RU97259U1 - HEMODYNAMIC MONITORING DEVICE - Google Patents

Abstract

 1. A device for monitoring the hemodynamics of organs or sections of the human body at different depths in local areas, including an eddy current transducer made in the form of an inductor, a working generator, a calibration generator, a converter of the output signal of the working generator into a square wave signal, a converter of the output signal of the calibration generator in square wave signal, frequency subtraction device, integrator, controlled element, characterized in that the device additionally contains an hour otomer, digital filter, control unit, pulse-width modulator, non-volatile memory for storing monitoring data, measurement depth switch, analyzer for detecting health-hazardous conditions, hazardous state indicator, interface unit for communication with a computer, the eddy-current transducer made in the form of one Inductors made on a flexible printed circuit board. ! 2. The device according to claim 1, characterized in that the frequency meter, digital filter, control unit, pulse-width modulator and analyzer for detecting health-hazardous conditions can be made in the form of a single integrated circuit.

Description

The utility model relates to medical equipment, namely, devices for dynamic non-invasive measurement of the degree of blood supply (hemodynamics) of human organs and can be used for long-term monitoring of the human circulatory system in an outpatient setting with the issuance of warning signals about borderline dangerous conditions (thromboses, etc. .).

It is known that the impedance of living tissues depends on their degree of blood supply [1].

Known instruments for non-invasive measurement of the impedance of living tissues of a biological object by electromagnetic resonance impedancemetry, which is carried out by exposure of a biological object to one of the elements of an oscillating circuit containing an inductor, a capacitor and determining the resonance resistance and resonance capacitance of this circuit without exposure and when exposed to a biological object and determine the relationship of the parameters of the circuit (patent RU 2182814 C2, A61B 5/053 "Method of electromagnetic-cutting ansnoy impedance of living biological tissues of the object and the device for its implementation ", of 27.05.2002).

During the study, the voltage of a series of frequencies is formed and fed to the oscillating circuit, scanning in the frequency range with a certain step. Next, the amplitude-frequency characteristic of the oscillatory circuit with the acting biological object is determined and the parameters of this circuit are determined. The obtained parameters are compared with the parameters of the oscillatory circuit without a biological object and the impedance of the biological object is calculated. The impact is carried out by introducing a biological object into the internal or external electromagnetic field of the inductance coil of the oscillatory circuit.

A device for implementing the method comprises a generator of test signals of variable frequency, a sensor, which includes an inductor and a capacitor forming an oscillatory circuit, and a recorder. A computer with an additional device for generating and processing signals is used as a generator of test signals of variable frequency and a recorder. The device is equipped with a signal conditioning and processing device comprising an interface, a digital-to-analog converter, a voltage controlled oscillator, a synchronizer, a frequency counter, an analog-to-digital converter and a channel switch.

This solution has the following disadvantages:

1) low measurement speed, limited by a large number of frequencies necessary for measuring the frequency response of the circuit and the speed of the computer;

2) insufficient accuracy of the measurement, due to the influence of possible interference (electromagnetic fields from neighboring devices, radio stations, etc.), which can significantly distort the measurement results;

3) in addition, at present, there is a need to conduct electromagnetic resonance impedanometry of individual organs and parts of biological objects, taking into account the process of blood supply and cardiac activity.

The device for electromagnetic resonance impedanometry, as claimed in patent RU 2295912, АВВ 5/053 “Method for electromagnetic resonance impedance measurement of living tissues of a biological object and a device for its implementation”, dated July 10, 2006) differs from the previous one in that the evaluation of the parameters of the oscillatory circuit they are carried out not by scanning frequencies, but by measuring the frequency of free vibrations arising and their attenuation rate during shock excitation of the circuit, and the parameters of the oscillatory circuit are measured simultaneously with the measurement of electric cardiac signal, discretely, during each of the N-measurements of the cardiac cycle time. This allows you to perform electromagnetic resonance impedancemetry of individual organs and parts of biological objects with greater speed, as well as taking into account the processes of blood supply and cardiac activity.

