DE3644213A1 - Device for continuously monitoring blood gases - Google Patents

Abstract

A device for continuously monitoring blood gases, with which blood is aspirated continuously from an external circulation, is used for measuring gases and ions dissolved in the blood by means of electrochemical sensors. The device contains an electromagnetic control device, a rotary control valve, a thermostat container and a microcomputer. The rotary control valve contains a stator element having bearing elements arranged in a flat block core, having a plurality of flow paths arranged in a concentric circle around the outer surface of the bearing element, sealing elements provided in the flow paths to seal them off, and a rotor element having flow paths corresponding to the flow paths of the stator element, and having profile channels, as well as a device which is set in rotary motion by a drive, motor or the like. The flow paths of five positions, such as washing, preparation, calibration, measurement and final position, are individually formed by a combination of rotary positions of the rotor element, as a result of which on-line measurement of the pH and of the partial pressures of the CO2 and O2 gases dissolved in the blood is continuously possible and the formation of thrombi is prevented.

Description

The invention relates to a device for the continuous monitoring of blood gases, with which blood is continuously sucked from an extracorporeal circuit and dissolved gases in the blood are measured by means of an electrochemical sensor, consisting of an electromagnetic actuating device with a plurality of electromagnetic valves for changing the flow paths of one Calibration solution, a calibration gas, a washing solution, a physiological salt solution and air, a rotary control valve with a plurality of components, which is connected to the electromagnetic control device with an outflow opening, in order to selectively switch between the flow paths of the fluids and a blood sample and to supply these fluids to sensors, a thermostatic tank with a probe for pH and for CO ₂ and O ₂ partial pressures and a bubble generator that keeps the measuring environment at a constant temperature, and a microcomputer to carry out the work process ens and the successive checking of the measurement data of the sensors.

The device is used for the continuous measurement of blood gases and thus used to indicate the status of a patient a heart surgery, especially when using a extracorporeal circulatory system with an artificial lung is carried out.

Continuous measurement methods for determining the blood values are known, such as the measurement of the K⁺ concentration in an external blood circulation (HF Osswald et al in CLINICAL CHEMIESTRY, 25-1, 39/43 (1979)), the measurement of K and the pH Values in an extracorporeal circuit (Toya et al in Journal of the Japanese Association of Automation of Clinical Inspection, Supplementary Volume, 5-3, 14/19 (1980)), the measurement of the pH and the partial pressure of CO ₂ by means of ISFET (Matsuo et al in Medical Electronic Living Body Engineering Data MBM of the Telecommunication Association, 79-81 (1981)), the continuous measurement of glucose in a portable artificial spleen (Nanasato et al in Artificial Organ, 9, 1094 (1980)) and the universal device for the continuous control of blood for the determination of glucose, the partial pressures of O ₂ and CO ₂ , of Na⁺, the pH and of K⁺ (Gonda et al in Artifical Organ, 10, 6 (1981)).

During heart surgery, especially when using it an extracorporeal circulation and an artificial lung, rapid changes in the gas composition of the blood occur and there are large fluctuations in the composition. Here measurements of the gas composition are essential. For now the blood is tested at irregular intervals and the measurement solutions are performed by a blood gas analyzer, whereby this method of measurement does not lead to satisfactory results.

No system suitable for measuring the three values necessary for the extra corporeal circulation, namely the pH value and the partial pressures pCO ₂ and pO ₂ , has yet been put into practical use. Furthermore, in devices that have sensors to be inserted into the patient's body, thrombi form on the surface of the sensors, which requires unsatisfactory continuity and accuracy of the measurement and causes a large change in the sensors. In addition, the shelf life of small sensors is short, which has a negative impact on running costs.

The invention is therefore based on the object, a Vorrich device for the continuous monitoring of blood gases len, with the display of rapid changes in the body data  The stability of the circulation during surgery was improved sert, and by automating the device the time is shortened for data acquisition.

