RU91838U1 - WEARABLE TELECOMMUNICATION COMPLEX OF MONITORING THE FUNCTIONAL STATE OF A HUMAN - Google Patents

Abstract

1. Telecommunication complex for monitoring and diagnosing the functional state of a person, consisting of a measuring module designed to be located on the human body, including nodes for picking up physiological signals and containing electrodes for picking up electrical biopotentials, an emitter and a photodetector for determining the amount of oxygen in the blood, an accelerometer for monitoring motor activity of a person, a cuff with a compressor and a sensor for systolic and diastolic pressures; a processor module consisting of a processor that processes and converts signals, a motherboard used to connect the devices of the measuring module to the processor, a memory card designed to store the processed information; an interface module consisting of a monitor that displays the received information, a keyboard that includes an alarm button, a screen activation button and a device activation button, a headset that performs the function of a human health audio diary and a feedback function with a doctor; a communication module that includes a GSM/GPRS node used to transmit alarm signals, a GPS node that determines the location of a person, a Wi-Fi and a Bluetooth node that transmits the collected information to any other digital device. ! 2. The complex according to claim 1, characterized in that it provides a power supply system from the power grid or other device. ! 3. The complex according to claim 1 or 2, characterized in that it has the function of communication with individual stationary monitors and system units. ! 4. The complex according to claim 1, characterized in that it has an open block-modular archi

Description

The utility model relates to medical equipment, namely to devices for monitoring and functional diagnostics. The utility model can be used for remote monitoring and individual analysis of free motor activity and the activity of the cardiovascular, musculoskeletal and respiratory systems of a person simultaneously according to several physiological parameters, as well as for indication and warning in case of a critical functional state of a person by deviation from the set threshold values.

Known telemetric complex for monitoring and diagnosing the functional state of a person. The telemetric complex includes a transmitting part located on the human body, and a receiving part. The transmitting part includes a series-connected unit for picking up physiological signals, containing electrodes for picking up electric biopotentials, a unit for pre-amplification, a multiplexer, a unit for encoding signals and an infrared unit. The receiving part includes a series-connected photodetector unit, a signal decoding unit, a demultiplexer, and an output information signal generating unit. In this case, the coding unit of the signals of the transmitting part and the decoding unit of the signals of the receiving part are synchronized with each other using the time-pulse modulator and time-pulse demodulator, respectively [1].

The disadvantage of this device is that it does not allow blood pressure measurement, the range of the complex is limited by the line of sight between the node of the infrared sensor and the photodetector.

A device for measuring, controlling and monitoring the physiological state of a person based on a cellular mobile phone, comprising a transceiver unit, a module for entertainment functions, containing ROM and / or extended RAM for storing music or other sound signals, comprises a compression cuff with a built-in primary supercharger, which is connected with a valve with a pressure regulator connected to a pendulum supercharger, a pressure sensor and a pulse wave sensor worn on the pressure source, sensors for a signal and a pulse wave that measures the pressure and pulse of the pressure source are connected to analog-to-digital converters in a cellular mobile phone through a port, analog-to-digital converters are connected to a cellular telephone controller that monitors and compares the measured values with thresholds and, if necessary, issues commands to send a message to the medical center via SMS or in batch form [2].

The disadvantage of this device is that it carries out diagnostics of the functional state of a person only by comparing the values of systolic and diastolic pressure with thresholds, does not contain monitoring and diagnostics of the functional state of human health according to electrocardiogram and oximetry.

A device for diagnosing the functional state of organs and the body as a whole, including an information processing unit, the input-output of which is connected to the memory unit, and the second input to the control unit, the buffer cascade with the current source connected to the first input, the active input to the second input an electrode, the first input of which is connected to the first output of the buffer cascade, and to the second input - an indifferent electrode, an evaluation unit in the form of a personal computer, the input of which is connected through the galvanic isolation unit to the first output of the unit an information processing window, a video controller connected between the second output of the information processing unit and the display, wherein the buffer stage includes matching and conversion elements, characterized in that an average value calculating unit is included between the second output of the buffer stage and the first input of the information processing unit, wherein all incoming blocks, except for the active and indifferent electrodes, the display, and the evaluation unit, are placed in a case made of insulating material of a table type [3].

The disadvantage of this device is that it has a sufficiently large size, which does not allow for round-the-clock diagnostics in a mode that is free for a person, as well as there is no possibility of remote monitoring of a person’s physical activity and alarm notification, there is no function for determining a person’s location.

