RU2568762C1 - Continuous health monitor - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: device comprises electrodes, amplifiers, transmitting and receiving antennas, a signalling unit, breathing rate, pulse, partial pressure of oxygen, temperature, blood pressure sensors, a device number register, a timing unit, a memory read register, a direct energy saving register, a number decoder, a comparator unit, setters, integral comparator units, information registers, integral deviation registers, a check register, parallel-serial registers, a control unit, an information display unit, an information input unit and a signalling unit.

EFFECT: using the invention enables providing more reliable transmission of health parameters under noise conditions.

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Description

The invention relates to medical equipment, namely to devices for remote monitoring of patients for diagnosis by several physiological parameters, and can be used in practical health care facilities, including the ambulance system, remote counseling centers using telemetric communication channels to support human life.

A known monitor system of physiological parameters, comprising a transmitting unit consisting of a sensor and a high-frequency generator, with a transmitting antenna connected to the output of the transmitting unit, and a receiving unit containing a receiving antenna, a radio receiver whose output is connected to the receiving antenna, a demodulation unit, and a recording unit ( Patent RU 2089094 C1, class A61B 5/02, publ. 09/10/1997).

The disadvantage of this device is the low reliability of the transmission of functional data in the presence of interference and the lack of adaptation of the device to the current state of the patient.

Known telemetric complex for monitoring and diagnosing the functional state of a person, consisting of a transmitting part located on the human body, including the connected physiological signal pickup unit, containing electrodes for picking up electrical biopotentials, a preliminary amplification unit, a multiplexer, a signal coding unit and an infrared radiation unit, and a receiving part, including the connected photodetector, signal decoding unit, demultiplexer and output information generating unit signals (Patent CH 675675 A5, class A61B 5/04, publ. 10/31/1990).

The disadvantage of this device is the loss of the patient’s functional data when they go beyond the network and there is no comparison of the integral parameters with acceptable indicators for this patient at arbitrary time intervals.

The closest is a device for continuous monitoring of the activity of the heart, containing serially connected electrodes and preamplifiers, a modulating code generator, a phase manipulator, a power amplifier and a transmitting antenna, a mixer, a local oscillator, an intermediate frequency amplifier and a phase detector, an audible alarm unit, a magnetic recorder ( Patent RU 2181258 C2, class A61B 5/04, 04/20/2002)

The disadvantage of this device is the loss of functional data during transmission under interference conditions, the lack of adaptation of the device to the current state of the patient and comparison of parameters with acceptable indicators for this patient and the assessment of integral indicators at arbitrary time intervals.

The objective of the invention is to create a device for continuous monitoring of the functional state of the patient, providing increased reliability of the transmission of the parameters of the functional state of the patient in the presence of interference, correction of the frequency of polling data when the condition worsens, monitoring of current status parameters and comparing them with acceptable for the patient, assessment and comparing integral indicators at arbitrary time intervals with the generation of warning signals when they deviate from the task values of the.

The technical result is to increase the reliability of the transmission of parameters of the patient’s functional state in the presence of interference, the ability to correct the frequency of polling data when the condition worsens, monitor the current state parameters and compare them with acceptable for the patient, evaluate and compare integral indicators at arbitrary time intervals with the generation of warning signals when they deviate from the set values.

