RU2138982C1 - Device for evaluating functional state of the cardiovascular system - Google Patents

Abstract

FIELD: medical engineering. SUBSTANCE: device has electrodes for reading biopotential values from patient chest, electrodes for reading biopotential values from patient extremities, multichannel amplifier of biopotentials, low frequency filter unit, as well as multiplexor, analog-to-digital converter, processor unit and recording unit connected in series. The first and the second oscillators creating synchronous probing current pulse bursts, the first and the second electrodes for delivering probing current to patient upper extremities, the first and the second electrodes for delivering probing current to patient lower extremities, the first and the second differential amplifiers of alternating current, adder, detector, low frequency filter and band-pass filter. Synchronous probing current pulse bursts succession period is at least 10 times as much as synchronous probing current pulse bursts duration, pulse frequencies being equal to (10-100).10³. EFFECT: concurrently recorded electrocardiogram and integral rheogram of human body. 3 cl, 2 dwg

Description

 The invention relates to medical equipment and can be used to diagnose the condition of the cardiovascular system.

 A known method of measuring the parameters of the central hemodynamics of the patient, based on the method of tetrapolar rheography. To implement this method, various rheographs are used, which contain current electrodes connected to an AC source and potential electrodes connected to a measuring circuit including a differential AC amplifier with a high input resistance (see, for example, [1, 2]).

 Rheographs provide a measurement of the constant component of human resistance (usually in the range of 150-350 Ohms - depending on the constitution) and the pulse component, which causes amplitude modulation with a depth of 0.03 to 0.7%.

 Rheographs do not provide the removal of electrocardiograms, which carry a lot of information about the state of the patient's cardiovascular system.

 Known electrocardiograph [3], which is the technical essence of the closest to the proposed device. This electrocardiograph contains electrodes for taking biopotentials from the patient’s chest, electrodes for taking biopotentials from the patient’s limbs, a multi-channel biopotential amplifier, a low-pass filter block, a multiplexer connected in series, an analog-to-digital converter, and a processing and recording device.

 An electrocardiograph [3] provides the removal of potentials of electrocardiograms (ECG), which are used to form twelve generally accepted ECG leads. The known electrocardiograph [3] does not allow measurements of the parameters of the patient’s central hemodynamics simultaneously with the removal of electrocardiograms.

 This drawback cannot be eliminated by simply combining the electrocardiograph and rheograph circuits. This is due to the fact that during rheographic studies of the state of the cardiovascular system, the patient's hands are short-circuited.

 The objective of the invention is to obtain the possibility of simultaneous removal of the electrocardiogram and integral rheogram of the body from the same electrodes applied to the limbs of the patient.

This problem is solved in that in a device for assessing the functional state of the cardiovascular system, containing electrodes for removing biopotentials from the patient’s chest, electrodes for collecting biopotentials from the patient’s limbs, a multi-channel biopotential amplifier, a low-pass filter unit, a multiplexer connected in series, and an analog a digital converter, a processing and recording unit, the first and second generators of bursts of synchronous pulses of the probing current, the first and second electrodes for dosing of the probe current to the upper limbs of the patient, electrically connected to the first terminals of the first and second generators of synchronous pulses of the probe current, the first and second electrodes for supplying the probe current to the lower limbs of the patient, connected to the second terminals of the first and second pulse generators electrically connected probing current, the first and second differential AC amplifiers, the first inputs of which are connected to the electrodes for biopot removal ialov from the upper limbs of the patient, and the second inputs of the differential amplifiers are electrically connected to each other and electrodes for removing biopotentials from the lower extremities of the patient, an adder, the first and second inputs of which are connected to the outputs of the first and second differential AC amplifiers, the detector, the input of which is connected to the output of the adder, a low-pass filter and a band-pass filter, the inputs of which are electrically connected to each other and connected to the output of the detector, while the inputs of the lower filter block x frequencies are connected to electrodes for removing biopotentials from the patient’s chest, electrodes for collecting biopotentials from the patient’s upper limbs and electrodes for collecting biopotentials from the patient’s lower extremities, the outputs of the low-pass filter block are connected to the corresponding inputs of the multi-channel biopotential amplifier, multiplexer inputs connected to the outputs of a multi-channel biopotential amplifier, lowpass filter output and bandpass filter output, trace period packs of Nia synchronous pulse current probe is at least ten times the duration of pulse bursts synchronized probing current, whose frequency is (10-100) • March ¹⁰ Hz.

 Each generator of bursts of synchronous pulses of the probing current can be made in the form of a voltage-current converter, while the device contains a generator of bursts of pulses, the output of which is connected to the input of each voltage-current converter.

 In addition, in the proposed device, the detector can be made in the form of a synchronous detector, the control input of which is connected to the output of the pulse packet generator.

The essence of the invention is illustrated by drawings, which depict:
in FIG. 1 is a functional diagram of a device,
in FIG. 2 is a diagram of connecting a device to a patient.

