RU148056U1 - REOGRAPH - Google Patents

Abstract

A rheograph containing the first and second four-contact resistance sensors of a human body area, having current and potential contacts, as well as a processing and display unit, a high-frequency signal generator having an information output, which is connected to the processing and display unit, characterized in that it additionally contains the first and second synchronous detectors, and the high-frequency signal generator has the first and second signal outputs and is configured to measure the values of high-frequency currents flowing through the first and second signal outputs and output the measured current values to the information output of the generator, while the first four-contact sensor measures the resistance along the arteries and veins of a part of the human body, and the second four-pin sensor measures the resistance across the arteries and veins of the same part of the body, in the high-frequency signal generator, the high-frequency voltage of the second signal output is phase-shifted by 90 ° relative to the high-frequency voltage of the first signal output, the first signal output of the generator connected to the current contacts of the first four-contact sensor, the second signal output of the generator is connected to the current contacts of the second four-contact sensor, the potential contacts of the first four-contact sensor are connected to the input of the first synchronous detector, the potential contacts of the second four-contact sensor are connected to the input of the second synchronous detector, the control input of the first synchronous detector is connected with the first signal output of the generator, the control input of the second synchronous

Description

The utility model relates to devices for the diagnosis of various diseases of the cardiovascular system by recording changes in the resistance of living tissue resulting from the activity of the cardiovascular system (blood inflow and outflow).

The well-known "Single-channel rheograph" (USSR patent No. 119966 dated January 15, 1959), containing a high-frequency generator and an electric power device supplying the device with a stabilized voltage, in which, in order to increase the sensitivity of the device to changes in the resistance of the studied body section, to increase the accuracy of the recorded curve , expanding the scope of the device and simplifying its design, it is made in the form of an electrocardiographic set-top box on the principle of a balanced AC bridge, while a part of the human body is included in one of the shoulders of the bridge, and the curve of changes in the resistance of living tissue is recorded at the output of the electrocardiograph.

The well-known "Sensor of biological signals" (US patent No. 6996428 from 02/18/2004), adopted for the prototype, which contains four flat annular potential contacts located on the plane of the holder and nested into each other. The first (having the largest diameter) contact and the fourth (having the smallest diameter) contact are connected to a high-frequency signal generator and are used to create a high-frequency current in the human body. Two contacts with intermediate diameters, and located between the transmitting contacts, are used to measure the magnitude of the current induced by the transmitting contacts in the human body.

All these devices have a common drawback - the low accuracy of the pulse wave measurement, due to the fact that these devices measure the volume resistance of the human body, and the resistance of the human body changes from the pulse wave in the vessels (arteries and veins) and when the filling of the capillaries changes.

The objective of the utility model is to increase the accuracy of the measurement of the pulse wave by providing the ability to record changes in the resistance of the human body separately from the pulse wave in the vessels (arteries and veins) and from changes in the filling of capillaries.

This problem is solved using two channels of recording the resistance of the human body: along and across the arteries and veins.

The technical result, which consists in increasing the accuracy of measuring the pulse wave by providing the ability to record changes in the resistance of the human body separately from the pulse wave in the vessels (arteries and veins) and from changing the filling of the capillaries, is achieved by the fact that the rheograph contains the first and second four-pin resistance sensors a portion of the human body having current and potential contacts, as well as a processing and display unit, a high-frequency signal generator having an information output that connects In addition to the processing and display unit, according to the utility model, the first and second synchronous detectors are additionally introduced, and the high-frequency signal generator has first and second signal outputs and is configured to measure the high-frequency currents flowing through the first and second signal outputs and to output measured current values to the information output of the generator, while the first four-pin sensor measures resistance along the arteries and veins of a portion of the human body, and the second four-pin sensor measures it shows resistance across the arteries and veins of the same body section, the high-frequency signal generator of the second signal output is 90 degrees out of phase with respect to the high-frequency voltage of the first signal output, the first signal output of the generator is connected to the current contacts of the first four-pin sensor, the second signal output of the generator connected to the current contacts of the second four-pin sensor, potential contacts of the first four-pin sensor is connected with the input of the first synchronous detector, the potential contacts of the second four-pin detector are connected to the input of the second synchronous detector, the control input of the first synchronous detector is connected to the first signal output of the generator, the control input of the second synchronous detector is connected to the second signal output of the generator, the outputs of the first and second synchronous detectors are connected to inputs of the processing and display unit.

