RU101347U1 - LIFE-IMPORTANT HEALTH CARE CONTROL SYSTEM AND EMERGENCY ASSISTANCE TO THE PATIENT - Google Patents

Abstract

 1. A system for monitoring vital health indicators and emergency care for a patient, comprising a cardiac monitoring sensor, a respiratory activity monitoring sensor, a hemodynamic monitoring sensor, a data water unit, a central computer, characterized in that it additionally contains a microprocessor, at least one mobile communication network GSM, supporting the transmission of a GPRS data packet (Generl Pacret Radio Service), as well as any positioning function in the PRCE (Positioning RadioCoordinating Function) radio system; motion control sensor; at least two GPRS modems designed for voice and data packet transmission; multi-channel microcontroller; information display display; no less than two mobile phones; a database; moreover, the sensors for monitoring cardiac activity, respiratory activity, hemodynamics and motor activity, the data input unit are connected respectively to the first, second, third, fourth and fifth inputs of the multi-channel microcontroller, the input / output of the microprocessor is connected to the first input-output of the microcontroller, and to the second input-output the microcontroller is connected to the input-output of the information display display, the input-output of the first GPRS modem is connected to the third input-output of the microcontroller; moreover, the set of all sensors for monitoring the activity and activity of the patient, the microprocessor, the data input unit, the multi-channel microcontroller, the first GPRS modem and the information display display is a mobile patient kit; the combination of at least one mobile phone and / or GPRS modem forms a mobile communications kit; input-output of the central

Description

The utility model relates to the areas of medical diagnostics, devices for rescuing people who are in a state of “imaginary death”, as well as signaling and determining the location of a patient using signals transmitted via mobile wireless communication networks to a medical emergency call center and / or to a confidential mobile receiver the patient. The utility model can be used for dynamic mobile monitoring and control of the physiological state of the body under medical supervision (patients), single elderly people, drivers of vehicles, representatives of special and rescue services and other interested people, as well as for search and rescue of people in helpless condition.

A device for continuous monitoring of the activity of the heart (USSR patent No. 1814538, AB 5/04).

The known device includes electrodes fixed to the surface of the human body, the cardiosignals from which, after passing through the preamplifier, enter the microprocessor, in which the recorded signal is constantly compared with the upper and lower maximum permissible levels set for a particular patient, taking into account the characteristics of the state of the cardiovascular systems of this patient. When the value of the recorded signal deviates from the set maximum permissible values, an adjustable threshold unit is activated, which includes an audible alarm unit, as well as a magnetic recording unit that records the pathological process. The disadvantages of this type of device include the fact that they can be used to assess the state of cardiac activity without taking into account the individual retrospective history of the subject under stationary conditions.

The well-known telemedicine complex for remote monitoring of human health (RF patent No. 94832 А61В 5/00) containing a personal interactive user module, which is a portable microprocessor device consisting of a microprocessor with a permanent and random access memory and a graphic indicator connected to it, a digital functional keyboard, a clock real time, and a self-powered timer, a radio interface port, a prima-transmission module over a cellular communication network, as well as a module for measuring physiological parameters connected to a personal interactive user module via a radio channel through a radio interface port, a signal bracelet, which is a small-sized device consisting of a microprocessor controller with built-in memory and a timer for sound and vibration indicators, an emergency call button for medical assistance, a GPS receiver and port of the radio interface for communication with a personal interactive user module and a doctor’s smartphone, The personal interactive user module and the doctor’s smartphone are connected by cellular mobile communication channels to a data reception and transmission server and a complex management server. In this complex, the GLONASS receiver can be used in the signal bracelet, and additional diagnostic equipment can be connected via the wireless access port. The disadvantage of the complex can be considered the lack of feedback from the impact of the doctor on the patient's condition, which excludes the possibility of providing assistance in a critical situation. In addition, the presence of a GPS navigation receiver, as follows from its purpose, makes it impossible to determine the location of the patient in enclosed spaces, in urban canyons, underpasses, subways, etc.

