RU2328210C2 - Method and device for tonometer calibration using patient body simulator - Google Patents

Abstract

FIELD: medicine; diagnostics.

SUBSTANCE: tonometer is calibrated using mechanism - patient body simulator - instead of patient organ with preliminary evaluation of simulator calibration factor. Calibration factor of calibrated tonometer is evaluated. It depends on simulator hydraulic pressure value measured using calibrated tonometer with pumped up cuff on simulator. Device consists of patient body simulator shaped as patient organ using to measure blood pressure and pulse, liquid supply tube, liquid supply capacity, potential hydraulic pressure sensor, liquid supply capacity pressure, liquid receiver.

EFFECT: lowered number of tonometer calibration errors.

2 cl, 1 dwg

Description

The invention relates to the field of tonometer calibration, and in particular to methods and devices for calibrating devices for measuring blood pressure and pulse using a patient simulator.

Tonometers for measuring blood pressure and heart rate can give measurement errors. One of the reasons for this is the lack of methods and devices for simple, reliable and cheap calibration of these devices after their manufacture and during operation.

Methods and devices for tonometer calibration are based on comparing the results of measurements on the patient’s organ with blood pressure and pulse determined by the calibrated tonometer with the results obtained with a calibrated tonometer or experimental calculation methods.

The known "Method and device for determining the need for calibration of the blood pressure measurement system", US patent No. 6,852,083 B2, dated February 8, 2005, which proposes a method and device for determining blood pressure by creating disturbances propagating along the patient’s artery, and calculating the dependence from the time of changes along the patient’s artery, blood pressure, pulse, blood speed and other parameters, taking into account the properties of blood vessels. When it is implemented, 3 cuffs are put on the patient’s hand: on the brachial artery, on the radial artery of the wrist and the third cuff is put on between them. The last cuff serves to create disturbances, and with the help of the extreme cuffs, a passing continuous wave traveling along the patient’s artery is recorded.

The disadvantages of this method and device are the complexity and high cost of the tonometer calibration process, a possible error when using the approximate calculation and experimental method for determining the parameters of blood flow and blood pressure in a blood vessel, as well as the use of a patient’s organ for calibration, the parameters of which can be unstable.

The closest solution adopted for the prototype is US patent No. 6.662.130 B1 dated December 9, 2003, "Method and device for calibrating a distorted signal using a calibrated signal", which proposed a method and device for calibrating tonometers using a calibrated tonometer. At the same time, both tonometers measuring blood pressure and pulse are placed on one patient’s hand, only a calibrated tonometer is located on the brachial artery, and calibrated - on the radial artery of the wrist. The change in physical parameters and blood pressure in the artery between the measured sections is determined, and by comparing the calculated and measured values, the calibration coefficient of the calibrated tonometer is found.

The disadvantage of this method of calibrating tonometers is the possible error in calculating changes in physical parameters and blood pressure in the patient’s arteries between the sections in which the cuffs are located. In addition, the parameters of the patient’s organ, on which blood pressure and pulse are measured, depend on the patient’s state of health, which can change during tonometer calibration, which will introduce an additional error in the calibration. Another disadvantage of this method and device are the complexity and high cost of calibration.

The objective of the proposed solution is to simplify, reduce time and reduce the cost of calibrating tonometers, as well as reducing the error in calibrating tonometers by using a patient simulator instead of the patient organ previously used for this purpose, whose characteristics may be unstable. Unlike the patient’s organ, the patient simulator is a technical device that can be performed with characteristics that are stable during the entire operation.

Therefore, when using it, there will be no need to compare the readings of a calibrated and calibrated tonometer, which was carried out earlier, and the process of calibrating a tonometer will be reduced to measuring blood pressure and heart rate with a calibrated tonometer on a pre-calibrated patient simulator. A highly accurate calibration of a patient simulator, achievable at the current level of development of medical technology, performed once, will allow the use of a patient simulator for high-precision calibration of a large number of calibrated blood pressure monitors. This will reduce time and simplify the calibration process, as well as reduce its error and cost.

In the proposed method, the result is achieved due to the fact that when calibrating tonometers instead of the patient’s organ, a patient simulator is used, made in the form of a patient’s organ, on which blood pressure and pulse are measured, and the patient simulator is capable of exciting pulsations of fluid pressure, and the calibration coefficient with a simulator the patient is determined by the magnitude of the fluid pressure in the tube with the fluid connected to the fluid volume of the patient simulator, while the measurements are carried out using a cuff worn on the simulator OR patient.

