RU187157U1 - Personal telemedicine device for remote monitoring of vital functions of the body of patients at risk - Google Patents

Abstract

The utility model relates to medical equipment and can be used as an instrument unit of a wearable medical diagnostic complex. The required technical result, which consists in expanding the arsenal of technical means used as a personal telemedicine device for remote monitoring of vital functions of the body of patients at risk, as well as increasing the reliability of its functioning and reducing the possibility of false alarms is achieved in a device containing a pulse measurement channel, a removal channel electrocardiograms, channel for measuring the patient’s body temperature, channel for measuring blood pressure, channel for measuring measuring respiratory rate and a channel for measuring oxygen content in the blood, a display for visual display of measurement information, a module for processing and analyzing measurement signals, an alarm reset button, an alarm delay timer and a key whose signal input is connected to the alarm output of the signal processing and analysis module measurements. 1 ill.

Description

The utility model relates to medical equipment and can be used as an instrument unit of a wearable medical diagnostic complex.

Known software and hardware unit that is part of the telemedicine diagnostic system "Distance Doc 2" [RU 125368, Ul, G06Q 50/00, 02/27/2013], which includes a receiver module for streaming audio and video, demultiplexer, video decompressor, audio decompressor , an output video interface, an analog audio output interface and a network interface that is connected to a local medical computer network, and the output is connected via a streaming audio / video receiver module to a demultiplexer, the outputs of the demultiplexer are connected to a video decompressor y, the output of which is connected to a monitor through the video output interface, and to an audio decompressor, the output of which is connected to the analog audio interface.

The disadvantage of this device is its relatively high complexity.

There is also known a transceiver [RU 110946, U1, АВВ 5/00, 12/10/2011] made with the possibility of automatically receiving and transmitting files with digital data to the server upon the moment of supply and removal of power from the devices, data buffering in case of a break connection and automatic retransmission of data until the server confirms its integrity, while the transceiver consists of a hardware module for storing and transmitting data in an Ethernet or GSM network to a data collection server and wireless modules for transmitting data from the instrument in to the hardware module, and the transceiver is made in the form of a portable module with the ability to place on the patient’s body and transmit data via the GPRS channel of the GSM network through the channels of at least two GSM network operators.

The disadvantage of this device is also relatively large complexity.

In addition, the instrument unit is known [RU 93655, Ul, АВВ 5/00, 05/10/2010], made in the form of a module for recording biomedical signals, which is part of the wearable "telemedicine diagnostic kit, connected to the base unit of the kit via a wireless data channel and intended for recording biomedical signals such as an electrocardiogram, body temperature and photoplethysmogram (PPG), which is a graphical recording of the pulse based on the determination of the optical properties of tissue in the light spectrum λ = 68 0 nm, while the data is digitized and digitally transmitted to the base unit of the wearable telemedicine diagnostic kit via the Bluetooth protocol for subsequent analysis and visualization.

This instrument unit, made in the form of a module for recording biomedical signals, allows you to quickly and fairly reliably assess the condition of the patient by analyzing objective recorded indicators, but it has the following disadvantages.

One of them is the relatively narrow functionality, since they are limited to recording only the electrocardiogram, body temperature and pulse. However, data on the parameters of respiration and blood pressure are also essential for an array of diagnostic data, especially during procedures and manipulations that are not recorded in the known technical solution.

In addition, the existing functionality of the known technical solution does not provide visual control of the parameters and their possible exceeding the permissible limits directly during the procedures and manipulations in rooms not equipped with receiving telemedicine equipment, as well as by the patient himself outside the treatment and treatment rooms. And the need to transfer data to receiving telemedicine means for their decryption reduces the speed and efficiency of data visualization.

The closest in technical essence to the proposed is the instrument unit of a wearable medical diagnostic complex [RU 172819, Ul, А61В 5/01, А61В 5/0205, А61 В 5/021, А61В 5/024, А61В 5/0402, А61В 5/145 , G08B 21/02, 07/25/2017] containing a pulse measurement channel, an electrocardiogram recording channel, a patient’s body temperature measuring channel, a blood pressure measuring channel, a respiratory rate measuring channel, and a blood oxygen measuring channel that are capable of receiving signals from corresponding sensors placed on the body of the pats entent, and the formation of output signals in digital form for subsequent analysis, as well as a display for visual display of measurement information and a processing and analysis module for measurement signals, the inputs of which are connected to the outputs of the channels for measuring pulse, taking an electrocardiogram, measuring body temperature, measuring blood pressure, measuring respiratory rate and measurement of oxygen content in the blood, and the output is connected to the input of the display, moreover, the module for processing and analysis of measurement signals is configured to generating output signals of the channels for measuring pulse, taking an electrocardiogram, measuring body temperature, measuring blood pressure, measuring respiratory rate and measuring the oxygen content in the blood into video signals for display on the display in the form of the results of current measurements with the possibility of highlighting the color of results that are outside the permissible limits and forming an audible alarm when exceeding the permissible limits, while the instrument unit of the wearable medical diagnostic complex is made in the housing, equipped with fastening means on the patient’s body, and the display is placed on its lateral surface with the ability to visualize the results of current measurements displayed on it.