The closest technical solution to the claimed one is a system for monitoring the state and restoration of vital (vital) human body (RF patent No. 2378983, АВВ 5/025, A61N 1/00), containing a series-connected block of sensors for monitoring cardiac activity, a sensor switch, a network interference compensator , an analog-to-digital converter, a controller, one of the inputs / outputs of which is connected to a read-only memory, one output is connected to a sensor switch, the second output is connected to a digital-to-analog converter Atel a digital channel and a computer, a block of sensors for monitoring cardiac activity is made in the form of a set of sensors for monitoring electrophysiological signals of cardiac activity, a data input unit; hemodynamic and vascular resuscitation control unit; a respiratory activity monitoring sensor, a gas composition monitoring sensor, connected, respectively, to the second, third and fourth inputs of the sensor switch; execution switch; a heart resuscitation unit, a respiratory resuscitation unit, an alarm unit connected to the outputs of the performance switch; video camera; a switch connected to the input of the respiratory activity monitoring sensor, a switch connected to the output of the cardiac monitoring sensor unit and to the input of the sensor switch, a switch connected to the output of the cardiopulmonary resuscitation unit, a switch connected to the output of the respiratory resuscitation unit, respiratory activity measuring electrodes connected through the switch to the input of the respiratory activity monitoring sensor, cardiopulmonary resuscitation electrodes connected through the switch to the output of the serum unit echnoy resuscitation, respiratory resuscitation electrodes are connected via a switch to the output unit respiratory resuscitation; a controller based on a software-logic integrated circuit with the ability to calculate the parameter values of the signals coming from the output of the sensor switch and determine their compliance with the specified intervals contained in the read-only memory, as well as with the possibility of generating, when the parameter value matches, the signal coming from the output sensor switch, at least one given interval that determines the predictor or terminal state of the controlled functions of the body, - coma to turn on the alarm unit and the camera’s turn-on command, and if the value of the signal parameter coming from the output of the sensor switch matches at least one specified interval that determines the terminal state of the organism’s controlled functions, and if there is an enable signal at the control unit’s output, the commands switching a switch connected to the input of the respiratory activity monitoring sensor and a switch connected to the output of the cardiac monitoring sensor unit and to the input of the sensor switch, in the mode of breaking the electric connection, and also in accordance with the sequence given by the enabling signal, - the command to switch the switch connected to the output of the cardiac resuscitation unit to the mode of breaking or connecting the electric communication with the simultaneous command of switching the switch connected to the output respiratory resuscitation unit, respectively, in the mode of connection or rupture of electric communication, as well as in accordance with the command parameters systematic way unit cardiac resuscitation unit respiratory resuscitation control unit hemodynamic and vascular resuscitation, and to generate a signal which describes the process of operation of the system; the execution switch is connected to the controller output based on the program-logic integrated circuit, to the output of the digital-to-analog converter, to the input of the network noise compensator, to the input of the hemodynamics and vascular resuscitation control unit; A computer is connected to the input-output of the controller on the basis of a program-logic integrated circuit and is connected through a digital channel to a central computer, to the input of which a control unit is connected; the video camera is connected to the input of the computer and is configured to record and transmit images in the presence of an input command; each of the switches is connected to the controller outputs on the basis of a program-logic integrated circuit and operates in the modes of connection or disconnection of electrical communication; wherein the digital channel is a telephone or fiber optic connection; the data input unit is configured to generate signals, at least one of which corresponds to a given access code to the data set contained in read-only memory; a permanent storage device contains a data set in the form of specified intervals of parameter values that determine the normal, predictive, terminal states of the controlled vital functions of the human body, taking into account its retrospective history; the hemodynamics and vascular resuscitation control unit contains at least two electrodes facing the human body with a medicinal substance deposited on their surface and is configured to generate an electrical voltage proportional to the electrical impedance of the biological tissue, and with the possibility of generating an output signal with a frequency of 27 MHz and power changed by an external signal in the range from 5 to 100 W; the respiratory activity monitoring sensor is configured to generate a magnitude of electrical voltage proportional to the magnitude of the perceived external pressure; the sensor for monitoring the gas composition of the air is configured to measure the values of the acoustic impedance of the air at two predetermined points and generate a voltage signal proportional to the difference in the measured values; the signaling unit is configured to generate audio and / or visual signals if there is an enable command at the input; the heart resuscitation unit is configured to generate an output controlled short-term high-voltage electrical signal up to 4 kV; the respiratory resuscitation unit is configured to generate an output sinusoidal signal with a frequency of 10 kHz, modulated by amplitude with a controlled modulation frequency of 0.12-0.33 Hz and a duty cycle of 1: 1, 2: 1, 1: 2; the control unit is configured to generate an enable signal that specifies the sequence of the controller's instructions for switching the switch connected to the output of the cardiopulmonary resuscitation unit and the switch connected to the output of the respiratory resuscitation unit in the electrical connection mode and setting the parameters of the output signals generated by the hemodynamic control unit and vascular resuscitation, cardiac resuscitation unit, respiratory resuscitation unit. The possible additional presence in the wireless communication system (radio channel) will allow, without reducing the degree of system responsiveness, to monitor a person in a place that does not have a wired connection and is remote from the head of the central computer (for example, at home, in a patient).