To achieve a technical result, a device for continuously monitoring the patient’s functional state, containing serially connected electrodes and preamplifiers, the first modulating code generator, phase manipulator, power amplifier and transmitting antenna, first mixer, local oscillator, intermediate frequency amplifier and phase detector, sound unit alarms, magnetic recorder, additionally introduced a respiratory rate sensor, heart rate sensor, partial pressure sensor oxygen, temperature sensor, blood pressure sensor, connected in series through pre-amplifiers and ADCs with the base register directly and through the first “I” element, the device number register and the third timer with the base register, second series-connected mixer, local oscillator, intermediate frequency amplifier, a phase detector, a setup register, the outputs of which are connected to the information inputs of the first timer for polling sensors, the second timer for polling memory, switch register, register read memory and energy saving register directly, and with the fixing inputs through the first decoder of the device number, the outputs of the first timer for polling sensors are connected to the input of the first element "I" and the input to the ADC start, the output of the basic register through the information inputs of the first intermediate register, the first storage device, the fifth element "And", the third intermediate register, the first parallel-serial register, the first phase manipulator and the first power amplifier is connected to the first transmitting ant the output of the first generator of the modulating code is connected to the second input of the first phase manipulator, the output of the base register is connected to the information input of the second intermediate register, the fixing input of which is connected to the output of the second element "And", the second timer polling memory is connected to the fifth element "And" and through the second inverter with the second element "And", the switching register is connected to the second element "And" and through the third inverter and the third element "And" with the locking input of the first intermediate register, read register the memory is connected through the fourth “And” element to the third intermediate register and through the fourth inverter to the fifth “And” element, the energy saving register is connected to the disconnecting inputs of the third intermediate register, the first parallel-serial register, the first modulating code generator, the first phase manipulator and the first amplifier power, the second intermediate register through the fourth element "And" is connected to the third intermediate register, the first element "And" through the first inverter is connected to the second element “And” through the third element “And” with the fixing input of the first intermediate register, the receiving register through the control register is connected to the output of the first phase detector, the outputs of the receiving register are connected directly to the information inputs of the information register, and the outputs of the information registering through the second decoder are register through the register of electrodes, register of respiratory rate, register of pulse rate, register of partial pressure of oxygen, register of temperature and register of arteries pressure, respectively, are connected to the first inputs of the electrode comparison unit, the respiratory frequency comparison unit, the pulse rate comparison unit, the oxygen partial pressure comparison unit, the temperature comparison unit and the blood pressure comparison unit, the second inputs of which are connected respectively through the electrode setter, respiratory rate setter , heart rate monitor, oxygen partial pressure monitor, temperature monitor and blood pressure monitor with reference register the outputs of the unit for comparing the electrodes, the unit for comparing the frequency of the respiratory movements, the unit for comparing the partial oxygen pressure, the unit for comparing the partial pressure of oxygen, the unit for comparing the temperature and the unit for comparing blood pressure through interval adders and, accordingly, through the integrated unit for comparing the electrodes, the integral unit for comparing the frequency of respiratory movements, the integral unit for comparing the pulse rate, the integral unit for comparing the partial pressure of oxygen, the integral unit for comparing the temperature and the integral unit for comparing blood pressure is connected to the control unit and the register of deviations of the integral values, the control unit through the register of integral tasks and the integral electrode setter, the integral setter for respiratory movements, the integral setpoint for heart rate, the integral setpoint for partial oxygen pressure, the integrated setpoint for temperature and the integral setter for arterial pressure is connected respectively to the second inputs of the integrated blocks comparing the electrodes, often s of respiratory movements, pulse rate, partial oxygen pressure, temperature and blood pressure, the control unit is connected to the reset inputs of the interval adders via the integration period timer, the task register input is connected to the control unit, the information register and integral deviation register outputs are connected to the control unit, the output of the control register through the fourth intermediate register and the second storage device is connected to the control unit, the control unit through the setpoint device measure, sensor polling timer dial, memory polling timer dial, switching register dial, memory reading register dial and energy saving register dial is connected to the forming register, the output of which is through a second parallel-serial register, the second phase manipulator is connected to the second power amplifier and the second transmitting antenna, the second generator of the modulating code is connected to the second phase manipulator, the permission output of the transmission of the control register is connected to the permission input the second parallel-serial register, the information display unit, the information input unit, the magnetic recorder and the sound alarm unit are connected to the control unit.

The invention is illustrated by drawings, in which in FIG. 1 shows the transmitting part, in FIG. 2 receiving part of the device for continuous monitoring of the functional state of the patient.