This solution has the following disadvantages:

1) the presence of electrodes for removing the electrocardiogram, i.e. the need for electrical contact with the patient's body;

2) the mandatory availability of a computer to control the device and calculate the results;

3) impedance measurement occurs for one specific depth of field penetration into the human body, which does not allow measuring the impedance of organs located at different depths;

4) the need for two-phase measurements, which significantly slows down the measurement process.

Closest to the claimed utility model, the device described in the article "Non-contact determination of the degree of blood supply to organs or parts of the human body at different depths in local areas", published in the journal "Medical Technology" No. 1, 1986 [2].

The device, called by the authors "Eddy Current Rheograph", measures the frequency deviation of the resonant circuit operating at a carrier frequency of 30 MHz, occurring simultaneously with the passage of blood flow through the studied human organ. The frequency change is estimated by comparing the frequency of the working generator with the frequency of the calibration generator. The allocated frequency difference is used to adjust the frequency of the calibration generator in order to eliminate the drift of the circuit, as well as to convert it to an analog output signal for recording on the recorder. The resulting rheogram allows the doctor to analyze the hemodynamics of the investigated organ.

The advantages of the device are that:

- impedance measurement is carried out only using an inductor, without additional electrodes;

- the device can measure the impedance of living tissues at different depths by selecting one of the three measuring inductors having different diameters;

- for carrying out measurements there is no need for a calibration phase;

- the entire procedure for measuring impedance is carried out by the device constantly, offline.

The disadvantages of the device are:

1) a significant mass of the construction of the inductive sensor (the sensor coils are made of a dielectric wire on the volume core), which leads to the necessity of attaching the sensor to the body with elastic straps;

2) the resulting signal is fed only to the recorder in the form of a recorder, which does not allow saving the measurement data on a computer for subsequent processing;

3) the device has a mass of 6 kg and dimensions of 300 × 250 × 400 mm, which does not allow it to be used for long-term monitoring of the patient on an outpatient basis (when attaching the device directly to the patient’s body).

The task of creating a utility model is to expand the possibilities of using a device for measuring hemodynamics in order to carry out long-term monitoring and subsequent analysis on the doctor’s computer of the state of blood flow and timely warning of health hazards, as well as improving the ergonomic parameters of the device for prolonged wear on the human body.

This object is achieved by the fact that the device for monitoring the hemodynamics of organs or parts of the human body at different depths in local areas, including an eddy current transducer made in the form of an inductor, a working generator, a calibration generator, a converter of the output signal of the working generator to a square wave signal, an output converter the signal of the calibration generator into a square-wave signal, a frequency subtraction device, an integrator, a controlled element of the calibration generator, according to the claimed technical solution, the device further comprises a frequency meter, a digital filter, a control unit, a pulse-width modulator, non-volatile memory for storing monitoring data, a measurement depth switch, an analyzer for detecting health-hazardous conditions, an indicator of dangerous conditions, an interface unit for communication with the computer, and the eddy current Converter is made in the form of a single inductor made on a flexible printed circuit board.

A frequency meter, a digital filter, a control unit, a pulse-width modulator and an analyzer for detecting health-hazardous conditions can be implemented as a single integrated circuit (for example, a microcontroller).

The essence of the utility model is illustrated by the functional diagram of the device shown in figure 1.

The device contains: eddy current transducer 1, a working generator 2, a converter of the output signal of the working generator to a square-wave signal 3, a calibration generator 4, a converter of the output signal of the calibration generator to a square-wave signal 5, a frequency subtraction device 6, an integrator 7, a controlled element 8, a frequency meter 9, digital filter 10, control unit 11, pulse-width modulator 12, non-volatile memory 13, measurement depth switch 14, hazardous state analyzer 15, hazardous status indicator Thaw 16, interface unit 17.

The eddy current transducer 1 inductor is made on a flexible multilayer printed circuit board made of polyamide, with a flexible protective coating, an outer diameter of not more than 50 mm, and is mounted on the human body in any way (on an adhesive base, wrapping with an elastic bandage, etc.).

Measurement of the degree of blood supply to a specific organ or part of a person’s body and monitoring of its hemodynamics are carried out as follows: the eddy current transducer is attached to the organ under investigation and monitoring is activated for a certain time (for example, for a day - Holter monitoring).