Also, the result is achieved in the inventive device due to the fact that instead of the patient’s organ, the patient’s simulator is used to calibrate the tonometers, made in the form of the patient’s organ, on which blood pressure and pulse are measured, equipped with a tube located on it with a liquid connected with the volume of the liquid, a sensor static fluid pressure, a sensor for fluctuations in fluid pressure in the volume with liquid and a receiver with liquid.

The patient simulator is a technical device consisting of elements that have constant properties that are independent of temperature, pressure and humidity, as well as psychological factors, and therefore its characteristics are stable throughout the calibration time. Therefore, during the calibration of blood pressure monitors, fluid pressure and fluctuations in fluid pressure in the volume with the liquid and in the tube with the liquid, simulating the blood pressure and pulse of the patient, are considered constant.

In the analogue, a patient’s organ is used for this purpose, in which, unlike the patient’s simulator, blood pressure and pulse can change during calibration under the influence of changes in temperature, pressure and humidity of the atmosphere, fatigue, mood and health of the patient. In addition, the calculation methods proposed in the analogue, which refine the blood parameters at the place of measuring blood pressure and pulse on the patient’s organ, are less accurate than direct measurements of these characteristics using a static pressure sensor and a pressure fluctuation sensor in the proposed patient simulator. It is naturally impossible to conduct direct measurements of these characteristics in the blood vessels of the patient’s organ, since this would require surgical intervention in the patient’s blood system.

If the calibration coefficient is not constant and depends on changes in the fluid pressure and / or fluctuations in the fluid pressure in the patient simulator, then a calibration function is used instead, depending on the fluid pressure and / or fluctuations in the fluid pressure in the patient simulator. For example, a fluid pressure calibration function, an upper or lower fluid pressure calibration function is used for a patient simulator or for a calibrated tonometer. In the patient simulator, a continuous medium can be used as a liquid, in which, for example, the density and viscosity are close to the density and viscosity of the blood, and / or the suspended particles contained in it have a concentration, shape and density the same as that of particles contained in the blood .

To reduce the calibration error associated with the dissimilarity of the properties and positions on the patient simulator of the inflated cuff of the calibrated tonometer and the calibrated tonometer, you can use one inflated cuff worn on the patient simulator, to which, when determining the calibration coefficient of the patient simulator, a calibrated tonometer is connected, the readings of which are taken as the standard and when determining the calibration coefficient of the calibrated tonometer, a calibrated tonometer is connected.

To excite pulsations of the fluid pressure in the patient simulator, instead of mechanically compressing the volume with the fluid by moving the moving part of the body relative to the fixed part of the body by means of an electric drive with an eccentric and a lever, you can use propulsors that create reciprocating movements of the moving part of the body, using, for example, compressed gas energy or magnetic forces.

Instead of the proposed closed volume with a liquid and a closed tube with a liquid, for example, devices with valves can be used to circulate a pulsating liquid in a volume with a liquid and in a tube with a liquid.

The drawing shows a diagram of a device for calibrating tonometers using a patient simulator. The device in the drawing contains a patient simulator 1, which has a body 21 made in the form of a patient’s organ, on which blood pressure and pulse are measured, a tube with a liquid 3 located on it, connected with a volume with a liquid 4 and a receiver with a liquid 9 with a liquid level 8 having a crane 18, a static pressure sensor 5 in the volume with liquid 4, a pressure fluctuation sensor 6 in the volume with liquid 4, as well as a fixed part of the body 7 of the volume with liquid 4 in contact with the volume of the liquid 4 and a moving part of the body 16 of the volume with liquid 4 with this the movable part of the housing 16 is connected to a lever 12 having an axis of rotation 10 with a direction of rotation 11, driven through an eccentric 14 with an electric drive 15 with a speed regulator 20, having a direction of rotation 13 of the eccentric 14 and a direction of movement 22 of the axis of rotation 10, and also contains a tonometer 2 with an inflated cuff 17 and the processing unit of the measurement results 19.

The operation of the device for calibrating tonometers using a patient simulator in the drawing is as follows. Open the valve 18 and fill the receiver with liquid 9, the volume with liquid 4 and the tube with the liquid 3 with liquid. To do this, place the receiver with the liquid 9 so that the volume with the liquid 4 turns up 18 to let the air out. After filling with liquid, close the valve 18 and everything is returned to its original position.