The disadvantage of the prototype is the inability to control vital health indicators and the location of people during their movement, that is, for example, outside a medical hospital place of residence or other building and provide them with quick remote consultation or assistance by emergency medical response authorities. In this case, an alarm about the onset of a critical state of the body can be perceived only by those who are in close proximity to the alarm unit. In addition, almost all elderly people, especially those who are lonely to one degree or another, are sick and need dynamic monitoring and control by outsiders. In the event of a sudden sharp complication of the state of health or death of such people during their movement (on foot or in transport), it is impossible to determine in time not only the reason, but the time and place where the complication occurred, and therefore promptly provide them with emergency medical assistance or notify the confidential ( proxy, family members, acquaintances, or guardian, heirs [4], etc.). At the same time, there are often nearby witnesses who do not have a medical education, who cannot correctly respond to a sudden deterioration in human health and provide the necessary first aid.

The objective of the claimed utility model is to provide quick remote medical consultation or assistance by emergency medical response bodies to people at risk and medical surveillance, located outside the hospital and in the access area of cellular communication systems with a deterioration in the basic vital indicators of their health, as well as timely notifications to family members, relatives, or people around about a sudden crisis (or death) of people, including the place and time of the incident.

This object is achieved in that the monitoring system of vital health indicators and providing emergency care to the patient, comprising a heart rate monitoring sensor, a respiratory activity monitoring sensor, a hemodynamic monitoring sensor, a data water unit, a central computer according to the invention further comprises a microprocessor, at least one network mobile (cellular) GSM communications supporting the transmission of a GPRS data packet (Generl Pacret Radio Service), as well as any positioning function in the PRCE (Positioning RadioCoordinating F unction); motion control sensor; at least two GPRS modems designed for voice and data packet transmission; multi-channel microcontroller; information display display; no less than two mobile phones; a database; moreover, the sensors for monitoring cardiac activity, respiratory activity, hemodynamics, and motor activity, the data input unit is connected respectively to the first, second, third, fourth and fifth inputs of the multichannel microcontroller, the microprocessor input-output is connected to the first input-output of the microcontroller, and the second input is the output of the microcontroller is connected to the input-output of the information display display, the input-output of the first GPRS modem is connected to the third input-output of the microcontroller; moreover, the set of all sensors for monitoring the activity and activity of the patient, the microprocessor, the data input unit, the multi-channel microcontroller, the first GPRS modem and the information display display, is a mobile patient kit; the combination of at least one mobile phone and / or GPRS modem form a mobile communications kit; the input-output of the central computer is connected to the input-output of the GPRS modem of the mobile communication kit; all GPRS modems and mobile phones work in the coverage area of at least one GSM mobile communication network; moreover, to the central computer and one of the mobile phones of the communication kit there is the possibility of multi-channel access to the personnel of the point of duty of the medical assistance service; the database contains an anamnesis, passport data, as well as contact information with the patient's confidant; high-speed communication is established between the database and the host computer; patient's confidential is equipped with a mobile communication kit.

In addition, there is the possibility of multichannel access for the personnel of the duty medical service on-site to a central computer and one of the mobile phones of the communication kit.

The database contains an anamnesis, passport data, as well as contact information with the patient's confidant.

The first GPRS modem is mounted at such a distance from the organs of hearing and speech that the patient can conduct verbal exchanges in speakerphone mode.

In the case of registration of threshold indicators of the state of health, the microprocessor generates a warning signal, which is a text and speech message that provides current indications of the patient’s health status, recommendations to the patient on reducing the likelihood of complications and transition critical state, a request to determine the patient’s location, and the signal the warning is intended for the patient himself, the point of medical care on duty and the patient’s authorized confid a, and is sent automatically via the transmission channels of the GPRS information packet, and the transmission of voice or text information of the GSM mobile communication, and if the operator of the emergency medical service call points confirms the presence of threshold signs, he contacts the patient and gives him recommendations to prevent the transition of basic health indicators in critical condition, clarifies the patient’s location, including via the location channel in the PRCE radio system, and in the absence of communication with the patient, the operator of the duty station the medical care service contacts the patient's confidant and notifies him of the need to pay attention to the patient according to one or another threshold indication of the vital health monitoring system.