According to the invention this object is achieved in that the control valve has a stator element, with a bearing element arranged in a flat block core, a plurality of flow paths which are arranged in a concentric circle around the outer surface of the bearing element, and sealing elements provided in the flow paths for Sealing the same, a rotor element with flow paths corresponding to the flow paths of the stator element and with profile channels, and a device or the like via a drive of a motor. is rotatable, flow paths in five positions, such as washing, preparing, calibrating, measuring and final position, are formed individually by combining the rotational positions of the rotor element and an on-line measurement of the pH and the partial pressures of the CO dissolved in the blood ₂ - and O ₂ gases continuously detected without causing thrombus formation in the flow paths and without interrupting the blood test.

The device according to the invention is designed such that in the washing position all flow paths are cleaned, in the preparation position the stabilization of the basic parameters of the pO ₂ sensor is accelerated, in the calibration position blood can flow through the bypass line to prevent the blood sample from clotting in the measuring position, the blood sample is mixed with the physiological saline solution at the end of the drain line for waste materials, in order to prevent coagulation of the blood and contamination of the flow paths at the end of the drain line, and in the end position drying out of the pCO ₂ and pO ₂ sensors and preventing the electrolyte from concentrating, maintaining the effectiveness of the sensors and preventing changes in the sensors and contamination of the flow paths.

Further details and features of the invention emerge from the following description, in which with reference to the drawing explains a preferred embodiment in more detail is. Show:

Fig. 1 is a block diagram of the system of the present invention;

Fig. 2A-2E diagrams showing the flow paths of the rotary control valve in different valve positions;

Fig. 3 is a perspective view of the rotary control valve, showing the flow paths in the measuring position according to Fig. 2D;

Fig. 4 shows a cross section through the rotary control valve;

Fig. 5A is a front view of the pneumatic Thermostatbe container and

FIG. 5B shows a section VB-VB through the container according to FIG. 5A.

Fig. 1 shows a block diagram of the system of the present invention. With ( 1 ) an insertion opening for blood samples is designated and with ( 2 ) a rotation control valve, the stator elements ( 2 S - 1 , 2 S - 2 and 2 S - 3 ) with flow paths and rotor elements ( 2 R - 1 , 2 R - 2 and 2 R - 3 ). The stator elements ( 2 S - 1 , 2 S - 2 and 2 S - 3 ) have inflow openings ( 2 a , 2 b , 2 c and 2 d) and outflow openings ( 2 A , 2 B , 2 C and 2 D) , and the flow paths of the five positions, namely washing, preparing, calibrating, measuring and switching off, which are formed by combining the rotary positions of the rotor elements ( 2 R - 1 to 2 R - 3 ), which will be discussed below.

With ( 3 ) a pneumatic thermostat container is called, which represents a measuring chamber, the temperature range between 37 ± 0.1 ° C is regulated to achieve a high measuring accuracy. The sensors are designated ( 4 , 5 and 6 ) and ( 7 ) represents a bubble generator which is arranged in the thermostatic container ( 3 ) in order to humidify gases ( 8 and 9 ) for calibrating the sensors.

In the illustrated embodiment, the sensor ( 4 ) for determining the partial pressure of carbon dioxide (pCO ₂ ), the sensor ( 5 ) for determining the partial pressure of oxygen (pO ₂ ) and the sensor for determining the hydrogen ion concentration (pH) is used. ( 10 ) denotes a pump for conveying the fluids, which is arranged downstream and with which a blood sample ( 1 ), a washing solution ( 11 ), a physiological salt solution ( 12 ), a calibration solution ( 13 ) and a calibration solution ( 14 ) is sucked in. With ( 15 ) is a manifold line and ( 16 ) denotes a bottle for waste materials. With ( 17 ) an electromagnetic actuator is referred to, with which the flow paths of the washing solution ( 11 ), the physiological salt solution ( 12 ), the calibration solutions ( 13 and 14 ), the reference gases ( 8 and 9 ) and air ( 18 ) changed will. With ( 19 ) an electromagnetic valve is designated, which is arranged after a certain distance of the flow path ( 20 ) between the sensor ( 5 ) and the pump ( 10 ). This electromagnetic valve ( 19 ) is open during the calibration of the sensors ( 4 and 5 ) so that the calibration gas can escape. With ( 21 ) a temperature controller for the Thermostatbe container ( 3 ) is designated, which is provided for regulating the temperature within the thermostat container ( 3 ) to 37 ± 0.1 ° C.

