RU83402U1 - DEVICE FOR REMOTE ARTERIAL PRESSURE MONITORING - Google Patents

Abstract

1. A device for remote monitoring of blood pressure, comprising a cuff connected to a pressure generating and depressurizing unit connected to one of the inputs and outputs of the blood pressure determining unit, a clock microcircuit and a control unit, wherein the outputs of the blood pressure detecting unit, a clock microcircuit, and a block controls are connected to inputs of a processor, the outputs of which are connected to a display unit, a blood pressure determination unit, and a clock microchip, characterized in that iemoperedayuschy unit configured with at least one channel for remote transmission and reception of data, input and output of which is connected to one of the inputs and outputs of the processor, and a control unit configured to provide a selection of different users and data. ! 2. The device according to claim 1, characterized in that the transceiver unit is made in the form of a cellular module with at least one slot for installing a SIM card. ! 3. The device according to claim 1, characterized in that the display unit is made in the form of a display on which a number of indicators of measurement results, operating modes, user identification and data transfer are installed. ! 4. The device according to claim 1, characterized in that the display unit is made in the form of a display and LEDs designed to display measurement results, operation modes of user identification and data transfer. ! 5. The device according to claim 1, characterized in that the display unit of the measurement results and operating modes is made in the form of a unit for reproducing sound signals designed to alert the measurement results, mode

Description

The utility model relates to medical equipment and is intended for measuring blood pressure and other indicators of the cardiovascular system in the remote control and monitoring mode for joint users of one device.

Blood pressure control is extremely important for the prevention and treatment of hypertension, the prevalence of which in different countries is from one third to half of all examined. Moreover, hypertension is not only one of the most common pathologies of our time, but also the most important risk factor for cardiovascular complications, especially cerebral stroke. Modern research data has shown that active involvement of patients in regular monitoring of blood pressure leads to a 48% reduction in mortality from cerebral stroke, and subsequent adequate control of blood pressure leads to a 28% reduction in the risk of re-stroke. However, at present, less than 10% and slightly more than 10% of women have registered appropriate controls. Particularly problematic is the monitoring of blood pressure in patients, which requires mandatory visits to the doctor to install an appropriate monitor and repeated calls to decipher the monitor and obtain appropriate recommendations from the attending physician. Because of this, solving the problems of adequate control and monitoring of blood pressure, especially at home, can effectively deal with the complications of high blood pressure and reduce mortality from cardiovascular diseases.

When maintaining the recorded blood pressure measurement values in a single blood pressure monitor for various users, it is essential to avoid confusion of the recorded values. As a method of maintaining data on blood pressure values and a blood pressure monitor designed for this purpose, measurements are recorded on a magnetic card belonging to an individual. The blood pressure monitor reads the recorded value from a magnetic card and displays a trend graph (Japanese Patent Laid-Open No. 05-137698). However, this monitoring principle is inconvenient for users, since the measurement results must be transmitted

specialists to decipher and issue recommendations on the measurement results, which requires additional visits to doctors.

A device for automatic control and monitoring of blood pressure, comprising a shoulder cuff, a compressor for generating pressure in the shoulder cuff, a cuff pressure sensor, a unit for calculating blood pressure and heart rate, an indicator for displaying blood pressure and heart rate. (UA-767 PC Automatic Blood Pressure Monitor. Modern electronic blood pressure measuring, monitoring and control equipment. A&D Company, Limited Tokyo, Japan). This device is intended for domestic use and allows automatic measurement of blood pressure when turned on manually and, if necessary, enter the measurement results into a personal computer. The advantage of this device is its relatively low cost, due to mass production, high accuracy of blood pressure measurement, reliability, ease of use. The disadvantage of this device is the inconvenience of its use for monitoring blood pressure associated with additional operations to enter data into a personal computer. In addition, in order to analyze the results of monitoring, the patient must appear for consultations with the attending physician, or keep his own observation diary. At the same time, the control and monitoring by several users of one device for measuring blood pressure does not exclude an accidental substitution of blood pressure readings, which reduces the reliability and reliability of the control and monitoring of indicators of cardiovascular activity.

A known blood pressure monitor (RF patent No. 2336809), comprising a first manipulation unit for selecting a storage area corresponding to an object, a second manipulation unit for manipulating the action of a blood pressure monitor and a control unit prohibiting manipulation of the second manipulation unit until a selection is made in the first block of manipulation.