If one of the current indications of the state of health corresponds to critical, then the microprocessor generates an alarm signal that includes a text message that displays the current indications of the patient’s health status, his passport data, contact number of the confidential, a request for determining the patient’s location, the alarm is intended for the point of duty of the medical care service, an authorized patient confidant and is sent automatically via the transmission channels of the information packet G PRS, and the transmission of voice or text information of GSM mobile communication, and when an alarm is received, the operator of the medical care duty service calls the database and requests personal data of the patient, compares the current critical health indicators with the local or attending physicians recorded in the database and making sure of the onset of a critical state, it determines the patient’s location using the location channel in the PRCE radio system and sends a car to the patient’s location the ambulance service, while he makes an attempt to communicate through the speakerphone of the first GPRS modem of the patient with possible witnesses of the onset of the terminal state of the patient and, in case of contact with the witnesses, the operator of the emergency medical service, clarifies the location of the patient for faster guidance of the ambulance medical assistance to the patient, consults witnesses regarding measures to provide assistance to the patient and sends a text message via cellular communication channels to the confidential ienta about immediate relief to the patient the need to arrive at your patient evacuation.

A diagram clarifying the principle of the system is shown in figure 1 and figure 2.

Figure 1 presents a structural diagram of a system for monitoring vital health indicators and providing emergency care to a patient.

In figure 2. presents a block diagram of the sets of mobile equipment of the system.

The monitoring system of vital health indicators and emergency care for the patient (figure 1) includes a mobile patient kit 1; a GSM 2 mobile (cellular) communication network with GPRS (Generl Pacret Radio Service) information packet transmission channels, 3 positioning in the PRCE (Positioning RadioCoordinating Function) 4 radio system [6], and voice or text information transmission 5; a point of duty medical care service 6, equipped with multi-channel access to a central computer 7 and ambulances; database 8; mobile communication kit 9; authorized patient confid 10.

The mobile kit (Fig. 2) of patient 1 contains: sensors for monitoring cardiac activity 11, respiratory activity 12, hemodynamics 13, motor activity 14, data input unit 15, multi-channel microcontroller 16, microprocessor 17, information display 18, first GPRS 19 modem moreover, the sensors for monitoring cardiac activity 11, respiratory activity 12, hemodynamics 13, motor activity 14, as well as the data input unit 15 are connected respectively to the first, second, third, fourth and fifth inputs of the multi-channel microcontrol Lera 16, and the microprocessor 17, the information display 18, and the first GPRS 19 modem are connected respectively to the first, second and third input-output of the multi-channel microcontroller 16. Moreover, all devices 11-15 and 17-19 are connected respectively to the inputs and inputs - multi-channel microcontroller outputs through flexible elongated adapters.

Mobile communication kit 9 contains: at least one mobile phone 20 and / or one GPRS modem 21. A single mobile communication network 2 allows you to organize the transmission channels of the GPRS 3 information packet, determine the location of the patient in the PRCE (Positioning RadioCoordinating Function) 4, and transmit voice or textual information 5 between the mobile kit of patient 1, and the mobile communication kits 9 of Confident 10 and the emergency medical service on-call point 6. Between the mobile communication kit 9 of the emergency medical center 6 and the central second computer 7 arranged multichannel packet exchange 3, a coordinate 4, 5, speech and text information. Between the central computer 7 and the database 8, a high-speed data channel 22 is established, which can be either wired or wireless.

The microprocessor 17 performs the following functions:

1. the conversion of the values of the electrical signals of the sensors 11-14 in the measured indications of the health status (cardiac, respiratory, hemodynamic and motor activity) of the patient in the form of a text and speech message;

2. preliminary recording and storage of indications of the state of health corresponding to the normal, threshold and critical (predictor or terminal) conditions of the patient. Record is carried out by the attending or local doctors at;

3. comparing pre-recorded indications of the patient’s health status with current

4. The formation of a warning signal in the event that one of the current health status indications approaches threshold values.