The closest in functionality to the proposed utility model is a telemetric complex for monitoring and diagnosing the functional state of a person, in particular the state of the cardiovascular system, consisting of a transmitting part, including a module for taking physiological parameters located on the human body, consisting of series-connected electrodes for removal of electrical biopotentials and electrical impedance, pre-amplification unit, signal coding unit and reception part, characterized in that the transmitting part of the complex contains a computing module located on the human hand, which contains a calculator, indicator, keyboard, memory device, blood pressure monitor, access node, and the output of the signal coding unit of the physiological parameters acquisition module is connected to the computing computer serial interface module, indicator, keyboard, storage device, blood pressure monitor, access point connected to the corresponding output I will give the calculator, and the receiving part of the complex comprises a data network, the storage node, processing and visualization of information, wherein the computing unit of the transmitter portion of access node is integrated with a wireless communication network information reception part complex [4].

This complex is selected as a prototype of the proposed solution.

The first drawback of the complex is that it does not allow for oximetric analysis and round-the-clock monitoring of human motor activity, which significantly limits the range of parameters by which it is possible to reliably and with a high degree of individuality analyze the state of human health.

The second drawback is the lack of tools to determine the location of a person, which reduces the possibility of detecting a person and can be difficult to provide a person with the necessary medical care.

The third disadvantage is that there is no system for operational processing of readings and an alarm system when threshold values are exceeded, operating in real time.

The main task that the model aims to solve is to obtain, during stationary, outpatient and free monitoring in real time, a complete set of physiological parameters and characteristics of a person’s functional state in the process of his free physical activity, as well as partial processing of the received information with the generation of alarm signals, determination location of a person, transfer of information for more detailed processing and subsequent qualified medical recommendations with identification possible pathologies.

The technical result of the proposed model is to provide an individual outpatient, stationary and free analysis of the physiological parameters of a person in real time, the threshold values of which are determined by the doctor, with the possibility of subsequent more accurate processing of the information obtained on any available digital devices, and accurate determination of the location of the person, in addition , the system introduces an alarm system that responds to the detection of pathological changes in the human body .

The specified technical result is achieved by the fact that in a utility model, to increase the reliability of the analysis of the state of human health, the arsenal of technical means is expanded for round-the-clock monitoring of the functional state of human health and its motor activity. In order to promptly provide the necessary medical care, a location system has been created based on the GPS module. For a critical alert quick alert system: a fall indicator based on an accelerometer, indicators of a critical change in heart rate and time between R-R 'based on an electrocardiograph, systolic and diastolic pressure based on a tonometer, and a drop in the amount of oxygen in the blood based on an oximeter. For the analysis in free motor mode, the compaction of technical means was used, as well as special miniature wearable wearable bodies. To ensure the availability of information processing and storage, the arsenal of the provided communication protocols of the utility model with any other digital devices has been significantly expanded.

To achieve a technical result, a telecommunication complex is proposed, which, in contrast to the prototype, includes a measuring module 1, a processor module 2, an interface module 3, and a communication module 4 shown in FIG.

The measuring module 1 includes four measuring nodes, in particular:

1) an oximetric measurement unit 5, consisting of an emitter 6 with a photodetector 7, galvanic isolation 8, which performs protective functions, a secondary converter 9 and an interface board 10, which serves to connect to the processor module 2;

2) an electrocardiogram unit 11, containing electrodes for picking up electrical biosignals 12, a galvanic isolation 13 that performs a protective function, as well as a secondary converter 14. Communication with the processor module 2 is also carried out by means of an interface board 15;

3) a blood pressure measuring unit 16, comprising a pump 17 with a pneumatic valve 18 performing a bleed function that fixes a painless cuff 19, as well as a pressure sensor 20, which transmits a signal to the processor module 2 via an interface board 21;

4) a site for measuring free motor activity 22, consisting of an accelerometer 23, giving as an output signal the acceleration values along three mutually orthogonal axes. The signal is transmitted to the processor module 2 using the interface board 24.

In the processor module 2, the received information is processed by the processor 25 from the measuring module 1 and recorded in a memory card 26.

Interface module 3 contains:

1) a touch monitor 27, which displays a set of physiological parameters of a person, and also sets their threshold values;

2) a keyboard 28, consisting of a power button for the device, activation of the touch panel and panic button;

3) the microphone 29, the headphones 30 and the transceiver 31 form a headset that functions as an audio diary of the patient, as well as a feedback function with the attending physician.

