DE2420610A1 - Pressure sensor for measuring internal body pressures - has elliptical cylinder sensor head containing one or more strain gauge measurement devices - Google Patents

Abstract

A pressure sensor for measurement of internal body pressures, particularly for intracardial and intravasal blood pressure measurements consists of a thin walled hollow body which is elastically flexed by the pressure fluctuations to be measured, closed at one end. At least one strain gauge measuring device extends through the length of the sensor head, in the position where most pressure variation is to be expected and the measuring strip or strips are fixed to the wall of the elliptical cylindrical shaped tube sensor head. The hollow body is protected by an outer sheath open at one end and with at least two side openings.

Description

Pressure receptor The invention relates to a pressure receptor for intracorporeal Pressure measurements, especially for blood pressure measurements in the heart and blood vessels with the help of an elastically deforming under the pressure fluctuations to be measured thin-walled hollow body, preferably an elliptical or flat-oval tube (;the cut.

This principle was first implemented in patent 1,262,503 of the same Inventor from A.T. 29.4.63. and also in the one from Siemens A.-G. with mentioning Patent claim 21 25 749.6 dated May 21, 71, filed by the same inventor.

In the patent 1 262 505 the measurement of the longitudinal deformation of the elastic Rohres still through the measurement of resistance or.

Changes in capacitance between 2 fixed platinum electrodes in an electrolyte solution, while in claim 21 25 349f 6 of 21.5.71.die Measurement of the longitudinal deformation of the elastic tube under pressure using strain gauges took place, which is glued to the points of greatest deformation of the elastic tube became. The change in shape of the pipe during the pressure changes affects the Resistance values of the strain gauges as a measure of the size of the pressure fluctuations are usable. Since the strain gauges are on the outside of the elastic Rohres found that they had to do so before direct contact with the pressure medium preferably to protect the blood. This was done through a layer of silicone oil which was located between the elastic tube and a fixed outer tube. The oil filling was for its part against the pressure medium by means of a silicone rubber membrane without straightening force delimited.

- The German Offenlegungsschrift shows the latest state of the art 2 206 624 (filing date 11.2.72.> From Millar, Houston, U.S.A. This is where it works Print medium on an elongated, single-sided fixed # flexible Beam or rod, i.e. a tongue that goes into the outside of a rigid housing is embedded and sealed against the surrounding housing by silicone rubber Pressure causes the tongue to deflect. The size of the deflection is measured by means of 2 strain gauges. The smallest built according to this principle Millar pressure measuring probe has an outside diameter of 1.67 mm.

Now it exists in many branches of physiological and clinical research there is a definite need for further miniaturization of pressure measuring probes In today's cardiology, so-called insert catheters for cardiac diagnostics and long-term monitoring of the circulation with an outside diameter 0.8-1.0 mm, that is introduced into the heart from a peripheral vein or artery is> guides the pressure waves occurring here through the liquid column of the long thin catheter tube to a pressure receptor located outside the body The associated damping necessarily leads to ritual distortions and phase shifts of the registered pressure curves. Only one pressure measuring head located at the tip of the catheter The registration became physically more exact with an outside diameter of at most 1 mm Allow curves.

Numerous other examples from pressure measurement in hngiology; especially venous pressure measurement and many other medical research areas could undermine the benefit of a pressure receptor with an outer diameter of at most 1 ms To prove.

The principle of the Millar probe (flexible tongue with silicone rubber seal) is However, this is not feasible in the tightest smallest dimensions Experiments in the laboratories of Siemens A.-G. clearly shown.

The one to be placed on the sealing material between the tongue and the housing Requirements such as freedom from directional force in every pressure area, no influence on the elastic properties of the manometer system etc. are all the more difficult to achieve, the smaller the dimensions of the pressure receptor can be selected. As miniaturization progresses, the deviations from linearity increase and occur Hysteresis and temperature dependence are more prominent.

These facts can be easily explained from the well-known elastic ones Properties of the rubber, including the silicone rubber.

This principle of the billion dollar means that the limits of miniaturization are established In fact, there is still no catheter tip pressure receptor of this size 1mm in diameter and below.

The present invention sets itself the task of the present here To close the loophole, in turn from the already i-r, the earlier patents by the same inventor makes use of elliptical elastic hollow body and strives for further miniaturization and increase in sensitivity.