5. the formation of an alarm if one of the current health status indications corresponds to critical (terminal or predictive);

The microprocessor can be made on the basis of RISC architecture [1]. RISC (Reduced Instruction Set Computer - a computer with a reduced set of instructions). The RISC architecture command set included only the basic elementary microoperations, which made it possible to unify the format of the instructions of the computational core, simplify the design, and reduce the cost of manufacturing computational cores. One example of a 32-bit RISC embedded microprocessor architecture is Motorola's PowerPC microprocessor. Microprocessors of this family are designed to build on their basis personal computers and servers, high-speed telecommunication equipment, systems based on GPS signal processing, for use in robotics and other applications that primarily require high performance and large amounts of memory from the processor. The key point of the PowerPC architecture is the possibility of parallel execution of commands due to the presence of several (from 3 to 11) actuators working in parallel, among which there is a block for performing floating-point operations. The presence of an ADC capable of interrogating up to 64 channels and several timer coprocessors allows controlling with dozens of channels with minimal involvement of the central processor. Such capabilities may be useful in robotics, systems of complex production control systems, fingerprint recognition due to the large amount of internal memory, high computing power and low power consumption.

The data input unit performs the following functions:

1. patient authentication by entering an individual code (password) and / or biometric data (fingerprints, iris, for example);

2. Introduction of preliminary data by the attending or district doctors;

3. Record of passport and contact details of the patient, including the confidential.

The multi-channel microcontroller 16 performs the following functions:

1. collection of analog signals from control sensors 11-14;

2. analog-to-digital conversion of signals of control sensors 11-14;

3. transmission of control commands from the data input unit 15 to the microprocessor 17;

4. transmission of warning and alarm signals to the first GPRS 16 modem;

5. blocking the operation of the mobile patient kit in the absence of a patient identification command from the data input unit 15;

6. control over the transmission of the signal flow between all devices connected to the microcontroller;

7. multiplexing and preparing data for exchange between devices connected to a multi-channel microcontroller;

8. determination of the parameters of the data transmission channel and determination of possible gaps in the data exchange channels.

A multi-channel microcontroller can be made on the basis of a family of 32-bit microcontrollers, the core of which are M-CORE cores [1]. The M-CORE 32-bit RISC core is designed for use in portable industrial and medical equipment, digital cameras, GPS systems and other portable applications that use battery power and require a processor with 32-bit resolution, on the one hand, and on the other - low consumption. Thanks to the built-in FLASH and SRAM memory blocks, the microcontrollers of the M-CORE family can work in a single-chip version, i.e. without additional external nodes, which is also important for portable applications.

The GPRS modem can be made on the basis of the Siemens model line. Siemens produces a wide range of GPRS modems [3]. Modems are available in the form of embedded modules and as complete devices adapted for operation as part of ACS systems. The TS35 Terminal and MC35 Terminal modems (Fig. 2) support almost all the functions of a regular cell phone, with the only difference being that control is not from the keyboard, but via the RS232 interface. Further development of the MC35 model additionally has the ability to work in the GPRS format (packet data transmission in cellular networks) and voice exchange. The command system is compatible with the standard Hayes command set, however, it has a number of additional commands for controlling GSM and GPRS parameters. Siemens MC35 Terminal GPRS modems allow you to create automation systems for remote autonomous objects that maintain constant communication with the control center.

As a motion control sensor, you can use the multifunctional actigraph SOMNOwatch by SOMNOmedics [5]. SOMNOwatch can be used for actigraphy when monitoring circadian rhythm, detecting periodic limb movement (MPC), perform Tremor analysis, conduct single-channel ECG or EEG recordings, monitor body temperature, respiratory screening with flow / snoring, body position, and sleep / cycle analysis wakefulness.

General characteristics:

- Measurements: Programmable start of registration and duration, up to 20 measurements are included;

- Patient interface: up to 9 different patient markers and LCD status indicator;

- Data synchronization: simultaneous use of two or more SOMNOwatch recorders with synchronized analysis;

- Data export: program files - ASCII, EDF format, reports - Excel, Word, PDF format;

- Patient database (option):

7 channels:

- 6 internal (body position, 3 activity sensors (X, Y, Z), ambient light sensor, patient button);

- 1 external (for connecting the sensor).

The operation of the system is as follows.

