RU2153842C1 - Mean arterial pressure monitor - Google Patents

Abstract

FIELD: medical equipment, in particular, devices monitoring the level of arterial pressure for a long period of time. SUBSTANCE: mean arterial pressure monitor has a case accommodating a biosignal generating unit connected to a recording and analysis unit based on an analog-to-digital converter, microcomputer and a liquid crystal indicator. The memory unit is connected to the recording and analysis unit, and the biosignal generating unit is made in the form of electrocardial signal transducers connected to an electrocardial signal amplifier, and photodetectors with a device for attachment on a patient's finger or ear, connected to the generators of the first derivative of the pulse signal. EFFECT: enhanced accuracy of measurements of mean arterial pressure. 2 cl, 1 dwg

Description

 The invention relates to medical equipment, in particular, to devices that monitor the level of blood pressure for a long period.

 Known devices that record the level of blood pressure (BP) during the day without the help of a compression cuff, based on measuring the propagation time of the pulse wave (VRPV), which, in turn, has an inverse relationship with blood pressure. The obvious advantage of such devices is their work without mechanical impact on the subject, which makes it possible, at least an order of magnitude more often, to carry out measurement cycles, and, on the other hand, to continue measurements as long as you like. An example of such devices is the BP-100 and HBP-500 type blood pressure meters (Casio, Japan), made in the form of wrist and pocket watches and intended only for self-monitoring in the home.

 However, they are not in the true sense of blood pressure monitors, because they cannot continuously display the specified parameter and can be used as medical devices.

 Closest to the claimed device is a NCCOM monitor (BoMed, USA), described in US patent N 4807638 (Cl. MKI A 61 B 5/02, publ. 02.28.1989).

The monitor includes two amplifiers of a rheographic signal, a processor, a device for displaying the current pressure level and an interface for accessing a personal computer. Using the first rheo-amplifier, the moment of occurrence of a pulse wave in the aortic root is determined, the stroke volume (blood ejected by the heart in one reduction) is determined by the same rheographic signal. 4 electrodes are placed on the chest and neck of the patient. With the help of a second rheographic amplifier, the moment of occurrence of a pulse wave on the leg of the subject is determined. The processor measures the VLF between the first electrode overlay and the second. Using the value of stroke volume calculated by the known formula Kubicek (1966), the distance between the electrodes, measured in advance, the processor from the empirical formula, the binding value of the stroke volume of the heart and the pressure increase in the aorta, calculates the mean arterial pressure (BP _avg).

The disadvantages of the described device are:
1. The use of the rheographic method of registering a pulse signal sensitive to the slightest movement of the patient, which excludes the use of the monitor in the patient’s free behavior mode;
2. Application for calculating the Kubitschek formula, which did not confirm the necessary measurement accuracy [1 All-Union impedance measurement congress. Theses of reports, Izhevsk, 1991].

 3. The lack of internal memory in the monitor, the need for constant communication with the computer.

 The objective of the proposed solution is to expand the class of instruments for measuring average blood pressure with enhanced amenities and accuracy.

 The essence of the claimed invention lies in the fact that the memory block is inserted into the average blood pressure monitor containing a biosignal forming unit connected to a recording and analysis unit based on an analog-to-digital converter (ADC), a micro-computer and an indicator, connected to the registration and analysis unit, and the biosignal generation unit is made in the form of electrocardiogram (EX) sensors connected to an EX amplifier, and a photosensor with a fastening device on the patient’s finger connected to driver of the first derivative of the pulse signal.

 An additional variant of the inventive monitor is the presence in the biosignal generating unit of a second photosensor with a fastening device on the patient’s ear and a second driver of the first derivative of the pulse signal.

 An additional convenience in the claimed monitor is the presence on its case of a command device in the form of a “command” button for arbitrary measurement of the mean arterial pressure and recording of a fragment of the patient's electrocardiogram (ECG) in the memory unit.