According to the invention, it is essentially assumed that on the oil layer surrounding the hollow body, which serves to protect the strain gauges and the closing membrane of patent 21 25 349 .6 can be omitted if you attach the strain gauges to the inside of the hollow body, their arrangement improved and optimally shaped hollow bodies used.

According to the invention, those arranged in the longitudinal direction of the pipe are used Strain gauges are placed in the areas of the pipe which are the strongest under pressure Experience changes in shape, namely between a tube of elliptical cross-section 4 moderate in the area of the apex lines.

According to the invention, a flat oval tube can also be used, which Flat sides the arrangement of two parallel side by side in the longitudinal direction Allow strain gauges.

To achieve high sensitivity and temperature compensation you can 4 measuring strips can be used as links in a measuring bridge.

Following are some embodiments based on the drawings the invention explained, which of course in strong Ver enlargement are shown. 1 shows a longitudinal section through the pressure receptor Fig. 2 also shows a longitudinal section through the pressure receptor, but by 90 # around the Longitudinal axis rotated against Fig.l Fig. 3 shows the elastic shown in Fig.l and 2 Tube of elliptical cross-section for the purpose of clarification in perspective representation, (with cross section), Fig. 4. # A long section of a second embodiment of the pressure receptor with another form of elastic tube.

FIG. 5 likewise a longitudinal section of the pressure receptor according to FIG. 4, but rotated by 900 about the longitudinal axis Tube of elliptical cross-section in perspective view (.n '. Cross-section) Fi ## 7 in longitudinal section a third embodiment of the pressure receptor with a so-called. Tubular tube as an elastic hollow body Fig. 8 bind a longitudinal section through the receptor 7, however, rotated by 90 ° about the longitudinal axis.

9 shows the elastic tube of the receptor according to FIGS. 7 and 9 in perspective Representation (with cross section) All three embodiments of the pressure receptor can with an outside diameter of 1.0 mm and less.

Therefore it is possible to have this pressure receptor not only in veins, but also in arteries using simple puncture needles # hm ~ -: ## surgical exposure to be introduced into the bloodstream and e.g. at the tip of a so-called flood catheter forward to the heart. It therefore allows in the simplest way and for the patient gentlest way blood pressure measurements as well as continuous blood pressure registrations in the heart and blood vessels.

In FIGS. 1 and 2, the end of the catheter tube is denoted by 1.

This goes directly into the outer metallic protective tube 2 from cylindrical # shape, which carries the narrow protective bracket 3 at the end near the blood. Two opposite one another # lie # o elongated openings Y in the side wall of the outer one Protective tube 2 allow as well as the terminal opening 5 of the outer tube which is located on both sides of the protective bracket 3, free access to the blood Inside the protective tube. The fixed connection between the end of the catheter and The metallic connecting tube 6 inside takes care of the metallic outer tube of the outer protective tube is axially the thin elastic metal tube 7 of elliptical Cuu section, the shape of which is illustrated in perspective in Fig. 3. It is close to blood End closed at 3, but open towards the catheter so that inside the elastic tube atmospheric pressure prevails, which thus serves as a reference pressure. For the purpose of fastening in the axial position, the elastic tube 7 is connected to the catheter through with the outer protective tube 2 and at the same time with the connecting pipe section 6 the chain 9 is tightly connected. At the end close to the blood, the chain is made with the outer protective tube 2, however, only at the ends of the two narrow sides of the elastic Rohres at 10. Thus the elastic ear is stiffened at both ends, near the kktheter End through the putty on all sides, at the bloody end through the closure 8. Under the action of blood pressure, the thin metal tube 7 is compressed, wherein the greatest flattening occurs in the middle of the pipe length. 11 are the 4 strain gauges referred to, before. of which on each broad side of the elastic tube each o in the The length of the pipe is glued to the inner wall of the pipe according to the axis of the vertex Since the inner ends of the strain gauges are near the middle of the pipe length, while the outer ends are practically fixed near the pipe ends, so are all strain gauges under pressure with their inner ends facing the pipe axis bent and thus compressed, resulting in changes in resistance the strain gauges are measured BEZW with the help of a bridge circuit.

registered.

