DE3500822A1 - PRESSURE MEASUREMENT DEVICE - Google Patents

Abstract

In order to measure the pressure inside the human body or the body of an animal, the pressure is transmitted to a pressure transducer (7) by means of a balloon (1) only partly filled with a gaseous medium, which is applied to a double or multi-luminar catheter(2). The partial filling required for reliable pressure transmission is achieved by one or several piston-pumps (6, 12) or a combination of one or several piston-pumps with one or several valves (8, 9).

Description

Device for pressure measurement

The invention relates to a device for measuring the pressure in Body cavities and vessels of the human and animal body and in others closed systems.

The measurement of pressure in body cavities and vascular systems of the human and animal body is an important means of obtaining information about the condition and the respective functional situation of the organism. especially the Measurement of blood pressure is useful for diagnosis and for monitoring the course of therapy in numerous cases Diseases Critical: The pressure in the heart chambers is for assessment the function of the heart and its valves. The pressure in the vein Cava, the so-called central venous pressure (CVP), is a parameter for the fluid balance of the body. This parameter is of central importance in intensive care medicine both in the diagnostic and therapeutic area. Based on the size of the CVPs are administered medication, infusion regimes and fluid balances are drawn up.

The measurement of the pressure in the brain is used in various diseases, associated with an increase in this pressure, applied. The measurement of pressure in body cavities such as the stomach and intestines has gained importance in research.

To measure the pressure in less accessible parts of the body, z. B. in the vena cava, in the aorta, in the heart chambers or in the pulmonary circulation it is known to use liquid-filled plastic tubes, so-called catheters, in to introduce the body so that its end reaches the measurement site. The pressure will then Transferred via the liquid in the hose - and at the end of the hose, preferably measured outside the body. This can be done with U-tube pressure gauges, through simple Measurement of the liquid level in the catheter or through connection by pressure transducers. This method is used in particular to measure the central Venous pressure, d. H. of pressure applied in the vena cava. Insertion of the catheter is usually done by piercing (puncture) an easily accessible vein in the Neck or collarbone area or the crook of the elbow either with a steel cannula through which the catheter is advanced to the appropriate measuring point can, or according to the Seldinger technique. Here, after puncturing the vein with a small-caliber cannula through this first a guide wire, a so-called Stylet inserted into the vein. This guide wire can be used in the further Catheter can be advanced after the cannula has previously been removed.

This catheter is used both for pressure measurement and for insertion of infusions and for drawing blood. The problem with this procedure is that because of the weight of the liquid in the hose, the measurement of the pressure is accurate must be at the height of the measuring point, i.e. the catheter tip. For precise determination the localization of the catheter tip now exists in clinical use not a workable procedure. Imaging methods are conceivable, but temporally and financially too expensive. The most common clinical procedure is based on on the assumption that there is a certain ratio of the chest diameter on the one hand and the position of the vena cava on the other. The diameter of the chest is measured in its sternum / back extension with a caliper, the position the vena cava is then set at 3/5 the diameter, measured from the back. However, natural anatomical variations are not taken into account in this formula, which depend on the size, nutritional status and gender of the patient. Insurmountable obstacles arise in extreme cases, such as chest deformities.

Even if using this method the location of the vena cava correct could be determined, it does not necessarily mean the position of the catheter tip known, which actually needs to be determined. Because the Vena Cava shows on average a diameter of 3 to 4 cm. Whether the catheter tip in the vessel is now more towards the sternum or more to the back remains completely unknown.

As a result, there are significant errors when the position of the catheter tip and thus the zero point is determined according to this method.

If one also takes into account the size of the measured values (normal value of the ZVD approx. 2 to 6 cm water column) the dimension of the measurement error becomes clear: it lies in the same order of magnitude as the pressures to be measured. That is, the relative Error can easily exceed 100 or 200 or even more percent.

It is also known to have a pressure transducer at the top of a To attach the probe. The pressure transducer is then with the probe up to the measuring point advanced. The problem with this method is the fact that all so far known pressure transducers do not have a stable zero point. It means that the pressure transducer regularly with a known pressure, preferably atmospheric pressure, must be applied. The signal measured in the process then serves as a zero point reference. To do this, however, the catheter tip must be pulled out of the vessel. At a Pressure measurement, which should take place over a longer period of time, is an additional one Stress for the patient. The measurement error resulting from the zero point drift at venous pressures is again in the order of magnitude of the actual measured values.