A device for continuously monitoring the patient’s functional state includes electrodes 1, a respiratory rate sensor 2, a pulse rate sensor 3, an oxygen partial pressure sensor 4, a temperature sensor 5, a blood pressure sensor 6, pre-amplifiers 7, an ADC 8, a second mixer 9, and a second local oscillator 10, second intermediate-frequency amplifier 11, second phase detector 12, tuning register 13, first device number decoder 14, first polling timer 15 sensors, second polling timer 16 memory, switching register 1 7, memory read register 18, power save register 19, base register 20, first memory 21, first 22 and second 23 and third 24 intermediate registers, first parallel-serial register 25, first modulating code generator 26, first phase shifter 27, first power amplifier 28, first transmitting antenna 29, device number register 30, third timer 31, first 32, second 33, third 34, fourth 35, fifth 36 “I” elements, first 37, second 38, third 39, fourth 40 inverters, first mixer 41, first local oscillator 42, first amplifier intermediate frequency 43, first phase detector 44, control register 45, receive register 46, second device number decoder 47, information register 48, electrode register 49, respiratory frequency register 50, pulse rate register 51, oxygen partial pressure register 52, register temperature 53, blood pressure register 54, electrode setter 55, respiratory rate adjuster 56, pulse rate setter 57, oxygen partial pressure setter 58, temperature setter 59, blood pressure setter I am 60, an electrode comparison unit 61, a respiratory rate comparison unit 62, a pulse rate comparison unit 63, an oxygen partial pressure comparison unit 64, a temperature comparison unit 65, a blood pressure comparison unit 66, interval adders 67, an integral electrode setter 68, an integral setter respiratory rate 69, integral heart rate controller 70, integrated oxygen partial pressure generator 71, integrated temperature controller 72, integrated blood pressure controller 73, timer integration period 74, integrated electrode comparison unit 75, integrated respiratory rate comparison unit 76, integrated heart rate comparison unit 77, integrated oxygen partial pressure comparison unit 78, integrated temperature comparison unit 79, integrated blood pressure comparison unit 80, task register 81, register of integral tasks 82, register of deviations of integral values 83, fourth intermediate register 84, second storage device 85, control unit 86, display unit info Missions 87, information input unit 88, magnetic recorder 89, audible alarm unit 90, device number dial 91, sensor polling timer dial 92, memory polling timer dial 93, switching register dial 94, memory reading register dial 95, energy saving register dial 96, the forming register 97, the second parallel-serial register 98, the second modulating code generator 99, the second phase manipulator 100, the second power amplifier 101 and the second transmitting antenna 102.

A device for continuous monitoring of the functional state of the patient works as follows.

The functional state of the patient is continuously monitored by the transmitting part by means of electrodes 1, a respiratory rate sensor 2, a pulse rate sensor 3, an oxygen partial pressure sensor 4, a temperature sensor 5 and a blood pressure sensor 6. The signals from the sensors through the pre-amplifiers 7 are fed to the ADC 8 and converted in digital form. Synchronization of the start of the conversion of the ADC 8 is carried out by means of the first polling timer 15 sensors. The end of the conversion of the ADC 8 is fixed by the first 32 “I” element, according to the signal from which the data coming from the ADC 8 and additionally from the register of the device number 30 and the third timer 31 generating the real-time signal are entered into the base register 20. As a result, information from all sensors is recorded in the base register 20 with the addition of an individual identification number of the device and the value of the current time.

The settings of the transmitting part of the device for monitoring the patient’s functional state are made from the receiving part of the device through the radio channel through the receiving antenna, the signal from which through the second mixer 9, the second amplifier of the intermediate frequency 11 and the second phase detector 12 enters the settings register 13 for monitoring the parameters of the functional state the patient. The second local oscillator 10 provides the operation of the second mixer 9. As a result, a code combination is received in the setup register 13, received from the receiving part, which reflects the requirements of the examining doctor for the parameters of the transmitting part of the patient monitoring device.

The data of the setup register 13, which is responsible for choosing this particular transmitting part of the device, is sent to the first decoder of the device number 14. The first decoder of the device number 14 is triggered only if the doctor conducting the examination of the patient has chosen this particular transmitting part. The first decryptor of device number 14 enables the first timer to poll 15 sensors, the second timer to poll 16 memory, shift register 17, memory read register 18, power saving register 19.

By means of the first interrogation timer of 15 sensors, the interrogation frequency of the sensors is established, which is important when changing the patient’s functional state, for example, when a sharp deterioration in health occurs, the pulse rate, pressure and other parameters go beyond the normal values for this patient.

By means of the switching register 17, data from the basic register 20 is recorded, either through the first 22 intermediate register in the first memory 21, or in the second 23 intermediate register for direct data transmission through the fourth 35 element "And", the third 24 intermediate register, the first parallel serial register 25, the first phase manipulator 27, the first power amplifier 28 and the first transmitting antenna 29 to the receiving part of the device in real time. To write data from the base register 20 to the first 22 intermediate register in the first storage device 21, a third 40 inverter and a third 34 “And” element are used. The first 37 inverter is designed to synchronize the operation of the basic register 20 and the first 22 of the intermediate register.

By means of the second memory polling timer 16, the data accumulated in the first memory 21 is transmitted at set intervals. To this end, the second 23 inverters are prohibited from reading the second 23 inverters and through the fifth 36 elements And the reading is allowed the first storage device 21, data from which through the third 24 intermediate register, the first parallel-serial register 25, the first phase manipulator 27, the first power amplifier 28 and the first transmitting antenna 29 is transmitted to the receiving part of the device.

By means of the memory reading register 18, through the fourth 35th element “And” or the fourth 40th inverter and the fifth 36th element “And”, data reading is selected from either the first storage device 21 or the second 23 intermediate register.