With ( 22 ) is a preamplifier for the sensors ( 4 , 5 and 6 ) and with ( 23 ) is a unit for processing analog signals and with ( 24 ) a controller for the rotary control valve ( 2 ) be. On commands from a microcomputer ( 25 ), the controller ( 24 ) is addressed to open and close the corresponding valves of the electromagnetic actuating device ( 17 ) and to control the rotary movement of the rotary control valve ( 2 ). With ( 26 ) a printer is referred to, which prints the measurement results, sample number and the times prepared by an A / D converter between the unit ( 23 ) for processing analog signals and the microcomputer ( 25 ) at certain time intervals. With ( 27 ) an analog connection for an external recording device (not shown) is designated, with which changes in the measured values are recorded continuously. With ( 28 ) is designated a digital display device with which the measured values for pCO ₂ , pO ₂ and pH are displayed. With ( 29 ) a device is designated, with the measuring intervals, the temperature and the current time are displayed, and ( 30 ) represents a control panel.

In FIGS. 2A to 2E positions of the flow paths within the rotating control valve (2) are shown. Here, 2A, FIG. The washing position where a washing line (2 A), a Meßfühlerleitung (2 C) and a Meßfühlerleitung (2 D) with an inflow (2 a) are connected to a bypass line (2 B) having an inflow line ( 2 b) is connected, and and fluids such as a wash solution, a physiological saline solution and air, through the inflow conduits (2 a and) flow 2 b to the washing line (2 a), the bypass line (2 B) the Meßfühlerleitungen (2 C and 2 D) and the sensors ( 4 , 5 and 6 ). The air is used to increase the cleaning effect by alternately entering washing solution and air.

Fig. 2B shows the preparation position in which the rotor element ( 2 R - 2 ) is rotated by 180 ° with respect to the position shown in Fig. 2A. The washing line ( 2 A) and the Meßfühlerlei device ( 2 D) are connected to the inflow line ( 2 a) , and the sensor line ( 2 C) communicates with the inflow line ( 2 c) to allow an inflow of calibration gas and ei ne Accelerate stabilization of the basic parameters of the pO ₂ sensor. In this position, the washing line ( 2 A) , the sensor line ( 2 D) and the bridging line ( 2 B) are filled with a fluid, such as physiological saline.

Figs. 2C shows the calibration position in which the Rotorele ment (2 R - 3) is rotated 180 ° from the position shown in Fig. 2B. The outflow paths of the washing line ( 2 A) , overflow line ( 2 B) , sensor line ( 2 C) and sensor line ( 2 D) work as independent flow paths. During calibration, the humidified calibration gas is allowed to flow into the sensor line ( 2 C) and the calibration of pCO ₂ and pO _{2 is} effected by the sensors ( 4 and 5 ). The calibration is carried out according to the two-point method, whereby pCO _{2 is set} at the pressures 39 mmHg and 72 mmHg and pO ₂ at the pressures 0 mmHg and 85.6 mmHg. The calibration solution can flow from the inflow opening into the sensor line ( 2 D) and the calibration of the pH value is effected by the sensor ( 6 ). This calibration is also carried out according to the two-point method, the pH being set at 7.0 and 7.6. After the calibration of the sensors ( 4 , 5 and 6 ) has been carried out, the washing solution, air and the physiological saline solution flow through the inflow line ( 2 b) in order to clean the inside of the rotary control valve ( 2 ).

After performing the calibration of the sensor (4, 5 and 6) flows during the measurement, the blood sample by the Überbrük kung line (2 B) of the rotary control valve (2).