In the drawings are indicated:
1, ..., 6 - electrodes for removing biopotentials from the chest of the patient,
7, ..., 10 - electrodes for removing biopotentials from the limbs of the patient,
11, ..., 14- electrodes for supplying a probing current,
15 is a block of lowpass filters,
16 is a multi-channel amplifier biopotentials,
17 - multiplexer,
18 - analog-to-digital Converter,
19 - processing unit and registration,
20, 21 - generators of packs of synchronous pulses of the probing current,
22, 23 - differential AC amplifiers,
24 - adder
25 is a detector
26 - low pass filter,
27 - band-pass filter,
28 - patient's chest
29, 30 - upper limbs of the patient,
31, 32 - lower limbs of the patient,
33 - generator of bursts of pulses.

The proposed device for assessing the functional state of the cardiovascular system contains electrodes 1-6 for taking biopotentials from the chest of a patient 28, electrodes 7-10 for taking biopotentials from the limbs 29,. .., 32 patients, a low-pass filter unit 15, a multi-channel amplifier 16 of biopotentials, a multiplexer 17 connected in series, an analog-to-digital converter 18, and a processing and recording unit 19. The device also contains the first and second generators 20 and 21 packs of synchronous pulses of the probe current with a frequency of (10-100) • 10 ³ Hz, the repetition period of the packs of which is at least ten times the duration of the packs of synchronous pulses of the probe current. The first and second electrodes 11 and 12 for supplying the probe current to the upper limbs of the patient are electrically connected to the first terminals of the first and second generators 20 and 21 of the synchronous pulses of the probe current, respectively, the first and second electrodes 13 and 14 for supplying the probe current to the lower limbs of the patient connected to electrically interconnected second terminals of the first and second generators 20 and 21 of the pulse packets of the probing current. In addition, the device also contains the first and second differential amplifiers 22 and 23 of alternating current, the first inputs of which are connected to electrodes 7 and 8 for removing biopotentials from the upper limbs of the patient, and their second inputs are electrically connected to each other and electrodes 9 and 10 for removing biopotentials with lower limbs of the patient, adder 24, the first and second inputs of which are connected to the outputs of the first and second differential amplifiers 22 and 23 of alternating current, a detector 25, the input of which is connected to the output of the adder and 24, a low-pass filter 26 and a band-pass filter 27, the inputs of which are electrically connected to each other and connected to the output of the detector 25, while the inputs of the low-pass filter unit 15 are connected to the electrodes 1-6 for removing biopotentials from the patient’s chest, electrodes 7- 8 for removing biopotentials from the upper limbs of a patient and electrodes 9 and 10 electrically connected to each other for removing biopotentials from the lower limbs of a patient. The outputs of the low-pass filter unit 15 are connected to the corresponding inputs of the multi-channel biopotential amplifier 16, the inputs of the multiplexer 17 are connected to the outputs of the multi-channel biopotential amplifier 16, the output of the low-pass filter 26 and the output of the band-pass filter 27.

 The first and second generators 20 and 21 packs of synchronous pulses of the probing current can be performed, for example, in the form of two voltage-current converters with a high output dynamic resistance, the inputs of which are connected to one common generator 33 packs of pulses, which can be made autonomous or based the use of schemes for dividing the clock frequency of the master oscillator of the digital part of the device. The principle of construction of generators 20 and 21 packs of synchronous pulses of the probing current does not affect the essence of the invention.

 The detector 25 can be performed, for example, in the form of a conventional precision detector on operational amplifiers. However, the best option is to implement block 25 in the form of a synchronous detector, synchronized by the frequency of the pulses generated by the generator 33.

 Block 15 low-pass filters can be made, for example, in the form of passive RC circuits, the passband of which is selected above the upper frequency in the spectrum of the analyzed biopotentials, but lower than the pulse frequency of the probe current generated by the generators 21 and 22.

 The low-pass filter 26 has a passband not exceeding a few hertz, and the band-pass filter 27 has a passband usually from fractions to tens of hertz.

 The construction of the remaining blocks of the device can be performed according to known schemes. In particular, the processing and registration unit 19 can be made in the form of a personal computer.

 The proposed device for the integral assessment of the functional state of the cardiovascular system works as follows.

 Electrodes 1, ..., 6 and 7, ..., 10 for biopotential removal are installed on the chest 28 and limbs 29,., 32 of the patient and connected to the measuring circuit as in conventional electrocardiographic studies. The electrodes 11, 12 and 13, 14 are installed on the limbs 29, ..., 32 in the same way as in the case of rheographic studies, electrodes are installed to supply the probing current (see Fig. 2).