The essence of the utility model is illustrated by the drawing, which shows a block diagram of the Reograph according to the proposed utility model.

In the drawing, the numbers indicate:

1 - The first four-pin resistance sensor of a section of the body, measures resistance along arteries and veins,

2 - The second four-pin resistance sensor of the body part, measures the resistance across the arteries and veins,

3 - A section of the body whose resistance is measured by the first and second four-contact resistance sensors,

4 - High-frequency signal generator,

5 - block processing and display,

6 - The first synchronous detector,

7 - Second synchronous detector,

8 - The first signal output of the generator 4, is connected to the current contacts of the first four-pin sensor 1,

9 - The second signal output of the generator 4, is connected to the current contacts of the second four-pin sensor 4,

10 - The first signal output of the generator 4, is connected to the control input of the first synchronous detector 6,

11 - The second signal output of the generator 4, is connected to the control input of the second synchronous detector 7,

12 - Potential contacts of the first four-pin sensor 1 are connected to the input of the first synchronous detector 6,

13 - Potential contacts of the second four-pin sensor 2 are connected to the input of the second synchronous detector 7,

14 - The output of the first synchronous detector 6, connected to the inputs of the processing and display unit 5,

15 - The output of the second synchronous detector 7, connected to the inputs of the processing and display unit 5,

16 - Information output of the generator 4, issuing the values of high-frequency currents flowing through the first 8 and second 9 high-frequency signal output.

The rheograph contains the first 1 and second 2 four-pin resistance sensors of the portion 3 of the human body having current and potential contacts 12, 13, as well as a processing and display unit 5, a high-frequency signal generator 4 having an information output 16, which is connected to the processing and display unit 5 .

The difference of the proposed rheograph is that the first 6 and second 7 synchronous detectors are additionally introduced into it, and the high-frequency signal generator 4 has first 8 and second 9 signal outputs and is capable of measuring high-frequency currents flowing through the first 8 and second 9 signal outputs , and the issuance of the measured values of the currents to the information output 16 of the generator, while the first four-pin sensor 1 measures the resistance along the arteries and veins of section 3 of the human body, and the second four-pin sensor measures the resistance across the arteries and veins of the same area 3 of the body, the generator of 4 high-frequency signals, the high-frequency voltage of the second signal output 9 is phase-shifted 90 degrees relative to the high-frequency voltage of the first signal output 8, the first signal output of the generator 8 is connected to the current contacts of the first four-pin sensor 1, the second signal output 9 of the generator is connected to the current contacts of the second four-pin sensor 2, potential contacts of the first four-pin date 1 is connected to the input of the first synchronous detector 6, potential contacts of the second four-pin sensor 2 are connected to the input of the second synchronous detector 7, the control input 10 of the first synchronous detector 6 is connected to the first signal output 8 of the generator, the control input 11 of the second synchronous detector 7 is connected to the second signal the output 9 of the generator, the outputs of the first 6 and second 7 synchronous detectors are connected to the inputs of the block 5 processing and display.

The work of the proposed reograph is as follows.

The difference of the proposed rheograph is that a change in the resistance of the human body is recorded separately from the pulse wave in the vessels (arteries and veins) and from changes in the filling of capillaries. The high-frequency generator 4, connected by conductors 8 and 9 with the current contacts of the first 1 and second 2 four-pin sensors, creates high-frequency currents in the area of the body 3. In this case, since the high-frequency voltage of the second signal output of the generator 4 is 90 degrees out of phase with respect to the high-frequency voltage of the first signal the output of the generator 4, the high-frequency currents of the first 1 and second 2 four-pin sensors also have a shift of 90 degrees relative to each other. This is necessary for separate, independent reception of signals from potential contacts of the first four-pin sensor 1, and from potential contacts of the second four-pin sensor 2.

This is possible when using synchronous detectors 6 and 7, which receive signals along lines 12 and 13 from potential contacts of the first 1 and second 2 four-pin sensors. The control inputs of the first 6 and second 7 synchronous detector, along lines 10 and 11, receive signals from the first and second signal outputs of the generator 4.