Figs. 2D shows the measuring position, in which each of the Rotorele elements (2 R - 1, 2 R - and 2 2 R - 3). To 180 ° from the position shown in Figure 2C is rotated. The blood sample flows through the inflow line ( 2 b) into the flow paths of the rotary control valve ( 2 ) and from this through the sensor lines ( 2 C and 2 D ). The values for pCO ₂ and pO ₂ and the pH value are measured by means of the sensors ( 4 and 5 ) connected to the sensor line ( 2 C ) or by means of the sensor ( 6 ) connected to the sensor line ( 2 D) .

The washing line ( 2 A) and the bypass line ( 2 B) are connected to the inflow line ( 2 a) and the physiological saline solution and air flow into the inflow line ( 2 a) in order to effect cleaning of the flow paths and activation. Furthermore, as already mentioned above, the blood sample is brought into contact with the physiological saline solution at the end of the disposal line of the collecting line ( 15 ) for waste materials, where coagulation of the blood and contamination of the flow paths is prevented.

FIG. 2E shows the end position in which the rotor elements ( 2 R - 1 and 2 R - 3 ) are rotated by 180 ° with respect to the position shown in FIG. 2D. The washing duct (2 A) and the sensor line (2 C) are connected to the inflow conduit (2 A) and the bypass line (2 B) and the Meßfühlerleitung (2 D) form independent flow paths. The physiological saline solution flows in the inflow lines ( 2 a and 2 b) . The washing line ( 2 A) , the bridging line ( 2 B) , the sensor line ( 2 C) and the sensors ( 4 and 5 ) connected to the sensor line ( 2 C ) are filled with physiological saline. The calibration solution flows in the inflow line ( 2 d) and the measuring line ( 2 D) and the measuring sensor ( 6 ) are filled with calibration solution.

Fig. 3 shows a perspective view of the flow paths in the rotary control valve ( 2 ) in the measuring position shown in Fig. 2D. The rotation control valve ( 2 ) has a plurality of flow paths ( S 11 , S 21 and S 31 ), which are arranged in concentric circles on the surfaces ( F 1 , F 2 and F 3 ). The stator elements ( 2 S - 1 , 2 S - 2 and 2 S - 3 ) have recessed sealing elements ( P 11 , P 21 and P 31 ) for sealing the flow paths ( S 11 , S 21 and S 31 ) and the flow paths ( R 11 , R 21 and R 31 ), which also form guide channels corresponding to the openings of the stator elements ( 2 S - 1 , 2 S - 2 and 2 S - 3 ). Furthermore, a sealing element (P) is arranged in the flow path between the stator elements.

In the measuring position, as previously mentioned, the blood sample flows into the inflow line ( 2 b) , via the flow path ( S 11 ), the stator element ( 2 S - 1 ), the flow path ( R 11 ), the rotor element ( 2 R - 1 ), the flow path ( S 12 ) of the stator element ( 2 S - 1 ), the flow path ( S 22 ) of the stator element ( 2 S - 2 ), the flow path ( R 21 ) of the rotor element ( 2 R - 2 ) and the flow path ( S 22 ) of the stator element ( 2 S - 2 ) in the sensor line ( 2 C) . The flow path ( S 21 ) penetrates the stator element ( 2 S - 2 ) and reaches the sensor line ( 2 D) via the flow path ( S 31 ) of the stator element ( 2 S - 3 ), the flow path ( R 31 ) of the rotor element ( 2 R - 3 ) and the flow path ( S 31 ) of the stator element ( 2 S - 3 ).

In FIG. 4 is a cross sectional view of the rotational control valve (2) is shown. With ( 2 S - 2 ) a stator element and with ( 201 ) a bearing element is designated, wherein a plurality of flow paths (eg S 21 ) are arranged in a concentric circle around the outside of the bearing element ( 201 ).

