTV ("Video analytics: face recognition, queue detector, search for objects on video) ", 02.21.2017, geektimes, ru). When automatically capturing a person’s fall using the video processor unit 11, the corresponding image frame is marked, for example, outlined with a circular marker and, together with the images of adjacent sections of the video control zone, is sent to the corresponding input of the logical system 12, which sends these images to the input of the radio communication channel 5 (Fig. . four). This video signal is fed to the corresponding input of interface 13, which converts it to the standard communication network format in the coverage area of which this terminal is located (for example, to the Wi-Fi network format) or to the format used by the 15 MHz narrowband transceiver and using the antenna system 16 is being broadcast.

This signal is received by the equipment of the remote emergency medical emergency call desk and displayed on its monitor, which allows the console operator to monitor the situation in the coverage area of this terminal and to timely record changes in this area, for example, to record a person’s fall.

When the operator fixes the remote control of a person’s fall, the console generates and sends the control signal of video cameras 9 of this terminal to the air. Details of the operation of the emergency medical console are not disclosed in this application, since the remote is an external device in relation to the complex under consideration and, accordingly, is not directly related to the subject of the invention.

The control signal of the video cameras 9 received using the antenna system 16 of the radio communication channel 5 through the block 14 of standard network radio modems or a narrow-band transceiver of the 15 MHz band and interface 13 is transmitted to the input of the logical system 12 and, further, to the control input of the video surveillance unit 10, which generates the corresponding control command video cameras 9. This signal is used to automatically aim this video camera 9 at the place where the victim fell and to autofocus it. The panel operator analyzes this improved image for the presence of signs of BOC in the victim (see above) and, if he suspects that he has this terminal state, generates and transmits an alarm message through radio communication channel 5 that carries an emergency text notification and information about the victim’s approximate location. This message is received by the standard radio unit 14 of the standard networks or by a narrow-band transceiver of the 15 MHz range and, via the interface 13, is fed to the communication input of the logical system 12. This system generates a corresponding text notification, which is sent to the public address unit 17 and broadcast by the loudspeaker 18 (voice announcement), and also through the display unit 19 is displayed on the screen 20 (visual alert).

As a result, the terminal simultaneously sounds a loud notification about the need for first aid to the victim, which is duplicated by the corresponding text that appears on screen 20. This notification allows people around the affected person to assess the situation, and one or more volunteers to begin providing first aid to the victim under remote control by the operator of the emergency medical console. Thus, using the terminal, the first link of the aforementioned "survival chain" is implemented.

People who are close to the victim should quickly assess the condition of the victim, first of all, whether he has consciousness, is breathing normally, and then immediately inform the operator of the emergency medical console. Volunteers and the emergency room dispatcher should suspect cardiac arrest in any patient with seizures and carefully evaluate whether such a patient is breathing normally. If the victim does not have consciousness and normal breathing, then this means that the victim has OSI that requires immediate application of CPR procedures and automatic external defibrillation. In this case, one of the volunteers starts the CPR procedure, and the other volunteer runs up to the terminal and, using the external microphone 21 integrated in his protective casing 7, reports this to the emergency medical operator, reports his name and waits for the terminal door to open automatically. to get access to the equipment 1 And. The face image of this volunteer falls into the field of view of one of the video cameras 9 connected to the video surveillance unit 10. The video signal with the image of the volunteer’s face is sequentially transmitted through the video processor unit 11, the logical system 12, and the radio communication channel 5 to the emergency medical console and recorded in it for the purpose of further monitoring the actions of the volunteers during their emergency assistance to the victim. The operator of the remote control sends a command via radio communication channel 5 to ensure that the volunteer has access to the AED equipment 1 located in the terminal’s inner chamber. This command through the radio communication channel 5 and the corresponding pin of the connector 8 is supplied to the device 1 of the AED - to the communication input of the programmable microcontroller 22, which converts it into a command to open the door of the protective casing 7 of the terminal to provide the volunteer with access to the equipment 1 of the AED. This command from the output of the programmable microcontroller 22 through a plug-in connector 8 and through a radio-controlled channel 5 is fed to the input of the lock control unit 4. The electromechanical lock 31 is triggered and the door in the protective casing 7 of the terminal opens, after which the volunteer removes the equipment 1 AND from the shelf of the inner chamber of the terminal. Further, he disconnects the AED equipment 1 using a detachable connector 8 from the remaining inside the protective casing 7 of the terminal of the AED uninterruptible power supply unit 6 and the radio communication channel 5, after which it delivers the AED equipment 1 to the victim.

From this moment, the device 1 of the IDA goes into autonomous mode of work under the control of a volunteer and performs the executive function of the complex to restore the heart rhythm of the victim. A high degree of readiness of the AED equipment 1 for autonomous operation is guaranteed, due to the fact that in the standby mode of the terminal, the AED equipment 1 was constantly connected to the radio communication channel 5, which allowed its remote testing, as well as to the uninterruptible power supply unit 6 of the AED, which allowed automatic recharging of the battery AND, which is part of the high voltage unit 23 (not shown in Fig. 4).

The automatic external defibrillation mode is implemented, further, as follows.

Initially, a volunteer carries out preparatory operations:

1. Turns on the defibrillator by pressing the power key and, following the voice instructions recorded in the device 1 AND, transmitted through the speaker 24 built into the case 2 of the AED, puts defibrillation electrodes 25 on the victim’s chest and connects them through the socket 26 of the electrodes built into the case 2 of the AED, for of which:

- frees the victim’s chest from clothes,

- opens the bag with disposable electrodes 25 for defibrillation, following the instructions on the package packaging,

- makes sure that the adhesive on the surface of these defibrillation electrodes 25 is not dry, and the upper protective surface, wire and connection connectors are not damaged,

- applies electrodes 25 for defibrillation to the chest of the victim and inserts the plug of the electrodes into the socket 26.