The energy-saving register 19 is designed to transfer the third 24 intermediate registers, the first parallel-serial register 25, the first modulating code generator 26, the first phase manipulator 27 and the first power amplifier 28 to the power-saving mode, which is caused by the battery supply of the transmitting part that is worn by the patient .

The receiving part of the device for continuous monitoring of the patient’s functional state receives data from the transmitting part through the first mixer 41, the first local oscillator 42, the first intermediate frequency amplifier 43, the first phase detector 44 and writes them to the reception register 46 through the control register 45.

In addition, data from the transmitting part through the fourth intermediate register 84 is supplied to the second storage device 85, where they are stored and sampled for submission to the control unit 86 with further presentation to the doctor through the information display unit 87 and for recording in the magnetic recorder 89.

The correctness of data transmission is carried out by the control register 45, which through the second parallel-serial register 98, the second phase manipulator 100 with the second modulating code generator 99, the second power amplifier 101 and the second transmitting antenna 102 transmits information about the correct reception of data from the transmitting part of the device.

The second device number decoder 47 provides for determining the identification number of the transmitting part of the device and writing data to the information register 48. The data from the information register 48 are divided respectively into the registers of the electrodes 49, respiratory rate 50, pulse rate 51, oxygen partial pressure 52, temperature 53, arterial pressure 54.

Individually for each patient, the doctor, through the information input unit 88, through the control unit 86 and task register 81 sets the physiological parameters for the patient on the electrodes 55, respiratory rate 56, pulse rate 57, oxygen partial pressure 58, temperature 59 and blood pressure 60.

Comparison of the current values of the physiological parameters of the patient with the permissible established by the doctor is performed on the blocks comparing the electrodes 61, respiratory rate 62, pulse rate 63, oxygen partial pressure 64, temperature 65 and blood pressure 66.

Then, the signals are fed to the interval adders 67, on which the values of the squares of the mismatch between the current physiological parameters of the patient and those valid for his condition at the time interval set by the doctor through the information input unit 88 through the control unit 86 and the integration period timer 74 are summed.

The obtained values are sent to the integral units for comparing the electrodes 75, respiratory rate 76, pulse rate 77, oxygen partial pressure 78, temperature 79 and blood pressure 80, where they are compared with the values set by the doctor set from the information input unit 88 via the control unit 86 and the register integral tasks 82 on the integral setters of the electrodes 68, respiratory rate 69, pulse rate 70, oxygen partial pressure 71, temperature 72 and blood pressure 73.

The obtained data are sent to the doctor for processing through the control unit 86 and the information display unit 87.

At the same time, the data obtained are sent to the register of deviations of the integral values 83, which in the case of significant deviations of the functional parameters of the patient from the values allowed by the doctor through the control unit 86 will transmit a signal to the doctor through the information display unit 87 and the audible alarm unit 90.

The doctor in the process of examination from the receiving part by means of the input unit 88 through the control unit 86 sets the data to the device number dial 91, the sensor polling timer dial 92, the memory polling timer dial 93, the switching register dial 94, the memory reading register dial 95 and the register dial energy saving 96.

The unit number dialing device 91 provides a choice of the transmitting part of the patient whom the doctor has planned to monitor. This signal through the forming register 97, the second parallel-serial register 98, the second phase manipulator 100 with the second modulating code generator 99, the second power amplifier 101 and the second transmitting antenna 102 enters the transmitting part through the second mixer 9, the second intermediate frequency amplifier 11, the second phase detector 12, setting register 13 to the first decoder of the device number 14. The first decoder of the device number 14 is triggered only if the doctor conducting the examination of the patient chose this particular transmitting part.

Similarly, the signals from the sensor polling timer setter 92, the memory polling timer setter 93, the switching register setter 94, the memory reading register setter 95, and the energy saving register setter 96 are used through the forming register 97, the second parallel-serial register 98, the second phase manipulator 100 with the second generator 99 the modulating code, the second power amplifier 101 and the second transmitting antenna 102 are supplied to the transmitting part through the second mixer 9, the second intermediate frequency amplifier 11, the second phase detector 12, reg mp 13 setting for the first timer survey sensors 15, the second poll timer memory 16, shift register 17, read register 18 and memory register 19, respectively, power saving, whereby the doctor sets patient survey parameters depending on the physiological state of the latter.