In order to prevent leaks between the flow path ( S 21 ) of the stator element ( 2 S - 2 ) and the flow path ( R 21 ) of the rotor element ( 2 R - 2 ), a sealing element ( 202 ) is provided, which with a spring ( 203 ) originating force is loaded.

The rotary movement of the rotor element ( 2 R - 2 ) is transmitted by a bolt ( 205 ) of the shaft ( 204 ). The rotor element ( 2 R - 2 ) has an end cap ( 207 ) which is removable from the shaft ( 204 ), so that by lifting the rotor element ( 2 R - 2 ) the flow paths of the stator element ( 2 S - 2 ) and Rotor element ( 2 R - 2 ) can be checked and serviced. With ( 208 ) a control disc for the rotational position is designated, which is attached to the shaft ( 204 ) and has recesses ( 209 and 210 ) which are offset by 180 ° on the circumference of the disc ( 208 ).

The control disc ( 208 ) is connected by means of a bolt (not shown) to a drive disc ( 213 ), which in turn is fixed by means of a bolt ( 212 ) to a shaft ( 211 ) which is driven by a drive ( 214 ) with a gear ( 215 ) is driven. The rotational position is determined by means of a roller ( 218 ) which scans the cutouts ( 209 and 210 ) of the control plate ( 208 ), and the end position is determined by means of microswitches ( 216 and 217 ).

Fig. 5A is a front view of the pneumatic thermal statbehälters (3) and in Fig. 5B is a section VB-VB of FIG. 5A. The housing ( 301 ) of the thermostatic container ( 3 ) has an opening ( 301 a) , as well as a pCO ₂ sensor ( 4 ), a pO ₂ sensor ( 5 ), a pH meter ( 6 ) and a sensor holder ( 302 ) with overhangs ( 303 , 304 and 305 ). The Ge housing ( 301 ) has support bearings ( 308 and 309 ) with pivot pins ( 306 and 307 ) which project vertically from the support bearings ( 308 and 309 ). The sensor holder ( 302 ) is mounted on the pivot pins ( 306 and 307 ) projecting from the support bearings ( 308 and 309 ) such that the holder ( 302 ) can be pivoted between the end positions ( B 1 and B 2 ).

With ( 310 ) a closure lid is designated, which has a window with two transparent panes ( 310 a and 310 b). Wei terhin a handle ( 310 c) , a sealing ring ( 310 d) and a hinge ( 311 ) are provided. The cap ( 310 ) is the type on the housing ( 301 ) that he between the end positions (C 1 and C 2 ) is pivotable.

The sensors ( 4 , 5 and 6 ) are then accessible for checking and maintenance when the cover ( 310 ) is in the end position ( C 2 ) and the sensor holder ( 302 ) is in the end position ( B 2 ), such as is shown in Fig. 5B by broken lines.

A heat source ( 312 ) connected to the housing ( 301 ) contains a fan ( 312 a) , a heating device ( 312 b) and an insulation ( 312 c) . The hot air ( 312 d ) coming from the heating device ( 312 b) flows through outflow openings ( 313 a and 313 b) of the guide channel ( 313 ) provided inside the housing ( 301 ).

As is apparent from the above description of the invention, tre no coagulation of the blood itself in the device with continuous use of the device over a län time period, so that the measurements are continuous can be performed and do not have to be canceled. Wei furthermore, the safety of an operation is increased and it can the measuring time shortened by automation of the device will.

Claims (6)