It is also known, especially in experimental surgery, to bring a balloon that is only partially filled with a gas or air to the measuring location. Since the balloon is only partially filled, there is none in its wall Tensile stresses are present, the pressure inside it is the same as the pressure outside it. The pressure is provided by a gas or air-filled tube that is attached to the balloon is connected, transmitted to a pressure transducer. Since the pressure transducer is outside of the body, it is easily possible to use it regularly to apply the atmospheric pressure and thus compensate for the drift. The little The weight of the pressure-transmitting gas does not cause any hydrostatic error. The problem with this method is that the gas due to leaks in the Measuring system and because of diffusion through the tube and balloon wall from the measuring system disappears. In order to avoid measurement errors resulting from this, the balloon must be regular sucked empty and then filled with a precisely determined amount of gas.

The invention is based on the object of a device for measurement of the pressure inside the human or animal body to create the is easy to use, does not pose a burden to the body, and does not involve is subject to measurement errors caused by hydrostatic or zero point drift.

According to the invention, a balloon whose thin wall material is a has a high modulus of elasticity, in the region of the tip of a double-lumen catheter attached so that the balloon does not exceed the tip and the balloon the The catheter surrounds a jacket. The one - thinner - lumen of the catheter is with the Balloon connected, it is used to transfer the pressure and the filling and emptying of the balloon. The other lumen can be used for infusions and for drawing blood, such as commonly used in almost all areas of medicine. The balloon can in the evacuated state be placed close to the catheter and will be like the usual single-lumen catheter inserted through a cannula inserted into a vessel. He can also according to the so-called Seldinger technique via a stylet directly in the Can be pushed. Furthermore, according to the invention, the balloon with a gaseous Medium only partially filled, so that no tensile stresses act in its wall. The pressure inside the balloon is therefore equal to the pressure on its outside. According to the invention, the balloon is closed at the measurement time and at the adjustment time but connected to an open system, which is also connected to the one pressure transducer is. The partial filling of the balloon, which is important for the accurate transfer, is achieved by one or more pistons or by one or more pistons in communication with controlled by one or more valves.

Fig. 1 shows an embodiment of the catheter. The balloon 1 is at the end of the catheter 2 attached, it is connected to a lumen of the catheter while the other lumen ends open. At the other end of the catheter 2 are both lumens provided with connecting elements 3 and 4.

Fig. 2 shows an embodiment of the invention in which the emptying and The balloon is filled by combining a piston pump with a valve. The balloon 1 at the end of the double-lumen catheter 2 is over one lumen of the catheter and the connecting hose 5 is connected to the piston pump 6. A pressure transducer 7 is connected to the system. The system can reach the environment via the valve 8 be opened. The filling process proceeds as follows: The valve 8 is opened so that the system is connected to the environment. The adjustment now takes place of the zero point. For this purpose, the reference value for the pressure transducer is obtained. then the piston pump 6 is moved up to a reference point. Now valve 8 closed. The piston pump 6 now sucks the balloon 1 empty.

The "empty" state is characterized by a certain size negative pressure peculiar to the balloon. Then with the piston pump 6 a certain, volume peculiar to the size of the balloon is pumped into the balloon. Now with to the Pressure transducer 7 measured the pressure.

According to a further embodiment of the invention, the gas volume is with which the balloon is filled, not constant, but from the pressure to be measured addicted.

According to a further embodiment of the invention, by a second Valve 9 of the piston pump during the measurement of the balloon-catheter-pressure transducer system be separated. This improves the dynamics of the system.

According to a further development of the system, the filling takes place and Emptying the balloon with a combination of two piston pumps. Fig. 3 shows a Arrangement scheme. The balloon 1 at the end of the double-lumen catheter 2 is over the one lumen of the catheter and the connecting tube 5 with the piston pump 6 tied together. A pressure sensor 7 is connected to the system. The inside of the piston pump 6 is through the bore 15 in the cylinder wall of the piston pump 6 with the environment tied together. The piston pump 6 is connected to the piston pump through the connecting hose 11 12 connected. The filling process proceeds as follows: The piston pump 6 is brought into its end position 13. Now the system is through the bore 10 with the environment connected and the reference value of the pressure transducer is obtained. Then the The piston pump 12 is brought into its end position 14 and the piston of the piston pump 6 is brought into position 15 so that the bore 10 is closed. Now with the Piston pump 12 sucked the balloon empty. Then the piston pump 6 is used to inflate the balloon filled with a defined volume. The measurement can now be carried out.