The second embodiment of the pressure receptor shown in FIGS. 4, 5 and 6 differs from the first (Fig. 1 - 3) only by the shape of the elastic Tube 12. While the tube of the first embodiment in its entire length has the same cross-section, the elastic tube used here only has in the middle of its length the same cross-section never the tube of Fig.3. To However, the major axis of the elliptical cross-section grows symmetrically towards both ends and reaches the inner diameter of the outer protective tube at both ends This is cemented in a similar way to the pipe of Fig. D: at the inner end Edge cementing on all sides, at the outer end close to the blood only cementing on both of them Ends of the narrow sides. The minor axis of the elliptical cross-section is about the The entire length of the pipe is pale.! With increasing pressure, the pipe becomes strongest in the Middle part - flattened, with the small cross-sectional axis shortened, at the same time The main axis is lengthened, the pipe narrowing in the middle part is like this dimension that the major cross-sectional axis under The highest pressures to be measured almost reached the size of the large axes at both ends of the pipe.

in turn, as in the first embodiment, the whole The strain gauges stuck on the inside are bent towards the pipe axis The changes in resistance that occur in the process are formed in a bridge circuit measured resp. The advantage of this tube shape is that it is larger Attack surface against the print medium.

Finally, a third embodiment of the invention is shown in FIGS Figs. 7-9 are shown. This also differs from the two already discussed only by the shape of the elastic tube 13.

This has the shape of a tube here. In the longitudinal section of FIG. 8 recognizes one, that is the elliptical tube cross-section in the inner half near the catheter of the tube remains approximately the same, increasing in the outer half of the tube near the blood flattened until the two broad sides at the outer end merge tube-like with one another and at the same time widen up to the inner diameter of the outer protective tube ( Sig. 7) In this case, the pipe only carries on the two broad sides of the inner one Half of the tube each have a strain gauge 11.

This embodiment is suitable for such cases in which one lower sensitivity of the pressure receptor is sufficient. It has the advantage that it can be built particularly short. In Fig. 9, this tube tube is for clarity shown in perspective.

Here, too, the lateral trend changes occurring under pressure changes of the two strain gauges measured in a bridge circuit respectively. registered,

Claims (11)

Claims. @ Pressure receptor for intracorporeal pressure measurements, especially for intracardiac or intravascular blood pressure measurements, with one closed on one side , elastically deforming thin-walled under the pressure fluctuations to be measured llohlkörper, preferably a tube with elliptical cross-section, d a d u r c h It is not noted that there is at least one on the pipe in the longitudinal direction of the pipe aspiring strain gauge is arranged. 2. Drwokrezeptor according to claim 1, characterized in that the The strain gauge is arranged in the area of the pipe in which the greatest changes in shape are to be expected in the event of pressure fluctuations. 3. pruckrezeptor according to claim 1 or 2, with one in cross section elliptical tube, characterized in that the or the strain gauges in the Area of the vertex line (s) of the elliptical tube is arranged or are. 4. Pressure receptor according to one of the preceding claims 2 and, characterized characterized that fier strain gauges are used as members of a measuring bridge are. Pressure receptor according to one of the preceding claims, characterized in that it is separated the respectively the measuring strips on the inner wall of the pipe is glued BEZW. are. 6. Pressure receptor according to one of claims 1 - 5, characterized in that that the hollow body is in an outer, stable protective tube of cylindrical shape is included, which gives the blood free access to the elastic hollow body, because it is open at the end and has at least 2 side openings. 7. Pressure receptor according to one of claims 1-5, characterized in that the elastic hollow body of elliptical cross-section on the outer (close to the blood) closed End only at the two ends of the narrow sides with the outer cylindrical protective tube is cemented, while it is cemented tightly into the protective tube on all sides at the inner end is. 8. pressure receptor according to any one of claims 1-7, characterized in that the major axis ~ it elliptical cross-section of the hollow body from the center of the The pipe length increases symmetrically towards both ends until it reaches both pipe ends reaches the diameter of the outer protective tube, while the small axis of the ellipse remains the same over the entire length of the pipe (Fig.b). 9. pressure receptor according to any one of claims 1-5, characterized in that the elastic hollow body has the shape of a tube tube of elliptical cross-section whose wide walls in the outer half of the tube under simultaneous widening keep getting closer in order to merge with each other at the outer end. 10. Pressure receptor according to claims 1-5 and 9, characterized in that only 1 strain gauge on the inside of the two wide walls of the inner tube half is glued on. 11. Pressure receptor according to one of the preceding claims, characterized characterized in that instead of an elastic hollow body of elliptical cross-section an elastic hollow body of flat oval cross-section is used, on which inner flat sides each 2 strain gauges in the longitudinal direction parallel next to each other can be attached.