A feature of the closest technical solution is that it is equipped with light and / or sound alarms, which can be triggered when the measurement results exceed the permissible limits, as well as a wi-fi controller, configured to transfer the results of current measurements to external devices for subsequent analysis and visualization.

The disadvantage of the closest technical solution is the relatively low reliability of operation, since in practice there are often false alarms of sensors, spontaneous short-term output of measured values beyond specified limits, disconnection of sensors from cables or cables from the measuring device, temporary removal of a personal telemedicine system by a patient, and other similar events.

If the patient’s remote monitoring system is used within the hospital, then the medical staff can understand in real time the causes of the emergency and either eliminate it or take immediate measures to help the patient.

If the patient is out of direct contact with medical workers (at home, at work, on a trip), the personnel of the remote monitoring centers, when an alarm condition is triggered, is forced to take measures to save the patient, which in some cases may have no reason.

The described situation can occur repeatedly. The disadvantage of such a control system is the unnecessary costs of organizing emergency care for the patient and a decrease in confidence in alarms from both the patient and the medical staff, which in real critical situations can lead to serious consequences.

The proposed solution allows to overcome these disadvantages. It consists in the fact that in the event of the occurrence of one of the events that trigger the alarm mode (the measured parameters go beyond the set limits, the data transfer from one or more sensors is stopped), the real start of actions in accordance with this mode is postponed for a certain time (60- 120 sec.). At this time, a warning system is triggered in the patient-worn device, which, either by a special form of a sound, light or mechanical (vibration) signal, or by a pre-recorded voice message, by a combination of these types of signals, or otherwise, informs the patient about the occurrence of an alarm mode.

Having received such a message, the patient has the opportunity to cancel the activation of the alarm mode within a set time. In this case, the personal telemedicine system returns to its original position. If the patient has not followed the cancellation of the alarm mode within the set time, it is activated and the medical personnel take measures to help the patient.

The problem that is solved in the proposed utility model is the creation of a personal telemedicine device for remote monitoring of vital functions of the organism of patients at risk, with increased reliability of operation and reduced possibility of false response.

The required technical result, which is achieved in the proposed utility model, is the expansion of the arsenal of technical tools used as a personal telemedicine device for remote monitoring of vital functions of the body of patients at risk, as well as increasing the reliability of its functioning and reducing the possibility of false alarms.

The problem is solved, and the required technical result is achieved by the fact that in the device containing the channel for measuring the pulse, the channel for taking the electrocardiogram, the channel for measuring the patient’s body temperature, the channel for measuring blood pressure, the channel for measuring the respiratory rate and the channel for measuring the oxygen content in the blood, which are made with the ability to receive signals from their respective sensors located on the patient’s body and generate output signals in digital form for subsequent analysis, as well as a display for visual display of measurement information and a processing and analysis module for measurement signals, the inputs of which are connected to the outputs of the channels for measuring pulse, taking an electrocardiogram, measuring body temperature, measuring blood pressure, measuring respiratory rate, and measuring oxygen content in the blood, and the output is connected to the display input, moreover , the module for processing and analysis of measurement signals is configured to convert the output signals of the pulse measurement channels, taking an electrocardiogram, measuring temperature body measurements, blood pressure measurements, respiration rate measurements, and blood oxygen measurements in the video signals to be displayed on the display as the results of current measurements with the ability to highlight results that are outside the acceptable range and generate an audible alarm when beyond the acceptable range, , the instrument unit of the wearable medical diagnostic complex is made in a housing equipped with fastening means on the patient’s body, and the display is placed on its lateral surface with According to the utility model, an alarm reset button, an alarm mode delay timer and a key are inserted, the signal input of which is connected to the alarm output of the measurement signal processing and analysis module, the first key control input is connected to the timer output and the second control input of the key is connected to the output of the alarm reset button, while the key output is connected to the timer off input and to the control input of the light and sound signals tion of the measurement signal processing and analyzing unit which intervene when the output measurements of limits.

The drawing shows a functional diagram of a personal telemedicine device for remote monitoring of vital functions of the body of patients at risk.