 Introduced into the inventive device, a memory unit is used to digitally store the results of measuring the average blood pressure and ECG fragments for their further input into a personal computer for viewing, statistical analysis, archiving and recording by the doctor of the monitoring results.

The use in the biosignal forming unit of the inventive device of an EX-signal amplifier with three miniature EX-sensors located on the patient’s chest and a first derivative of the pulse signal with a photosensor fixed on his finger made it possible to use the R wave of the electrocardiogram and the first maximum of the pulse wave to start and end reference VRPV, respectively. To calculate the value of blood pressure and _compare the principle of the formula set out in the Author's Certificate USSR N1445689, cl. A 61 B 5/02, [publ. 12/23/88, Bull. N47] and publications: [Bugram R. Eine Methode zur Bestimung des Pulsewellelaufzeit. Aut.-Biomed. Tech., 1994, Bd 39, ss 51-56], [N. Lutter. Noninvasive continuous blood pressure control by pulse wave velocity. Zeitschrift Fur Kardiologie, 1996, Bd 85, ss 124-126].

 The second driver of the first derivative of the pulse signal inserted into the biosignal forming unit of the claimed device, connected to the photosensor equipped with a fastening device on the patient’s ear, allows, firstly, to use the pulse signal recorded on the patient’s ear to start the VRPV measurement, when the tooth R ECG is not expressed due to, for example, cicatricial changes after myocardial infarction, secondly, to monitor myocardial contractility by calculating the Weissler index, using an assessment of the duration of the voltage phase and the phase of the expulsion of the left ventricle of the heart, determined by the characteristic points of the ECG and two pulse signals [Patent for invention RU 2106792 C1, cl. A 61 B 5/02, publ. 03/20/98, Bull. N8].

 The presence of a “command” button on the monitor case allows measurement of the mean arterial pressure at arbitrary points in time and at the same time records a fragment of a paroxysmal ECG of a specified duration in the memory unit for further input into a personal computer for viewing and analyzing heart rate variability, which is currently time is a recognized standard of the functional state of the cardiovascular system [Heart rate variability. Standards of measurement, physiological interpretation and clinical use. - European Heart Journal, 1996, p. p. 354 - 381]. This is done by calculating the RR intervals from the digitized ECG record and the subsequent statistical and spectral analysis of the obtained time series.

 The invention is illustrated by the drawing, which shows the inventive device, where: 1 is a patient biosignal generating unit, consisting of an ECG signal amplifier (2), shot by three disposable contact electrodes (R, L, N), and two identical photodetector devices (FPU) ( 3 and 4), forming the first derivative of the pulse signal from the photosensors, 5 - registration and analysis unit, based on a single-chip micro-computer, multi-channel ADC and random access memory (RAM); 6 - memory block; 7 - button - "command"; 8 - indicator block; 9 - RS232 interface unit for data exchange with a PC; 10 - electronic key for auto power off of input analog circuits in the pauses between measurements; 11 - converter voltage; 12 - small-sized acoustic transducer for the supply of warning sound signals of the beginning and end of measurement.

At the beginning of the measurement cycle, during the first 60 s, the analog signals from the bio-amplifier block are fed to the inputs of the switch of the 8-bit ADC of the TN87C51GB microcircuit, operating with a quantization frequency of 1000 Hz, which is necessary to ensure the measurement error of the VRPR ± 1 ms, and converted into a digital data stream, temporary which storage takes place in RAM. Then the processor calculates the average value of the VLW and the absolute value of HELL _cf from the digitized records of the pulse wave and ECG stored in RAM, and transcribes it to the RPZU. After the completion of the measurement cycle, the processor automatically turns off the power of all circuits and switches to energy saving mode until the next measurement cycle. By clicking on the patient button- "command" simultaneously with the measurement of the mean blood pressure and calculating VDPV _cf. performed post in EPROM fragment paroxysmal ECG set duration, digitized with a sampling rate of 250 Hz.