The specified device is more reliable due to the built-in technical configuration, which eliminates the mixing of measurement values for many users, since each of the users using the switches first sets the storage area for measurements, and then takes measurements. However, the practical use of this device does not exclude confusion in pressing the corresponding switches by different users, which

may lead to inaccurate measurements. Moreover, in crisis situations, the attention and well-being of patients, especially the elderly, is sharply weakened, which leads not only to erroneous measurements, but also to the inconvenience of using a monitor, since delays in the measurement process are likely.

The closest in technical essence and the achieved result to the claimed is a device for monitoring and monitoring of blood pressure (RF patent No. 2299008), created on the basis of manufactured blood pressure meters, containing a blood pressure meter, a microcontroller unit, a digital memory unit, a clock chip, a recording unit and sound reproduction. The device also contains a button for selecting the first or second patient, connected to the microcontroller. This device allows you to measure blood pressure and heart rate at programmed points in time, to accumulate and analyze the measurement results over long time intervals with the issuance of information to the patient in gradations "norm" - "excess of norm", transferring the analysis results to a cell phone or personal computer.

However, the implementation of this device does not provide reliable and reliable control and monitoring of blood pressure and other indicators of cardiovascular activity in various users of the same device. The presence of a button, the pressing of which must be controlled by the patient himself when changing users, reduces the reliability and reliability of the measurement data from a particular user. In addition, the accumulated information is transmitted to diagnostic centers via separate telephone communication channels, which requires additional equipment for measuring blood pressure with appropriate external equipment and a number of additional data sending operations. In this case, the patient's choice of whether each of the accumulated measurement values should be transferred or only favorable for him, or only those for which he has free time to transmit, is determined subjectively. The lack of automatic transmission of data to diagnostic centers obtained as a result of monitoring blood pressure by various users of the same device does not allow medical specialists to obtain a reliable picture of patient pressure indicators in optimal terms, which in turn does not contribute to the development of timely optimal treatment recommendations.

The main task solved by the claimed device is the creation of a device that allows you to control and monitor blood pressure at home by automatically transferring data to a medical site

active observation, on which any user of the device can have an individual page that reflects the observation diary with medical data, which will improve the reliability of diagnosis and make timely recommendations to users by medical specialists.

The technical result consists in increasing the reliability and reliability of the control and monitoring of blood pressure in joint users of the same device for measuring indicators of cardiovascular activity. At the same time, the functional capabilities of devices for monitoring blood pressure are expanded, which is achieved by providing data reception and transmission in the process of control and monitoring directly from the device.

To solve this problem, in a known device for controlling and monitoring blood pressure, comprising a cuff connected to a pressure generating and pressure relief unit connected to one of the inputs and outputs of the blood pressure detecting unit, a clock microcircuit and a control unit, while the outputs of the blood pressure detecting unit , a clock microcircuit and a control unit are connected to the inputs of the processor, the outputs of which are connected to a display unit, a blood pressure determination unit and a clock microcircuit , a transceiver unit has been introduced, made with at least one channel for remote data transmission and reception, the input and output of which is connected to one of the inputs and outputs of the processor, and the control unit is configured to provide various users and data transmission.

It is preferable to perform the transceiver unit in the form of a cellular module with at least one slot for installing a SIM card.

It is advisable to display unit in the form of a display on which a number of indicators of measurement results, operating modes, data transfer and user identification can be installed.

Preferably, the display unit is made in the form of a display and LEDs designed to display measurement results, operating modes, data transfer and user identification.

The display unit can be made in the form of a unit for reproducing audio signals designed to notify about the measurement results, operating modes, data transfer and user identification.

It is advisable to perform the control unit in the form of on / off switches, setting the current date and time, selecting operating modes and programming measurement parameters, selecting users and transmitting data.

Preferably, the user selection switches are configured to identify the user by fingerprints.

It is advisable to additionally provide the display with indicators of communication.

In a preferred embodiment, the display is equipped with indicators for the number of users of the device.

The display may be liquid crystal.

It is preferable to run a processor with non-volatile memory.

It is advisable to provide an antenna communication device.

In the prior art, devices are unknown that make it possible to control and monitor indicators of cardiovascular activity at home by several users without additional external equipment, without special visits with monitoring results to medical specialists, which relates the claimed utility model to technical solutions that meet the criterion of "novelty" .