Communication module 4 is used to connect to any other digital devices for the purpose of more detailed processing and viewing of all collected information and contains a Bluetooth and Wi-Fi 32 wireless network device, GSM / GPRS 33 module for sending alarm signals to a working medical server, as well as GPS 34 module for determining the exact location of a person.

There is an option in which the cardiograph, oximeter, tonometer, processor and communication module are made in a single wearable case 35, which is mounted on a person’s body in the region of the belt, the electrodes of the cardiograph 36 are mounted in the chest area, the photodetector and emitter of the oximeter 37 are fixed on the index finger human, the accelerometer and headset 38 are mounted in the neck, the cuff 39 is attached to the shoulder of the left hand (figure 2).

There is also an option in which the telecommunication complex has two buildings: 40 and 41. Case 41 contains a cardiograph, microphone, speaker and accelerometer, case 42 contains an ECG ADC, a communication module, a processor module, a compressor, a pressure sensor, a monitor and a keyboard. The electrodes of the cardiograph 43 are attached in the chest area, the photodetector and the emitter 44 of the oximeter are fixed on the index finger of the person, the cuff 45 is attached to the shoulder of the left hand. The housing 40 is mounted in the shoulder region, the housing 41 is mounted in the waist region. Both cases can be interconnected by wireless and wired communication (figure 3).

Telecommunication complex operates as follows.

The processor module sends request signals to the ECG card, accelerometer, tonometer and oximeter. Electrical biosignals from the electrodes, cuff pressure from the pressure sensor, acceleration values from the accelerometer along three mutually orthogonal axes, the amount of oxygen in the blood from the oximeter undergo ADC processing, enter the processor module, where further filtering, processing and preliminary analysis of the signals occur, issuing alarms (automatic or as a result of pressing the panic button located on the case), which are sent via GSM / GPRS together with an indication of the GPS position. Then, the processed information is recorded on a permanent memory card, which can be transferred via USB, Wi-Fi, Bluetooth or CF to any other digital device for individual analysis. To ensure longer operation of the complex, energy-saving modes of operation of the processor and GSM / GPS / GPRS module, as well as a touch screen activation button, are provided.

Literature

1. Patent RU 2175212 C1, cl. A61B 5/04, A61B 5/0205 published on 10.27.2001.

2. Patent RU 82416 U1 class. А61В 5/021, Н04М 1/00 published on 04/27/2009.

3. Patent RU 28432 U1, cl. A61B 5/05, published 03/27/2003.

4. Patent RU 75145 U1, class A61B 5/04, published July 27, 2008.

Claims (5)

1. Telecommunication complex for monitoring and diagnosing the functional state of a person, consisting of a measuring module designed for location on the human body, including nodes for picking up physiological signals and containing electrodes for taking electrical biopotentials, an emitter and a photodetector for determining the amount of oxygen in the blood, an accelerometer for monitoring human motor activity, a cuff with a compressor and a systolic and diastolic pressure sensor; a processor module, consisting of a processor that processes and converts signals, a motherboard used to connect the devices of the measuring module with the processor, a memory card designed to store processed information; an interface module consisting of a monitor on which the received information is displayed, a keyboard including an alarm button, a screen activation button and an activation button for a device, a headset that performs the function of an audio diary of human health and the function of feedback from a doctor; a communication module, including a GSM / GPRS node, used to transmit alarms, a GPS node that determines the location of a person, Wi-Fi and Bluetooth node, transmitting the collected information to any other digital device. 2. The complex according to claim 1, characterized in that it provides a power system from a power grid or other device. 3. The complex according to claim 1 or 2, characterized in that it has a communication function with individual stationary monitors and system units. 4. The complex according to claim 1, characterized in that it has an open block-modular architecture with the possibility of operational layout of measuring, processor, interface, communication modules. 5. The complex according to claim 1 or 4, containing one or more diagnostic devices from the series: glucometer, electroencephalograph, electrogastrograph, electrodermographs, thermometer, reodermograph, electromyograph, heart rate monitor, sphygmomanometer, spirograph, phonocardiograph, phonospirograph, phonogastrograph, electromyoreflexometer, electrodensometer , phonosensometer, audiometer, pressosensometer, thermosensometer, dosimeter, sensor of toxic gases in the environment, capnometer, circulosensometer.