The first synchronous detector 6 extracts signals U1 proportional to the fall of high-frequency voltage in the area of the body 3 along the arteries and veins, the second synchronous detector 7 extracts signals U2 proportional to the fall of high-frequency voltage in the area of the body 3 along the arteries and veins. The outputs of synchronous detectors 6 and 7 are connected, by lines 14 and 15, to the inputs of the processing and display unit 5, and contain values proportional to the drop in the high-frequency voltage in the area of the body 3 along U1 and across U2 arteries and veins. The information output 16 of the generator 4, gives the values of high-frequency currents flowing along the first 8 and second 9 high-frequency signal output equal to the currents flowing on the body part 3 along Iv and across Ip arteries and veins.

As a result, knowing the current Iv and voltage U1, we can calculate the resistance of the body portion 3 along the arteries and veins, similarly knowing the current Ip and voltage U2, we can calculate the resistance of the body part 3 across the arteries and veins. In this case, the resistance of the portion of the body 3, which is caused by capillaries, due to the highly branched structure of the capillaries is isotropic, that is, the resistance weakly depends on the direction. At the same time, the resistance of the body portion 3, which is caused by arteries and veins, strongly depends on the direction along or across the arteries and veins: the resistance along the arteries and veins is less than in the transverse direction. Therefore, if we subtract from the voltage U1 (in which the contribution of the resistance of the arteries and veins, and the resistance of the capillaries) the voltage U2 (in which the main contribution is made by the capillaries), we can obtain the contribution of the resistance of the arteries and veins, and more accurately measure the contribution of this resistance.

The processing and display unit 5 calculates the difference signal Up = U1 * k-U2 * (1-k), and the total signal Uc = U1 * k + U2 * (1-k), where U1 and U2 are the output signals of the first 6 and second 7 synchronous detectors, the coefficient k lies in the range from 0 to 1, and is continuously adjusted by the processing and display unit 5 so that the average value of the difference signal Up for a time interval of 10 seconds is zero. The processing and display unit 5 further calculates the resistance of the human body Rв along the arteries and veins Rв = Up / Iв, and the resistance of the human body Rп across the arteries and veins Rп = Uc / Iп. Accordingly, Rв will be determined mainly by the resistance of arteries and veins, Rп will be determined by the resistance of capillaries.

Such a measurement scheme has the following advantages in comparison with the prototype:

- The change in the resistance of the human body is carried out separately from the pulse wave in the vessels (arteries and veins, Rв) and when the filling of capillaries (Rп) changes.

- The coefficient k is related to the ratio of the resistance along and across the arteries and veins, and is used to control the quality of the four-pin sensors 1 and 2 of the resistance of the body section, and when the coefficient k falls into the range from 0 to 0.1 or from 0.9 to 1 block processing and display gives a signal about the malfunction of the contact sensor.

- The presence of two measured parameters, Rв and Rп, makes it possible to build a two-dimensional graph: along the vertical axis, the person’s resistance along the arteries and veins Rв is laid out, along the horizontal axis, the body’s resistance is laid across the arteries and veins Rп. This two-dimensional graph is more informative compared to conventional graphs of the dependence of Rв and Rп on time.

Thus, in comparison with the prototype, the proposed rheograph has significant advantages, allowing a much more accurate measurement of the pulse wave, more informative in the role of measuring the resistance of arteries and veins.

Claims (1)

A rheograph containing the first and second four-pin resistance sensors of a portion of the human body having current and potential contacts, as well as a processing and display unit, a high-frequency signal generator having an information output that is connected to the processing and display unit, characterized in that it is additionally introduced the first and second synchronous detectors, and the high-frequency signal generator has first and second signal outputs and is configured to measure high-frequency currents, leakage the first and second signal outputs, and the issuance of the measured current values to the information output of the generator, while the first four-pin sensor measures the resistance along the arteries and veins of the human body, and the second four-pin sensor measures the resistance across the arteries and veins of the same body, generator of high-frequency signals, the high-frequency voltage of the second signal output is phase-shifted 90 ° relative to the high-frequency voltage of the first signal output, the first signal The generator one is connected to the current contacts of the first four-pin sensor, the second signal output of the generator is connected to the current contacts of the second four-pin sensor, the potential contacts of the first four-pin sensor are connected to the input of the first synchronous detector, the potential contacts of the second four-pin sensor are connected to the input of the second synchronous detector, the control input of the first synchronous the detector is connected to the first signal output of the generator, the control input of the second synchronous about the detector is connected to the second signal output of the generator, the outputs of the first and second synchronous detectors are connected to the inputs of the processing and display unit.

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