Figure 1 presents a block diagram of the inventive device.

Figure 2 schematically shows the design of the claimed device.

Figure 3 presents a view of the front panel of the housing of the claimed device.

A device for remote monitoring of blood pressure (figure 1) contains a cuff 1 connected to a unit 2 for creating and depressurizing a cuff connected to one of the inputs and outputs of the blood pressure determining unit 3, a clock chip 4 and a control unit 8, while the outputs unit 3, the clock chip 4 and the control unit 8 are connected to the inputs of the processor 5, the outputs of which are connected to the display unit 7, the blood pressure determination unit 3 and the clock chip 4. The device also contains a transmitting and receiving unit 6, made, for example, in the form of a cellular module for remote transmission in the preferred embodiment of CMC messages, in which at least one SIM card slot is inserted, the input and output of which is connected to one of the inputs and outputs of the processor 5, containing non-volatile memory (not shown in the drawing).

A cell module, as a transceiver, can use the GSM standard (Global System for Mobile Communications), the GPRS standard (General Packet Radio Service), the UMTS standard (Universal Mobile Telecommunication System), or any other mobile standard that is based on a signal from a logical means control automatically calls at least one external service

and passes her the data. To provide low-cost communications and for device autonomy, it is preferable to use special type CMC messages.

The control unit 8 is made in the preferred embodiment in the form of switches 11-15 (Fig. 3), for example, on / off, setting the current date and time, programming measurement parameters, selecting operating modes, user and data transmission. It is preferable to select the user to use the switches made with the possibility of identifying the user by fingerprints.

The display unit 7 is made in the form of a display 10, on which a series of indicators of measurement results, operating modes, data transmission and user identification can be installed.

The inventive device has a rectangular shape (figure 3). The display 10 is located at the top of the front panel of the apparatus. The panel also has switches that can be made in the form of buttons, or sensors (etc.), or finger readers, designed, for example, to turn on / off 11 and control the operation of the device 12, 13, 14, 15. On the upper part, near the entrance for the air tube of the shoulder cuff 1, has an antenna, for example, for external communication 9. On the rear panel of the device’s case there is a socket for a battery or battery, closed with a tight cover on top, and a socket (Fig. 2) for installing SIM -kart. It is possible to implement a device with a cellular module that has several slots for installing individual SIM cards of various users.

Display 10 can be made monochrome and consist of four standard 7-segment numeric fields separated by a dot in the third position (that is, the device can show any number from the range 0.0-999.9), as well as indicators of operating modes, such as indicators of the device’s operation network (via a network adapter) or from internal batteries (batteries or accumulators), communication indicators, such as a level indicator, for example, GSM-connection, SIM card installation indicator and balance replenishment indicator, daily monitoring indicators I, for one 12-hour or 24-hour mode of daily monitoring and programmable user mode of daily monitoring of blood pressure and heart rate indicator, time and date indicators, and indicators of user identification.

The display unit 7 can also be made in the form of a display 10 and LEDs (not shown), designed to display the measurement results, operating modes, data transfer and user identification.

The display unit 7 can be made in the form of a unit for reproducing sound signals (not shown in the drawing) designed to notify about the measurement results, operating modes, data transfer and user identification.

The display 10 may also be liquid crystal.

The inventive device for remote monitoring of blood pressure in joint users works as follows.

After acquiring the device according to the claimed utility model, the user installs, for example, in a preferred embodiment, a SIM card in one of the slots of the cellular module 6. The cellular module can have at least one channel for sending messages, which involves reinstalling the SIM card each of the users of the device. It is possible to implement a device with a number of channels for transmitting messages, structurally made in the form of several sockets, where each user has their own SIM card, or use one SIM card, identifying the user by using the appropriate switch. When using the device according to the claimed utility model by several users, the processor 5 stores the IMSI (unique international subscriber identifier) of the inserted SIM cards in the buffer, for example, up to 10 numbers. Each dimension that is saved must be marked with an IMSI index from the IMSI buffer. If, for example, the 11th SIM card is inserted in the device, then the earliest used IMSI is deleted from the buffer, and all data associated with it is also erased. Thus, the inventive device allows reliable remote control and monitoring by a number of users, for example, up to 10 people in the same time period.