1. Device for the continuous monitoring of Blutga sen, with which blood is continuously sucked out of an extracorporeal circuit and gases dissolved in the blood are measured by means of an electrochemical sensor, consisting of an electromagnetic actuator with a plurality of electromagnetic valves for changing the flow paths of a calibration solution, one Calibration gas, a washing solution, a physiological saline solution and air, a rotary control valve with a multitude of components, which is connected to an outflow opening with the electromagnetic actuating device in order to selectively switch between the flow paths of the fluids and a blood sample and to supply these fluids to sensors, a thermostat container , with a probe for the pH value and the CO ₂ and O ₂ partial pressures and a bubble generator which keeps the measuring environment at a constant temperature, and a microcomputer for carrying out the working process and the other Checking the measurement data of the sensors, characterized in that the rotary control valve ( 2 ) has a stator element ( 2 S - 1 , 2 S - 2 and 2 S - 3 ), with a bearing element ( 201 ) arranged in a flat block core, one A plurality of flow paths, which are arranged in a concentric circle around the outer surface of the bearing element ( 201 ), and sealing elements ( 202 ) provided in the flow paths for sealing the same, a rotor element ( 2 R - 1 , 2 R - 2 and 2 R - 3 ) with the flow paths of the Stato relements corresponding flow paths and profile channels, and a device or the like via a drive of a motor. is rotatable, flow paths in five positions, such as washing, preparing, calibrating, measuring and end position, are formed individually by combining the rotational positions of the rotor element and an online measurement of the pH and the partial pressures of those dissolved in the blood CO ₂ and O ₂ gases continuously detected without causing thrombus formation in the flow paths and without interrupting the blood test. 2. Apparatus according to claim 1, characterized in that the rotary control valve ( 2 ) with a plurality of components len outflow paths, such as a washing line ( 2 A) , a bridging line ( 2 B) , a sensor line ( 2 C) and a measuring sensor line ( 2 D) , wherein in the washing position the washing line ( 2 A) , the sensor line ( 2 C) and the measuring line ( 2 D) are connected to each other, while the bridging line ( 2 B) forms a separate flow path and fluids , such as the washing solution, the physiological saline and air, flow through all flow paths, whereby all flow paths are cleaned. 3. Device according to claim 1 or 2, characterized in that connected in the preparatory position, the washing line (2 A) with the Meßfühlerleitung (2 D), while the bypass line (2 B) and the Meßfühlerleitung (2 C) sepa rate flow paths form, and the physiological saline solution flows through the washing line ( 2 A) , the bypass line ( 2 B) and the sensor line ( 2 D) , while the calibration gas flows through the sensor line ( 2 C) , thereby stabilizing the basic parameters of the pO ₂ - Sensor ( 5 ) is accelerated. 4. Device according to claim 1 or 2, characterized in that in the calibration position, the washing line (2 A), the bypass line (2 B), the Meßfühlerleitung (2 C) and the Meßfühlerleitung (2 D) independent flow paths form and the washing solution , the physiological saline solution, air and the blood sample flow in the bypass line ( 2 B) , and during the calibration the calibration gas flows in the sensor line ( 2 C) and the calibration solution in the sensor line ( 2 D) , whereas before and after calibration the Wash solution, the physiological saline and air in the sensor lines ( 2 C) and ( 2 D) flow, whereby clotting of the blood sample in the washing line ( 2 A) and in the bypass line ( 2 B) is prevented. 5. Apparatus according to claim 1 or 2, characterized in that in the measuring position, the washing line ( 2 A) with the bridging line ( 2 B) and the sensor line ( 2 C) are connected to the sensor line ( 2 D) and the physiological saline and air flows in the washing line ( 2 A) and the bridging line ( 2 B) and the blood sample in the sensor line ( 2 C) and the sensor line ( 2 D) , the blood sample being mixed with the physiological saline solution at the end of the drain lines, thereby avoiding blood coagulation and contamination of the flow paths at the end of the drain lines. 6. The device according to claim 1 or 2, characterized in that in the end position, the washing line ( 2 A) is connected to the sensor line ( 2 C) and the bridging line ( 2 B) and the sensor line ( 2 D) form separate flow paths , and the washing line ( 2 A) , the bridging line ( 2 B) and the sensor line ( 2 C) are filled with physiological salt solution, and the sensor line ( 2 D) is filled with the pH calibration solution, causing the membranes to dry out pCO ₂ and pO ₂ sensors and a concentration of the electrolyte is prevented, the effectiveness of the pH meter is maintained and a change in the sensors and contamination of the flow paths is prevented.