A personal telemedicine device for remote monitoring of vital functions of the patient’s body at risk includes a channel 1 for measuring heart rate, channel 2 for measuring blood pressure, channel 3 for taking an electrocardiogram, channel 4 for measuring respiratory rate, channel 5 for measuring the patient’s body temperature, and channel 6 for measuring oxygen in the blood which are configured to receive signals from their respective sensors located on the patient’s body and generate output signals in digital form for next analysis.

In addition, a personal telemedicine device for remote monitoring of vital functions of the organism of patients at risk contains a module 7 for processing and analyzing measurement signals, the inputs of which are connected to the outputs of channel 1 for measuring heart rate, channel 2 for measuring blood pressure, channel 3 for recording an electrocardiogram, channel 4 for measuring frequency breathing channel 5 measuring the body temperature of the patient and channel 6 measuring the oxygen content in the blood.

A personal telemedicine device for remote monitoring of vital functions of the organism of patients at risk also contains a display 8 for visual display of measurement information, the input of which is connected to the output of the module 6 for processing and analysis of measurement signals.

In a personal telemedicine device for remote monitoring of vital functions of the organism of patients at risk, the module 7 for processing and analyzing measurement signals is configured to convert the output signals of channel 1 for measuring heart rate, channel 2 for measuring blood pressure, channel 3 for recording an electrocardiogram, channel 4 for measuring respiratory rate, channel 5 measuring the body temperature of the patient and channel 6 measuring the oxygen content in the blood into video signals for display on the display 8 in the form of results Live measurements with the possibility of highlighting the results are outside the specified limits. It is also equipped with means of light and sound signaling that are triggered when a signal arrives that the measurement results are outside the permissible limits.

In addition to the above, a personal telemedicine device for remote monitoring of vital functions of the organism of patients at risk contains an alarm reset button 9, an alarm delay timer 10 and a key 11, the signal input of which is connected to the alarm output of the measurement signal processing and analysis module 7, the first the control input of the key 11 is connected to the output of the timer 10, and the second control input of the key 11 is connected to the output of the alarm reset button 9, while the output of the key 11 is connected to the input off cheniya timer 10 and to an input of the control means of light and sound signaling processing module 7, and analysis of measurement signals which are triggered by output measurements of limits.

A personal telemedicine device for remote monitoring of the system of vital functions of the organism of patients at risk in a case equipped with fastening devices on the patient’s body, and display 8 is placed on its side surface with the possibility of visualizing the results of current measurements displayed on it.

In addition, personal telemedicine ^{- a} device for remote monitoring of vital monitoring? body functions of patients at risk are equipped with a wi-fi controller (not shown in the drawing), configured to transmit the results of current measurements of the pulse measurement channel 1, blood pressure measurement channel 2, electrocardiogram recording channel 3 / respiration rate measurement channel 4, temperature measurement channel 5 the patient’s body and the channel for measuring oxygen in the blood to external devices for subsequent analysis and visualization.

In addition to the above, the instrument unit of the wearable medical diagnostic complex is equipped with batteries, for example, a replaceable battery, which ensures its operation.

The personal telemedicine device of the remote monitoring system of the system of vital functions of the organism of patients at risk is working as follows.

In the dashboard of a wearable medical diagnostic complex, the determination of the values of saturation (oxygen content in the blood) and heart rate is made by a signal from a standard sensor worn on the patient’s finger (finger clip). Blood pressure measurement is performed by a non-invasive blood pressure meter (tonometer), consisting of a cuff constantly placed on the patient’s arm in the shoulder area (usually the left), a compressor with an actuator, a valve system connected by piping, and a control controller. The cuff is fastened with a textile fastener (Velcro - burdock). Data for the formation of an electrocardiogram are obtained from special electrodes that are glued to the patient’s body in the chest area. The number of electrodes is from 3 to 5, which provides removal from 6 to 7 leads (I, II, III, aVR, aVL, aVF, V). Respiratory rate is recorded by processing impedance signals from ECG sensors, with no additional sensors being used. The temperature sensor is installed in those places on the patient’s body where the skin surface is not blown with external air: in the nostril, ear, mouth, anus or in the armpit.

The body of a personal telemedicine device for remote monitoring of vital functions of the body of patients at risk is attached to the patient’s body with its own textile fastener, or mounted on the cuff of a blood pressure monitor, it is also possible to wear it on a belt-belt. The device is powered by a removable battery.

The pulse measurement channel 1, the blood pressure measurement channel 2, the electrocardiogram recording channel 3, the respiration rate measurement channel 4, the patient’s body temperature measurement channel 5 and the blood oxygen measurement channel 6 are configured to receive signals from their respective sensors located on the patient’s body and generating output signals in digital form for subsequent analysis.