According to a further embodiment of the invention, the connection takes place between the two mentioned piston pumps through a bore in the cylinder wall the first piston pump.

Fig. 4 shows a scheme of the arrangement. The connection between the piston pump 6 and piston pump 12 is done here the bore 15 in the cylinder wall the piston pump 6. Now the balloon is filled by the piston pump 6 during the process is, the piston pump 12 is separated from the system, which improves the dynamics leads.

According to one embodiment of the invention, the system is for emptying and filling, as well as the pressure transducer arranged on a circuit board with a Connection plug is provided so that the complete unit looks like an electronic circuit board can be built in.

According to a further embodiment of the invention are in the board Arranged recesses for the individual components.

According to a further embodiment of the invention, the board is through Deep drawing manufactured.

According to a further embodiment of the invention are on a multi-lumen Catheter attached several balloons, with each of the balloons having a lumen each of the catheter with its own device for pressure measurement and for emptying and Fill is connected.

Although the application of the invention in terms of the measurement of Pressing in the human or animal body has been described, it is by no means limited to this application, but can also be used to measure pressures on others inaccessible places. It makes sense to use it with closed technical systems, e.g. B. reactors possible.

Claims (16)

Claims 1. Device for faithful transmission of a print from the inside of the human or animal body or from the inside of a Hermetically sealed technical area to an outside of the body or the pressure transducer located in said technical area by a flexible one Balloon that is only partially filled with a gaseous medium and with a a closed system at the measurement time but an open system at the adjustment time, the is also connected to the pressure transducer, characterized in that the for the faithful transfer of important partial filling of the balloon via one or more Pistons or via one or more pistons in conjunction with one or more Valves is controlled. 2. Device for faithfully transmitting a pressure from within the human or animal body or from the inside of a hermetically sealed technical area to an outside of the body or said technical Area located pressure transducer by a flexible balloon, which with a gaseous medium is only partially filled and with a closed at the measurement time, but the open system is connected to the adjustment time, which is also connected to the pressure transducer is connected, characterized in that the connection between the balloon and the pressure transducer takes place through a lumen of a double or multi-lumen catheter, while one or more other lumens serve other purposes. 3. Device according to claim 2, characterized in that at least one of the lumina of the catheter not used for pressure measurement for insertion of liquids to the measuring location. 4. Device according to one or more of claims 2 to 3, characterized characterized in that the at least one of the not used for pressure measurement Lumina of the catheter is used to remove liquids from the measurement site. 5. Device according to one or more of claims 1 to 4, characterized characterized in that the pressure transducer is a pressure transducer. 6. Device according to one or more of claims 1 to 5, characterized characterized in that the means for deflating and filling the balloon from the Combination of a piston pump with a valve that opens the system to the environment serves, exists. 7. device according to claim 6, characterized in that an additional Valve separates the piston pump from the rest of the system during the pressure measurement. 8. Device according to one or more of claims 1 to 5, characterized characterized in that the means for deflating and inflating the balloon consists of two Piston pumps exist whose interiors are connected to one another and whose; one Has bore in the cylinder wall, which the system when it passes through the piston is released, opens to the environment. 9. Device according to claim 8, characterized in that the connection the connection between the two piston pumps via a hole in the cylinder wall the one piston pump takes place, so that the connection through the piston of this piston pump can be locked. 10. Device # according to one or more of claims 1 to 9, characterized in that it is also used to measure the pressure in the vessels of the human or animal body and the supply of infusions or to remove the contents of the vessel. 11. Device according to one or more of claims 1 to 10, characterized in that it is also used to measure the pressure in body cavities of the human or animal body and the supply of infusions or the Removal of content is used. 12. Device according to one or more of claims 1 to 11, characterized in that the means for filling and deflating the balloon and the device for pressure measurement are arranged on a circuit board. 13. Device according to claim 13, characterized in that the Board is provided with a connector. 14. Device according to one or more of claims 12 to 13, characterized in that the board is provided with recesses in which the elements arranged on it are attached. 15. Device according to one or more of claims 12 to 14, characterized in that the board is made by deep drawing. 16. Device according to one or more of claims 1 to 15, characterized in that the filling state of the system depends on the pressure to be measured is controlled dependent.