The device 1 of the AED immediately after switching on independently using the data entering the programmable microcontroller 22 from the ECG of module 27 and the memory unit 28, analyzes the victim's ECG and, if it detects ventricular fibrillation, prepares for defibrillation discharge.

With the correct connection of the electrodes 25 for defibrillation, the analysis of the heart rhythm automatically starts and the corresponding message sounds from the speaker 24.

If ventricular fibrillation is not detected, then the volunteer will be asked to conduct a CPR again within one to two minutes. On the graphic display 29, the time remaining until the end of CPR will appear. If ventricular fibrillation is detected, then the device 1 AND immediately proceeds to the procedure of energy storage. To confirm the intention to carry out a defibrillation discharge, the volunteer presses and holds the discharge key. If it is found that ventricular fibrillation has disappeared and the heart rhythm is detected, then internal self-discharge will occur, and the device 1 AND will again go into rhythm analysis mode. After the end of the defibrillation discharge, the AED equipment 1, using the speaker 24 and the graphic display 29, reports that the discharge has been completed and will suggest that the volunteer perform the CPR procedure again within one to two minutes. After a repeated CPR cycle, the rhythm analysis cycle is repeated and, if necessary, a repeated defibrillation discharge cycle is performed. Turning off the equipment 1 AED at the end of the work is done automatically.

During the described resuscitation procedure, the IDA microphone 30 remains on, with which, under the control of the programmable microcontroller 22, the conversations of people near the victim are recorded in the memory unit 28 for subsequent decryption and documentation of the entire procedure.

After completing the resuscitation procedure described above, volunteers return the AED equipment 1 to its storage location in the terminal, connect the AED equipment 1 using a connector 8 to the radio communication channel 5 and to the uninterruptible power supply unit 6 of the AED, and then close the door of the protective casing 7. the electromechanical lock 31 is activated, controlling access to the AED equipment 1 from the outside, and the terminal returns to standby mode. At the same time, volunteers remain next to the victim and await the arrival of an ambulance. The arrived doctor introduces cardiotropic drugs to the victim and delivers him to the nearest hospital. This concludes the third phase of the implementation of the aforementioned “survival chain”.

Thus, the "survival chain" is implemented in full, which indicates the achievement of the expected technical result of the invention, which consists in expanding the arsenal of resuscitation drugs used to save the victim from a sudden heart attack in a community-acquired environment.

Claims (4)

1. The terminal of a public defibrillation system, comprising automatic external defibrillator (AED) equipment located inside the protective casing, installed in the AED insulating casing and equipped with defibrillation electrodes, an electromechanical lock integrated into the protective casing connected to the output of the lock control unit, and also connected to the equipment AED is a radio communication channel with an antenna system that provides radiation and reception of signals in the megahertz and gigahertz wave bands, characterized by the fact that inside the protective casing there is installed an uninterruptible power supply unit for the AED and a video surveillance and notification device, the outputs of which are connected to video cameras, a speaker, a viewing screen and an external microphone, and a detachable connector is built into the electrical insulation housing of the AED through which the AED equipment is connected to the radio communication channel and unit uninterruptible power supply of the AED, while the radio communication channel is made with two additional inputs / outputs, the first of which is connected to a video surveillance device alerts, and the second - a lock control unit, wherein the electromechanical lock is configured with an input terminal for remote opening of the protective housing of the door, which is connected to the output of the lock control unit. 2. The terminal according to claim 1, characterized in that the AED equipment contains a programmable microcontroller, an ECG module, a memory unit and a high voltage unit, configured to connect defibrillation electrodes to it through the electrode socket built into the AED insulating casing, as well as built-in the insulating housing of the AED microphone, AED microphone, speaker and graphic display, while the audio input and audio output of the programmable microcontroller are connected respectively to the AED microphone and speaker, and the video output is connected to by the graphic display, the ECG module is connected between the measurement input / output of the high voltage unit and the measurement output / input of the programmable microcontroller connected to the memory unit, and the control output of the programmable microcontroller is connected to the control input of the high voltage unit, while the communication inputs / outputs and inputs / Programmable microcontroller power control outputs are connected to the corresponding pins of the plug connector. 3. The terminal according to claim 1, characterized in that the video surveillance and notification device comprises a video monitoring unit configured to receive a video stream from video cameras and transmit commands for controlling their connection, rotation and focusing to video cameras, as well as a video processor unit, a public address unit, a unit mappings and a logical system, the first input / output of which is a communication input / output of a video surveillance and notification device, used to communicate with the first additional output / input of a radio communication channel, the second input is connected to the output of the video processor unit, the third input is an input for connecting an external microphone, and the second, third and fourth outputs are connected respectively to the control input of the video surveillance unit and to the inputs of the public address unit and display unit, the outputs of which are device outputs CCTV and alerts, which serve to connect the speaker and viewing screen, respectively. 4. The terminal according to claim 1, characterized in that the radio communication channel contains an antenna system connected to a block of radio modems of standard networks (Wi-Fi, GSM / GPRS, Internet) and a narrow-band megahertz transceiver, the inputs / outputs of which are connected to the interface, made with the possibility of exchanging information with a video surveillance and warning device, a lock control unit and a detachable connector.

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