The signal curves from the outputs of the measurement channels are not shown on the display, since their information content is not high, and the screen will be too small for their qualitative consideration, which will not allow the device to be used for independent monitoring by the patient of the main diagnostic parameters.

Therefore, there is a module 7 for processing and analyzing signals from the outputs of the measurement channels, the inputs of which are connected to the outputs of the pulse measurement channel 1, blood pressure measurement channel 2, electrocardiogram recording channel 3, respiratory rate measurement channel 4, patient body temperature measurement channel 5, and measurement channel 6 oxygen in the blood. In this module, the signals from the outputs of the measurement channels are converted into generally accepted parameters, which are displayed in large numbers on the display 8 in accordance with the accepted color gamut. In addition, in the module 7 for processing and analysis of signals, the set of measured numerical parameters is constantly monitored in order to determine alarm conditions, in particular, whether these parameters fall within acceptable limits, and when exceeding the acceptable limits an alarm is generated, for example, displaying the corresponding parameter on the display red, as well as light and / or sound alarm.

If necessary, the device can be equipped with a wi-fi controller capable of transmitting the results of current measurements of the pulse measurement channel 1, blood pressure measurement channel 2, electrocardiogram recording channel 3, respiratory rate measurement channel 4, patient body temperature measurement channel 5, and channel 6 measuring oxygen in the patient’s blood to external devices for subsequent analysis and visualization. For this, the controller input is connected to the outputs of either the measurement channels or the signal processing and analysis module 7, depending on the options for their technical implementation.

In the event of the occurrence of one of the events that trigger the alarm mode (the measured parameters go beyond the set limits, the data transfer from one or several sensors is stopped), the real start of actions in accordance with this mode is postponed for a certain time (60-120 sec.). This is ensured by the fact that the alarm signal is sent to the signal input of the key 11 with the simultaneous start of the timer 10. Until the timer 10 counts the delay time, the signal through the key 11 does not pass.

At this time, a warning system is triggered in the patient-worn device, which, either by a special form of a sound, light or mechanical (vibration) signal, or by a pre-recorded voice message, by a combination of these types of signals, or otherwise, informs the patient about the occurrence of an alarm mode.

Upon receiving such a message, the patient has the opportunity to cancel the activation of the alarm mode for a set time by pressing the alarm reset button 9. This eliminates the passage of the signal through the key 11, and the timer after counting the delay time goes into the initial state according to the signal from its overflow output.

If the button 9 is not pressed, and the timer provides a delay signal to the control input of the key 11, then the signal is output from the key output to the control input of the light and sound signaling of the module 7 for processing and analysis of measurement signals, which are triggered when the measurement results exceed the permissible limits, followed by medical personnel taking measures to help the patient.

The device is equipped with configuration tools, means for entering patient data, etc., allowing for comfortable and convenient use.

Thus, due to the introduction of additional blocks and connections, the required technical result is achieved, since the expansion of the arsenal of technical means used as a personal telemedicine system for remote monitoring of vital functions of the body of patients at risk, as well as increasing the reliability of its functioning and reducing the possibility of false alarms, is ensured.

Claims (1)

A personal telemedicine device for remote monitoring of vital functions of the body of patients at risk, containing a channel for measuring heart rate, a channel for taking an electrocardiogram, a channel for measuring the patient’s body temperature, a channel for measuring blood pressure, a channel for measuring respiratory rate, and a channel for measuring blood oxygen, which are configured to receiving signals from their respective sensors located on the patient’s body, and generating output signals in digital form for after analysis, as well as a display for visual display of measurement information and a processing and analysis module for measurement signals, the inputs of which are connected to the outputs of the channels for measuring heart rate, taking an electrocardiogram, measuring body temperature, measuring blood pressure, measuring respiratory rate and measuring oxygen in the blood, and the output is connected to the display input, and the processing and analysis module of the measurement signals is configured to convert the output signals of the pulse measurement channels, removing electric trocardiograms, body temperature measurements, blood pressure measurements, respiration rate measurements, and blood oxygen measurements in video signals to be displayed on the display as the results of current measurements with the ability to highlight results that are outside the acceptable range and generate an audible alarm when exceeding the acceptable limits, while the instrument unit of the wearable medical diagnostic complex is made in a case equipped with fastening means on the patient’s body, and the display is sized on its side surface with the possibility of visualizing the results of current measurements displayed on it, characterized in that an alarm reset button, an alarm delay timer and a key are inserted, the signal input of which is connected to the alarm output of the measurement signal processing and analysis module, the first control the key input is connected to the timer output, and the second control key input is connected to the output of the alarm reset button, while the key output is connected to the timer off input and to the media control input by means of light and sound signaling of the module for processing and analysis of measurement signals, which are triggered when the measurement results exceed the permissible limits.

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