Open the valve 18 and adjust the lower pressure of the liquid in the volume with the liquid 4 by the sensor of the static pressure of the liquid 5 by moving the receiver with the liquid 9 in the direction of changing the liquid level 8. After the adjustment of the lower pressure of the liquid is finished, the valve 18 is closed. The electric drive 15 with a speed controller 20 rotates the eccentric 14 in the direction of rotation 13, while the lever 12 rotates about the axis of rotation 10 in the direction of rotation 11, and the movable part of the housing 16 makes reciprocating movements relative to the fixed part of the housing 7 and periodically compresses the volume with liquid 4, the shell of which is made of flexible material, generating fluid pressure fluctuations in the volume with the liquid 4. The amount of movement of the movable part of the housing 16 determines the level of the upper liquid pressure compared to the lower liquid pressure in the patient simulator 1. The upper liquid pressure is controlled by moving the pivot axis 10 relative to the lever 12 in the direction of arrow 22 and during adjustment the liquid pressure is monitored by the static pressure sensor 5. Oscillation frequency the pressure in the volume with the liquid 4 is regulated by a speed regulator 20 and is controlled by a pressure fluctuation sensor 6 in the volume with the liquid.

When calibrating the patient simulator 1, the calibration coefficient of the patient simulator 1 is determined using, for example, the pressure of the liquid in the liquid tube 3, measured using a calibrated tonometer 2 with its inflated cuff 17, worn on the body 21 of the patient simulator 1, the readings of which are taken as a reference, and the pressure of the liquid in the tube with the liquid 3 associated with the volume with the liquid 4, measured by the static pressure sensor 5.

When calibrating the calibrated tonometer 2, the calibration coefficient of the calibrated tonometer is determined using, for example, the pressure of the liquid in the liquid tube 3, measured using a calibrated tonometer 2 with its inflated cuff 17, worn on the body 21 of the patient simulator 1, and the pressure measured by the static pressure sensor 5 in a tube with a liquid 3, connected with a volume with a liquid 4, while processing the measurement results is carried out using the processing unit of the measurement results 19.

Currently, when calibrating tonometers, a forearm, a wrist, a finger, or some other organs of a patient are used to compare the results of measurements with a calibrated tonometer and a calibrated tonometer and to determine the calibration coefficient of a calibrated tonometer. However, methods for calibrating tonometers using a patient’s organ are complex, expensive, and inconvenient. In addition, blood pressure and heart rate depend on the patient’s state of health, and therefore can be unstable, which will lead to an additional calibration error for tonometers.

The proposed method for calibrating tonometers is based on the use of a patient simulator instead of a patient’s organ, which must first be calibrated using a calibrated tonometer, the readings of which are taken as a standard, or a more accurate calculation and experimental method for measuring blood pressure and heart rate. Since the patient simulator is a technical device with more stable characteristics than the patient’s organ, its use will simplify the calibration process, reduce time and cost, and also reduce the calibration error of tonometers.

Claims (2)

1. A method for calibrating tonometers, namely, that a calibrated tonometer with an inflated cuff, the readings of which are taken as a standard, measure blood pressure and pulse with a calibrated and calibrated tonometer, determine the calibration coefficient of the calibrated tonometer and enter the calibration coefficient of the calibrated tonometer in the processing unit of the measurement results calibrated tonometer, characterized in that when calibrating using a patient simulator made in the form of a patient’s organ, on which pressure is measured blood pressure and pulse, moreover, the patient simulator is configured to excite pulsations of the fluid pressure, and the calibration coefficient with the patient simulator is determined by the value of the fluid pressure in the tube with the fluid connected to the fluid volume of the patient simulator, while the measurements are carried out using a cuff worn on the simulator the patient. 2. A device for calibrating tonometers, including a calibrated tonometer, the readings of which are taken as a standard, an inflated cuff, a calibrated tonometer and a unit for processing the results of measurements of a calibrated tonometer, characterized in that a patient simulator made in the form of a patient’s organ on which pressure is measured blood and pulse, equipped with a tube located on it with a liquid associated with the volume with the liquid, a sensor for static pressure of the liquid, a sensor for fluctuations in the pressure of the liquid in the volume with the liquid and receiver with liquid.