 The signals taken from the electrodes 1,., 10, are fed to the inputs of the multi-channel amplifier 16 through the low-pass filter unit 15, which filter out the high-frequency signals generated when the probe current generated by the generators 21 and 22 flows through the patient’s body. An additional reduction in the influence of high-frequency voltage in The proposed device is achieved by choosing a significant relationship between the repetition period of the bursts of synchronous pulses of the probe current and the duration of the bursts of these pulses. The signals filtered from the high-frequency interference associated with the probing current flowing through the patient’s body are amplified by a multi-channel amplifier 16, sequentially interrogated by a multiplexer 17, converted by an analog-to-digital converter 18, and transmitted to the processing and registration unit 19 in a digital code. During the passage and processing of signals taken from the electrodes 1, ..., 10, the well-known leads form the conventional leads used in electrocardiographic studies, they are analyzed, displayed and recorded. In this case, the possibility of the correct formation of generally accepted leads is ensured by the absence of an electrical connection of the electrodes 7 and 8, which is produced during rheographic studies according to the classical scheme.

 Simultaneously with conducting electrocardiographic studies, the signals taken from electrodes 7 and 9, as well as from electrodes 8 and 10, are amplified by AC differential amplifiers 22 and 23, summed in block 24, detected by block 25, and filtered by blocks 26 and 27. Signals from outputs filters 26 and 27, proportional respectively to the basic resistance of the patient’s body and its pulse component, are interrogated by multiplexer 17, converted by an analog-to-digital converter 18, and in a digital code enter the processing unit 19 records and records in which they are analyzed, displayed and recorded. The proposed rheogram removal scheme is practically equivalent to the rheogram removal scheme with shorted electrodes 7 and 8, but it does not distort the signals used in electrographic studies. The implementation of the detector 25 in the form of a synchronous detector further reduces the effect of electrocardiographic signals on the results of rheographic studies.

 Thus, the proposed device provides the ability to simultaneously remove the electrocardiogram and integral rheogram of the body from the same electrodes applied to the limbs of the patient. This, in turn, makes it possible to reduce the time of investigation of the state of the patient's cardiovascular system and increase the information content of studies.

 Industrial applicability of the invention is determined by the fact that the device can be manufactured on the basis of the above description and drawings and used to diagnose the state of the cardiovascular system.

Sources of information
1. Auth. testimonial. USSR N 1755790, IPC A 61 B 5/05, publ. 08/23/92

 2. Yu.N. Volkov et al. Comprehensive assessment of the functional state of the circulatory and respiratory system by the method of integral body rheography (Methodical recommendations). Ministry of Health of the USSR, M. - 1989, p. 21.

 3. Mike Curtin. Sigma-delta techniques reduce hardware count and power consumption in biomedical analog front ends. Analog dialoge 28-2, 1994, pp. 6-7 (prototype).

Claims (3)

1. A device for assessing the functional state of the cardiovascular system, containing electrodes for taking biopotentials from the patient’s chest, electrodes for taking biopotentials from the patient’s limbs, a multi-channel biopotential amplifier, a low-pass filter unit, a multiplexer, an analog-to-digital converter, a processing unit connected in series and registration, characterized in that the first and second generators of bursts of synchronous pulses of the probing current, the first and second electrodes for dosing of the probe current to the upper limbs of the patient, electrically connected to the first terminals of the first and second generators of synchronous pulses of the probe current, the first and second electrodes for supplying the probe current to the lower limbs of the patient, connected to the second terminals of the first and second generators electrically connected to each other synchronous pulses of probing current, the first and second differential AC amplifiers, the first inputs of which are connected to the electrodes I take biopotentials from the upper limbs of the patient, and the second inputs of the differential amplifiers are electrically connected with each other and electrodes for taking biopotentials from the lower extremities of the patient, an adder whose first and second inputs are connected to the outputs of the first and second differential AC amplifiers, a detector whose input connected to the output of the adder, a low-pass filter and a band-pass filter, the inputs of which are electrically connected to each other and connected to the output of the detector, while the inputs are low pass filter eyes are connected to electrodes for removing biopotentials from the patient’s chest, electrodes for removing biopotentials from the patient’s upper limbs and electrodes for collecting biopotentials from the patient’s lower extremities, the outputs of the low-pass filter block are connected to the corresponding inputs of the multi-channel biopotential amplifier, the multiplexer inputs are connected to the outputs of the multi-channel biopotential amplifier, low-pass filter output and bandpass filter output ra, while the repetition period of the packets of synchronous pulses of the probe current is at least ten times the duration of the packets of synchronous pulses of the probe current, the frequency of which is (10-100) • 10 ³ Hz.  2. The device according to claim 1, characterized in that each generator of bursts of synchronous pulses of the probing current is made in the form of a voltage-current converter, while a generator of bursts of pulses is introduced into the device, the output of which is connected to the input of each voltage-current converter.  3. The device according to claim 2, characterized in that the detector is made in the form of a synchronous detector, the control input of which is connected to the output of the pulse packet generator.

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