A change in blood flow affects the eddy current transducer 1, changing the frequency of the working generator 2. The calibration generator 4 is tuned to a frequency that is spaced from the frequency of the working generator by a preset value of the differential frequency. The output signal of the working generators 2 is converted into a square-wave signal by the converter 3, the output signal of the calibration generator 4 is converted into a square-wave signal by the converter 5. Then, in the frequency subtraction device 6, the frequency of the calibration generator 4 is subtracted from the frequency of the working generator 2. The resulting differential frequency signal is converted to digital view by a frequency meter 9 and is filtered by a digital filter 10 to eliminate network interference and other interference.

The filtered signal is the result of measurements and is recorded in non-volatile memory 13 to save long-term monitoring data and subsequent transfer to the doctor’s computer via the interface unit 17.

In addition, the result is converted into analog form by a pulse-width modulator 12 and supplied to the integrator 7 with a time constant of at least 30 s. From the integrator 7, the signal is supplied to the controlled element 8 of the calibration generator 4, changing its frequency. Thus, the frequency of the calibration generator 4 is adjusted to stabilize the value of the differential frequency, which varies due to the drift of the circuit parameters from temperature, supply voltage, etc.

Also, the obtained result is sent to the hazard state analyzer 15, which, using a special algorithm, determines the occurrence of dangerous blood flow conditions in the human organ (for example, the occurrence of blood clots) and warns the patient about them using the hazard state indicator 16.

The depth of penetration of the field into the human body is changed by changing the power of the magnetic field excited in the eddy current transducer 1 by the working generator 2. The power, in turn, changes by changing the supply voltage of the working generator 2 when the measurement depth switch 13 is applied to the control unit 11.

Frequency meter 9, digital filter 10, pulse-width modulator 12 and hazardous state analyzer 15 operate under control of control unit 11.

Frequency meter 9, digital filter 10, pulse-width modulator 12, hazardous state analyzer 15 and control unit 11 can be functional units of one integrated circuit, which significantly reduces the dimensions and weight of the device and allows it to be implemented as a portable portable unit (fixed, for example , on a belt) for long wear.

The implementation of the inductance coil of the eddy current transducer 1 in the form of a light and thin flexible board of small diameter allows you to fix it on any necessary part of the human body and increases the reliability of measurements for studies of body parts of complex (not flat) shape.

The positive effect in the proposed utility model is based on a combination of circuitry and design solutions aimed at increasing the functionality and integration of the circuit, reducing the number of sensor coils and optimizing the design of the sensor coil of the eddy current transducer, which allows monitoring of the hemodynamics of parts of the human body at different depths with prolonged wear of the device patient, as well as timely warn a person about the dangerous conditions of his circulatory system.

In the proposed utility model, an additional positive effect is achieved, consisting in the fact that when using the proposed sensor with a flexible coil, it is possible to monitor the hemodynamics of parts of the human body in different volume forms (for example, limbs).

Information sources

1. D.S. Ryabokon. Impedansometry of living tissues of a biological object. // Radio engineering. - 1995. - No. 2 - S.176-182.

2. Zinovieva L.A., Avdeeva D.K., Zinoviev A.I. Non-contact determination of the degree of blood supply to organs or parts of the human body at different depths in local areas. // Medical equipment. - 1986. -№1.-S.15-18.

Claims (2)

1. A device for monitoring the hemodynamics of organs or sections of the human body at different depths in local areas, including an eddy current transducer made in the form of an inductor, a working generator, a calibration generator, a converter of the output signal of the working generator into a square wave signal, a converter of the output signal of the calibration generator in square wave signal, frequency subtraction device, integrator, controlled element, characterized in that the device additionally contains an hour otomer, digital filter, control unit, pulse-width modulator, non-volatile memory for storing monitoring data, measurement depth switch, analyzer for detecting health-hazardous conditions, hazardous state indicator, interface unit for communication with a computer, the eddy-current transducer made in the form of one Inductors made on a flexible printed circuit board. 2. The device according to claim 1, characterized in that the frequency meter, digital filter, control unit, pulse-width modulator and analyzer for detecting health-hazardous conditions can be made in the form of a single integrated circuit.