Moreover, all measurements of blood pressure and heart rate from time to time (by default, for example, after every 15th measurement) are adapted to automatically send a medical website to the server. All measurement values are correlated with the mobile number of the SIM card and digital identifier - a unique device code specified in the user manual and on its rear panel. Each device has a unique 9-digit digital identifier. Each incoming CMC message must begin with this number. If the code does not match, then the incoming message is ignored.

Later, the user can go to the site, enter the mobile number of the SIM card, the digital identifier of the device and gain access to all stored data. The user can also register on the site in manual mode. In this case, he enters his personal data and forms his personal page, which is subsequently tied to the measurements made by the claimed device. To do this, you must also enter a mobile SIM card number and a unique device code. All measured data and the results of subsequent measurements will be on the individual user page.

The inventive device can be used for daily or 12-hour monitoring, as well as for single measurements at the request of the patient with remote data transfer to the medical website. Before taking measurements in this mode, the user must make sure, in accordance with the readings of one of the communication indicators, that the SIM card is installed, and based on the readings of the time and date indicators, that the time is set correctly. When the device is turned on by the switch 11 for measuring pressure, the unit 2 for creating and depressurizing pumps air into the cuff 1 connected to the input of the unit 2, and also bleeds the air from the cuff. Block 2 also transmits the current value of the pressure in the cuff to the input of block 3 for determining blood pressure and heart rate (HR). Block 3 determining blood pressure through the corresponding output sends control signals to block 2 for creating and depressurizing and converts the corresponding pressure signal in the cuff 1 coming from the output of block 2 to the input of block 3. In accordance with these signals, the systolic and diastolic blood pressure values are determined , as well as heart rate. The measured values from the output of blood pressure determination unit 3 are sent to a processor 5 with non-volatile memory and to a measurement results display unit 7, which can be made in the form of a display 10, on which a number of indicators of measurement results, user identification, operation modes, and data transmission are installed.

In one of the implementations of the claimed utility model, the display unit may be made in the form of a unit for reproducing sound signals intended to notify of measurement results, operating modes and data transmission. The indicated implementation option can facilitate the use of the claimed device by older people, since in this case the measurement result is duplicated by notifying the user, in addition, sound signals can be sent when switching the monitoring modes, replacing the user, etc.

Processor 5 is the central node that provides support for operating modes, the monitoring process, saving measurement results and sending them to the server in a timely manner. It coordinates the operation of the entire device and controls the operation of the blood pressure determination unit 3 by supplying a signal for measuring pressure. The processor 5 initializes the cellular module, for example, the GSM module, and checks for the presence or absence of an installed SIM card, user identification. If a SIM card is installed, then processor 5 reads its IMSI. Next, the processor checks in its memory whether a SIM card with such IMSI was used in the device or not. If a SIM card has not been used, then a new entry is made in the well-known IMSI buffer, otherwise the already known IMSI is used. The processor also reads the value of the communication level, for example, at the request of the GSM module.

The processor checks the setting of the current time and date and determines the operation mode of the device (if the time is set, the date and the SIM card are installed, the device will operate in personal mode).

At each point in time, the device for measuring blood pressure and heart rate can be in various internal operating modes, such as: standby mode of a user command, pressure measurement mode, sending mode of CMC messages, manual time setting mode, etc. Each mode is characterized by a set of current parameters and the processor accordingly sets the necessary indicators and properly responds to pressing the switches of the control unit 8, etc.

The processor 5 also checks the cellular module 6 for incoming CMC messages. If there is such a CMC message, the code is verified at the beginning of the CMC message with an individual number and, if there is a match, the operation programmed in the CMC message is performed.

The processor 5 receives the signals coming from the switches 11-15 of the control unit 8, and depending on the type of signals gives commands to measure pressure, switch to monitoring mode, exit the mode, enter forced synchronization with the server, etc.

In the pressure measurement mode, the processor 5 does not respond to the user pressing the switches of the control unit 8, but instructs the blood pressure determination unit 3 to measure the pressure. At each clock cycle, the processor 5 displays information for the user on the display 10. After a complete measurement of blood pressure (and this process takes a lot of clock cycles) if the pressure could not be determined, processor 5 goes into error display mode. In personalized mode, processor 5 stores the next measurement in

non-volatile memory (with date and time of measurement), checks the number of unsynchronized measurements with the server. If there are more than 15 unsynchronized messages, for example, the device goes into synchronization mode of unsynchronized measurements with the server.