Such a technical solution provides an increase in the reliability of the transmission of the parameters of the patient’s functional state in the presence of interference, the possibility of correcting the frequency of polling data when the condition worsens, monitoring the current state parameters and comparing them with those acceptable for the patient, evaluating and comparing integral indicators at arbitrary time intervals with the development of warning signals when they deviate from the set values.

Claims (1)

A device for continuously monitoring the patient’s functional state, comprising serially connected electrodes and preamplifiers, the first modulating code generator, phase manipulator, power amplifier and transmitting antenna, first mixer, local oscillator, intermediate frequency amplifier and phase detector, audible alarm unit, magnetic recorder, characterized in that the device additionally includes a respiratory rate sensor, a pulse rate sensor, an acid partial pressure sensor orod, temperature sensor, blood pressure sensor, connected in series through pre-amplifiers and ADCs with the base register directly and through the first “I” element, the device number register and the third timer with the base register, the second series-connected mixer, local oscillator, intermediate frequency amplifier, phase a detector, a setup register, the outputs of which are connected to the information inputs of the first timer for polling sensors, the second timer for polling memory, switch register, memory read register the energy saving register and register directly, and with the fixing inputs through the first device number decoder, the outputs of the first sensor polling timer are connected to the input of the first AND element and the ADC start input, the output of the basic register is through the information inputs of the first intermediate register, the first storage device, the fifth element "And", the third intermediate register, the first parallel-serial register, the first phase manipulator and the first power amplifier is connected to the first transmitting antenna, in the output of the first generator of the modulating code is connected to the second input of the first phase manipulator, the output of the base register is connected to the information input of the second intermediate register, the fixing input of which is connected to the output of the second element "And", the second timer polling memory is connected to the fifth element "And" and through the second an inverter with a second element “And”, the switching register is connected to the second element “And” and through a third inverter and a third element “And” with a latching input of the first intermediate register, the memory read register connected through the fourth “I” element with the third intermediate register and through the fourth inverter with the fifth “I” element, the energy saving register is connected to the disconnecting inputs of the third intermediate register, the first parallel-serial register, the first modulating code generator, the first phase manipulator and the first power amplifier , the second intermediate register through the fourth element "And" is connected to the third intermediate register, the first element "And" through the first inverter is connected to the second element "And" Without the third “I” element with the fixing input of the first intermediate register, the receiving register through the control register is connected to the output of the first phase detector, the outputs of the receiving register are directly connected to the information inputs of the information register, and the outputs of the information register are fixing through the second decoder of the device number, through the register electrodes, respiratory rate register, heart rate register, oxygen partial pressure register, temperature register and arterial register the pressure is respectively connected to the first inputs of the electrode comparison unit, the respiratory movement frequency comparison unit, the pulse frequency comparison unit, the oxygen partial pressure comparison unit, the temperature comparison unit and the blood pressure comparison unit, the second inputs of which are connected respectively through the electrode setter, respiratory rate setter, heart rate monitor, oxygen partial pressure monitor, temperature monitor and blood pressure monitor with task register, you odes of the electrode comparison unit, the respiratory frequency comparison unit, the pulse rate comparison unit, the oxygen partial pressure comparison unit, the temperature comparison unit and the blood pressure comparison unit through interval adders and, accordingly, through the integrated electrode comparison unit, the integrated respiratory movement frequency comparison unit, integral unit for comparing the pulse rate, integral unit for comparing the partial pressure of oxygen, integrated unit for comparing the temperature and integr A blood pressure comparison unit is connected to the control unit and the register of deviations of the integral values, the control unit via the register of integral tasks and the integral electrode adjuster, the integral respiratory frequency adjuster, the integral heart rate adjuster, the integral oxygen partial pressure adjuster, the integral temperature adjuster and the integral arterial adjuster pressure is connected respectively to the second inputs of the integrated blocks comparing the electrodes, respiratory rate movements, pulse rate, partial oxygen pressure, temperature and blood pressure, the control unit is connected to the reset inputs of the interval adders via the integration period timer, the job register input is connected to the control unit, the outputs of the information register and the register of deviations of integral values are connected to the control unit, output the control register through the fourth intermediate register and the second storage device is connected to the control unit, the control unit through the dial transistor, sensor polling timer switch, memory polling timer switch, switching register switch, memory reading register switch and energy saving register switch is connected to the forming register, the output of which is through a second parallel-serial register, the second phase manipulator is connected to the second power amplifier and the second transmitting antenna , the second modulating code generator is connected to the second phase manipulator, the output of the enable transmission of the control register is connected to the input of the permission of the second o parallel-serial register, information display unit, information input unit, magnetic recorder and sound alarm unit are connected to the control unit.

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