Previously, before applying the monitoring system of vital health indicators and providing emergency assistance to the patient, the following group of patient data is entered into the microprocessor database and memory on the basis of voluntary consent:

1. according to the measurement data of sensors 11-14, the parameters that determine the functional and physiological state of the patient, namely “normal”, “threshold” or “critical” (predictor or terminal), in which are controlled functions of the body in processes related to each other, data from a retrospective history, other manifestations of a physiological state (short-term memory loss, for example). These data are entered by the local or attending physician.

2. passport data;

3. contact numbers and addresses of authorized confidants (family members, neighbors, guardians, etc.).

Only authorized services of the unified dispatch duty service, including the duty medical care service, have access to the database 6.

An agreement is concluded between the operator of the GSM mobile network 2, the emergency medical service call point 6, and the patient on the provision of services via the transmission channels of the GPRS 3 information package, location in the PRCE 4 radio system, as well as text and voice messages 5 in case of a critical condition of the patient according to one of the indicators of the sensors 11, 12, 13, 14. The mobile kit 1 is fixed on the patient’s body in such a way as not to cause cramping and impeding movement. At the same time, the first GPRS 19 modem is mounted at such a distance from the organs of hearing and speech so that the patient can conduct a voice exchange without using his hands in speakerphone mode. The current parameters recorded by the sensors 11-14, through the microcontroller 16 enter the microprocessor 17.

A text message can be displayed on the information display 18, the mobile phone 20 of the mobile communication set 9, as well as the monitor of the central computer 7, and the voice message can be transmitted by the first GPRS 19 modem, as well as the mobile phone 20 and the GPRS 21 modem of the mobile communication set.

Under normal health conditions, text and voice messages are intended for the current informing of the patient himself through the information display 18 and the first GPRS 19 modem, respectively. In this case, the reproduction of current indicators on the information display 18 is carried out upon request from the data input unit 15.

The warning signal is a text and speech message that provides current indications of the patient’s health status, recommendations to the patient to reduce the likelihood of complications and transition critical condition, a request to determine the location of the patient. The warning signal is intended for the patient himself, the operator of the emergency medical service call point 6 and the authorized patient confidant 10. The warning signal is sent automatically via the transmission channels of the GPRS information packet (Generl Pacret Radio Service) 3, and the transmission of voice or text information 5 of the GSM 2 mobile communication through the first GPRS 19 modem. Upon receipt of a warning signal, the operator of the medical emergency call center 6 contacts the database and requests the patient’s personal data, compares the current x threshold data recorded precinct or the attending physician in the database. In case of detection of threshold signs, it contacts the patient and gives him recommendations on preventing the transition of the main health indicators to a critical state. In the absence of communication with the patient, the operator of the medical emergency call center 6: determines the patient’s location using the positioning channel in the PRCE (Positioning RadioCoordinating Function) 4 system, contacts the patient’s confidant 10 and notifies him of the need to pay attention to the patient threshold indications of the monitoring system of vital health indicators. In the absence of communication with the confidential, the ambulance carriage is sent to the patient, at the place of his last stay.

The alarm signal includes a text message that provides current indications of the patient’s health status, his passport data, confidant's contact phone number, and a request for determining the patient’s location.

The alarm signal is intended for the emergency medical service duty point 6 of the authorized patient confid 10. The warning signal of the first GPRS 19 modem is automatically sent through the transmission channels of the GPRS information packet (Generl Pacret Radio Service) 3, and the transmission of voice or text information 5 of the GSM 2 mobile communication network . Upon receipt of an alarm, the operator of the medical emergency call center 6 accesses the database and requests the patient’s personal data, compares the current critical readings with those recorded in AZE data precinct or the attending physician. After ascertaining the approach (or occurrence) of a critical state, it determines the patient’s location using the positioning channel in the PRCE radio system (Positioning RadioCoordinating Function) 4. Sends an ambulance to the patient’s place of residence. Attempts to communicate through the speakerphone of the first GPRS 19 patient modem with possible witnesses of the onset of the terminal state of the patient. In the event of entering into contact with witnesses, the operator of the medical emergency call center 6 clarifies the location of the patient for faster guidance of the ambulance to the patient, advises witnesses on measures to assist the patient. Sends a text message via cellular communication channels to the patient's confidential about the urgent care of the patient and the need to arrive at the patient's evacuation site.