At the beginning of work, using the personal computer, the frequency and duration of the measurement cycles of VLF and paroxysmal ECG fragments (depending on the medical task), the setting flags for the method of determining the VLR, the supply of warning sound signals of the beginning and end of the measurement and the indication of the measurement results are programmed using the serial interface ZhKI, as well as an individual empirical coefficient for determining the absolute value of arterial pressure _avg from the patient's VRP, calculated according to preliminary calibration by the doctor of blood pressure with a cuff tonometer before installing the monitor. The frequency of measurements of blood pressure _avg is usually selected in the daytime - every 30 minutes or 1 hour, at night - every 2 hours. The volume of the RPZU is designed to record from 2 to 16 fragments of a paroxysmal ECG with a total duration of 16 minutes at a sampling frequency of 250 Hz.

After closure monitoring set of measured data is transmitted to the computer, where it calculates the values of blood pressure _Wed, statistical parameters of heart rate variability estimation, deciphering the recorded paroxysmal ECG fragments are plotted BP profile _cp and the main parameters adopted for the analysis of the pressure dynamics and the patient's cardiac rhythm in cardiological practice.

 An example of a constructive implementation of the proposed solution.

The monitor contains the above nodes. The registration and analysis unit in it is made, for example, on the basis of a single-chip microcomputer with an 8-channel 8-bit ADC in integrated design (TN87C51GB chip from Intel) and RAM chip 128K (UM621024C-70LL from UMC). The memory block is made, for example, on the basis of a re-programmable read-only memory device with serial data exchange E ² PROM with a capacity of 32K (8 Atmel AT24C256 chips). The indicator block is made, for example, on the basis of an alphanumeric 1-line 8-character LCD with an integrated controller HD44780 (model HDM08116 from HANTRONIX Inc.).

An example of the application of the proposed solution in clinical practice. Patient S., 48 years old. Diagnosis: coronary heart disease, class III angina, hypertension. 10/12/98 he underwent 24-hour blood pressure monitoring using a portable cuff monitor TM-2421 (AND, Japan), included in the top five instruments according to the standards AAM1 and BHS [O'Brien E. et al. A review of ambulatory blood pressure monitoring devices. Hypertention, 1995, v. 26, pp 835-842]. In parallel with this, the patient had cuffless monitoring of mean blood pressure using a prototype of the inventive device (weight not more than 500 g). Measurements on both instruments were carried out at the same hours of the day: during the day with an interval of 30 minutes, at night - 1 hour. A total of 42 measurements were taken. The average blood pressure per day on the TM-2421 monitor was 123 mmHg, on the inventive device - 125 mmHg. The pair correlation coefficient between the two daily profiles of blood pressure _avg was very high and equal to 0.86. In addition to this command by the patient in 12: 30 and 16:45 in the memory device of the claimed two fragments ECG duration of 5 min were recorded on one of which ischemic ST segment variation was observed, which coincides in time with a significant rise in blood pressure _cp to 147 mm Hg .art. The analysis of the dynamics of myocardial contractility based on the Weissler index measured by the inventive device showed an insufficient range of regulation of cardiac contraction force at the moments of myocardial overload. All this made it possible for the attending physician to more fully assess the degree of coronary circulation disturbance in this patient.

Claims (2)

 1. The average blood pressure monitor comprising a biosignal forming unit placed in the housing and connected to a recording and analysis unit based on an analog-to-digital converter, a microcomputer and an indicator, characterized in that a memory unit connected to the recording unit is inserted into it and analysis, and the biosignal generation unit is made in the form of electrocardiogram (EX) sensors connected to an EX amplifier and two photosensors with fastening devices, one on the finger and the other on the patient’s ear, each of which connected to the corresponding drivers of the first derivative of the pulse signals.  2. The monitor according to claim 1, characterized in that it has a command button displayed on the housing for randomly measuring the mean arterial pressure and recording a fragment of the patient’s electrocardiogram in a memory unit.