In the monitoring mode, the processor 5 reconciles each measurement step with the measurement schedule programmed in the current monitoring profile. Measurements can be tied to the beginning of the monitoring mode - for example, measurements 2, 4, 6 hours after the start of monitoring, or to the time of day, for example, measurements at 11:00, 14:00 and 17:00). The measurement result from one of the processor outputs is sent to the display unit 7, and also, if necessary, is stored in the non-volatile memory of the processor 5.

Cell module 6 is designed to transmit CMC messages to the user identification number specified in the firmware of the central processor, as well as receive incoming CMC messages and transfer them to the processor 5 through the corresponding output.

At the same time, control signals are received at the input of the processor 5, which are initiated by the user using the switches of the control unit 8.

The user can make measurements using the inventive device in a single measurement mode, i.e. in control mode. If the user measures the pressure using the first button 12, then the measurement result (three digits - systolic and diastolic blood pressure, as well as heart rate) with the date and time is stored in the device's memory. The memory allows storing, for example, at least 1000 measurements. In this case, the measurement data can also be transmitted to the medical website.

For more objective observation, the user can use the device in the daily monitoring mode, which is carried out at the request of the user or as directed by a doctor. In this case, the device is fixed on the user's belt, included only at the moments of measurement, as programmed in the device, or in manual mode by the user. The daily monitoring mode is activated using the second button 13. In the device, for example, two hard-coded monitoring modes and three user modes that can be programmed by the user on his own or by his attending physician can be installed. In this case, special software is used that allows for day or night 12-hour monitoring, which is reflected on the display using the appropriate indicators.

Remote transmission of data on the measurement results using the inventive device allows each user to maintain their health passport and communicate with their attending physicians through the website for prescribing drugs or recommendations.

A health passport can consist of information about diagnoses, doctor visits, prescribed drugs and courses of treatment, and is filled in personally by the patient or his or her attending physician. On the individual page of the patient, blood pressure measurements are recorded by the claimed device in automatic mode. Doctors can also prescribe special daily monitoring profiles for their patients who have blood pressure measuring devices made according to the claimed technical solution.

The inventive utility model allows reliable remote control and monitoring of blood pressure among joint users of one device with reliable storage of measurement results in a personal diary of observations - an individual page on the Internet site of each user. The claimed utility model also allows optimal analysis of the dynamics of changes in blood pressure over a period of long-term observation, which significantly increases the effectiveness of the prevention and treatment of arterial hypertension and its complications, as well as improving the quality of diagnosis of the patient’s cardiovascular system by monitoring the deviations of blood pressure from normal.

Claims (9)

1. A device for remote monitoring of blood pressure, comprising a cuff connected to a pressure generating and depressurizing unit connected to one of the inputs and outputs of the blood pressure determining unit, a clock microcircuit and a control unit, wherein the outputs of the blood pressure detecting unit, a clock microcircuit, and a block controls are connected to inputs of a processor, the outputs of which are connected to a display unit, a blood pressure determination unit, and a clock microchip, characterized in that iemoperedayuschy unit configured with at least one channel for remote transmission and reception of data, input and output of which is connected to one of the inputs and outputs of the processor, and a control unit configured to provide a selection of different users and data. 2. The device according to claim 1, characterized in that the transceiver unit is made in the form of a cellular module with at least one slot for installing a SIM card. 3. The device according to claim 1, characterized in that the display unit is made in the form of a display on which a number of indicators of measurement results, operating modes, user identification and data transfer are installed. 4. The device according to claim 1, characterized in that the display unit is made in the form of a display and LEDs designed to display measurement results, operation modes of user identification and data transfer. 5. The device according to claim 1, characterized in that the display unit of the measurement results and operating modes is made in the form of a unit for reproducing sound signals designed to alert the measurement results, operating modes, user identification and data transfer. 6. The device according to claim 1, characterized in that the control unit is made in the form of on / off switches, setting the current date and time, selecting operating modes and programming measurement parameters, selecting a user and transmitting data. 7. The device according to claim 6, characterized in that the user's selection switches are configured to identify the user by fingerprints. 8. The device according to claim 1, characterized in that the processor contains non-volatile memory. 9. The device according to claim 1, characterized in that it is equipped with an antenna.