Claims (6)

1. A system for monitoring vital health indicators and emergency care for a patient, comprising a cardiac monitoring sensor, a respiratory activity monitoring sensor, a hemodynamic monitoring sensor, a data water unit, a central computer, characterized in that it additionally contains a microprocessor, at least one mobile communication network GSM, supporting the transmission of a GPRS data packet (Generl Pacret Radio Service), as well as any positioning function in the PRCE (Positioning RadioCoordinating Function) radio system; motion control sensor; at least two GPRS modems designed for voice and data packet transmission; multi-channel microcontroller; information display display; no less than two mobile phones; a database; moreover, the sensors for monitoring cardiac activity, respiratory activity, hemodynamics and motor activity, the data input unit are connected respectively to the first, second, third, fourth and fifth inputs of the multi-channel microcontroller, the input / output of the microprocessor is connected to the first input-output of the microcontroller, and to the second input-output the microcontroller is connected to the input-output of the information display display, the input-output of the first GPRS modem is connected to the third input-output of the microcontroller; moreover, the set of all sensors for monitoring the activity and activity of the patient, the microprocessor, the data input unit, the multi-channel microcontroller, the first GPRS modem and the information display display is a mobile patient kit; the combination of at least one mobile phone and / or GPRS modem forms a mobile communications kit; the input-output of the central computer is connected to the input-output of the GPRS modem of the mobile communication kit; all GPRS modems and mobile telephones operate in the coverage area of at least one GSM mobile communications network between the database and the host computer high-speed communication is established; patient's confidential is equipped with a mobile communication kit. 2. The system for monitoring vital health indicators and emergency care for a patient according to claim 1, characterized in that there is the possibility of multichannel access to the personnel of the emergency medical service on-site computer and one of the mobile phones of the communication kit. 3. The system for monitoring vital health indicators and providing emergency assistance to a patient according to claim 1, characterized in that the database contains an anamnesis, passport data, as well as contact information with the patient's confidant. 4. The monitoring system of vital health indicators and emergency care for the patient according to claim 1, characterized in that the first GPRS modem is mounted at such a distance from the hearing and speaking organs that the patient can conduct a verbal exchange in loud-speaking mode. 5. The system for monitoring vital health indicators and emergency care for a patient according to claim 1, characterized in that in the case of registration of threshold indicators of a state of health, the microprocessor generates a warning signal, which is a text and speech message that provides current readings of the patient’s health status , recommendations for the patient to reduce the likelihood of complications and transition to a critical state, a request to determine the location of the patient, and a warning signal waiting time is intended for the patient himself, the emergency medical service duty point and the authorized patient confid, and is sent automatically via the GPRS information packet transmission channels and the transmission of voice or text information of GSM mobile communication, and if the operator of the medical emergency duty service confirms the presence of threshold signs, he contacts the patient and gives him recommendations to prevent the transition of basic health indicators to a critical state, clarifies the location of the patient, including after and through the location channel in the PRCE radio system, and in the absence of communication with the patient, the operator of the medical care duty service point contacts the patient's confidant and notifies him of the need to pay attention to the patient according to certain threshold indications of the vital health monitoring system. 6. The system for monitoring vital health indicators and providing emergency care to a patient according to claim 1, characterized in that if one of the current health status indications is critical, the microprocessor generates an alarm signal that includes a text message in which current indications of the patient’s state of health, his passport data, confidant’s contact number, a request for determining the patient’s location, while the alarm is intended for the medical emergency call center of medical assistance, an authorized patient confidant, and is sent automatically via the transmission channels of the GPRS information packet and the transmission of voice or text information of GSM mobile communication, and upon receipt of an alarm, the operator of the emergency medical service call points to the database and requests the patient’s personal data, compares the current critical health indicators with the district or attending physicians recorded in the database, and making sure of the onset of a critical condition, determines the month the patient’s location through the positioning channel in the PRCE radio system and sends an ambulance to the patient’s place of residence, while he makes an attempt to communicate through the speakerphone of the first GPRS modem of the patient with possible witnesses of the onset of the terminal state of the patient, and if the operator contacts the witnesses point of the emergency medical service on duty clarifies the location of the patient for faster guidance of the ambulance to the patient, consults It provides information on measures to provide assistance to the patient and sends a text message via cellular communication channels to the patient's confidential about urgent care for the patient, the need to arrive at the patient's evacuation site.