DE1061958B - Catheter with built-in transmitter for electrical pressure measurement in the human or animal organism, especially in the heart - Google Patents

Description

Catheter with built-in transducer for electrical pressure measurement in the human or animal organism, especially in the heart The invention concerns the measurement of pressures in the human and animal organism with the help of inductive measuring transducers, which convert mechanical into electrical measurands allow. Such measurements are useful both in the fields of physiology and Pharmacology as well as for clinical-diagnostic purposes of great importance.

One difficulty with such measurements is the transmitter as close as possible to the measuring point itself. That of course requires one Particularly small size of the transmitter for the installation in an E4atheter. In such So far, attempts have already been made to change the electrical resistance of small measuring transducers to be used by means of strain gauges. This is mainly due to the flaw, that the achievable change in resistance is particularly small and also depends on the Body temperature of the patient being examined is also influenced. A transmitter with the smallest dimensions with a total diameter of only 2 to 3 mm but build for a catheter according to the invention in the way. that through a membrane 24 controlled ferromagnetic coil core 18 of the inductive transducer 15, 16 held in the middle part by a coil spring 21 penetrating the coil body 14 is. the protruding ends of which are supported on the bobbin 14. One of those Transmitter in a catheter has the advantage that it is small enough on the one hand is to be brought directly to the place of measurement, and secondly that it is little dependent on external temperature influences and, thirdly, that it is sufficient is sensitive to directly generate a measurable voltage quantity. Per se an inductive measuring transducer has already become known in the manner that the measuring transducer at the end of the catheter or needle was outside the patient's body and in communication with the body part only through the catheter tube or needle was in which pressure fluctuations should be measured. Such a transmitter cannot follow the fluctuations in pressure immediately because the considerable Length of the liquid cavity from the measuring point to the transducer, very short-term fluctuations is not able to transfer in the correct amount. A needle is for longer distances unusable.

To explain the subject matter of the invention, the head of the probe, which encloses an inductive manometer, represented by FIGS.

The pressure gauge head consists of a bobbin 14 with two chambers for the two induction coils 15, 16, which each consist of a primary and secondary coil exist. The four leads to these coils are twisted together and are by a longitudinal section, not visible in FIG. 1, backwards into the catheter guided. A ferromagnetic core 18 is through one between a threaded ring 19 and a retaining ring 20 extended helical spring 21 made of wire, which runs through the bobbin 14 and used to hold the bobbin 18 will. The coil core 18 carries a plate 22 at the head end on a rod 21 a a ring 23 with internal thread can from the front with a special tool of the threaded ring 19 are rotated, whereby the spring tension and thus the rest position of the 18 core can be set. From the front, the arrangement is air-conditioned by a membrane 24 sealed liquid-tight. The pressure to be measured acts on the membrane 24 and so on the adjacent plate 22, whereby the core 18 is displaced in proportion to the pressure becomes what at the poles of the secondary coil a proportional to this shift AC voltage can arise.

In the arrangement of FIG. 1, the retaining ring 20 can be through a Fix screw 25 inserted from the outside and thereby achieved that after loosening the screw 25 and removing the membrane 24 the entire mechanically movable part for any necessary repairs taken out to the front or the tension of the spring 21 is adjustable. The parts 14 and a protective tube 16 pushed over can made of metal or a plastic, e.g. B. synthetic resin. In case of Manufacture from metal is proposed to suppress the electrically disruptive Eddy currents a metal alloy with a particularly high specific resistance and to stay with a small temperature coefficient. For the magnetic core 18 is a ferromagnetic one Alloy with particularly high magnetic Use permeability.

The membrane 24 can be made of thin rubber or a permanent plastic film getting produced. It is glued to the front attachment of the bobbin 14 and / or held by a ring 27 pushed over. Should negative pressure for measurement arrive, either the plate 22 must protrude slightly beyond the front end of 14 and are therefore pushed back somewhat by the elastically tensioned membrane 12, or plate 22 and membrane 24 must be firmly connected to one another. The ring 27 must be so long. that it protrudes beyond the membrane 24 to the front and is thus movable Parts, e.g. B. of the heart. cannot touch the membrane directly. Also can the ring 27 can be closed to a streamlined cap at the front and lateral Holes are preserved so that in blood vessels with strong currents the hvdrodvnamic pressure has no influence on the measurement result. If the bobbin 14 is made of metal, For reasons of insulation, it is suggested that a burnt-in one be applied to it before wrapping it Coat of varnish. The coils themselves are made with enamelled copper wire or enameled silk wire wrapped and still soaked with an impregnating agent. On the tapered approach 26 with an olive is the pushed-over end of a cardiac catheter or another itatheter 17 cemented.

Through this catheter, for. B. to secure against loosening of the Manometer head pulled a firmly soldered steel wire 28 in the approach 26 and at the rear Catheter end are attached. The catheter is also used to accommodate the four Lead wires for the pressure gauge coils and the connection of the inside of the pressure gauge head with the outside air (atmospheric pressure) or one of its reference pressure, with the latter If the measurement of differential pressures is made possible. The calibration of the manometer can either by supplying a known positive or negative pressure from the front the membrane or vice versa by applying a known negative or positive pressure be made through the catheter. For the latter purpose is the T-tube 29 with the side tube 30 is provided. It goes without saying that this way too a calibration can be carried out during the course of a measurement.

Since when measuring blood pressure in the heart cavities, etc., a sample is often taken of blood or the injection of X-ray contrast media is required, it is suggested that to use a double-barreled catheter, the first channel of which is in the pressure gauge head ends and is connected to the T-tube 29 and its second, slightly shorter Channel ends behind the manometer head and here has an opening to the blood.

The four twisted leads for the pressure gauge coils are from T-tube 29, which is hermetically sealed at the rear with putty 31, by any long insulating tube 32 is fed to a four-pin plug which is connected to the electrical Additional device containing the switching elements required to operate the pressure gauge, is connected. The use of of different colored insulating hoses or of markings on the four-pole Plugs suggested.

The catheter manometer is also proposed for other purposes to leave even outside the body in a fixed position, so that the membrane 24 adjoins the atmospheric air, and from the side tube 30 a connecting hose lead to places in the body where gas pressure fluctuations occur, e.g. B. to Interpleural space or to the airways. In this way, these gas pressure fluctuations easily registered.

Of course, the catheter manometer sketched in FIG. 1 also connected to the outer end of a fluid-filled cardiac catheter as was the case for other pressure gauges with previously known measurements and what is associated with the disadvantages mentioned at the beginning.

For pressure measurement by means of a puncture in peripheral and other Blood vessels, in the heart cavities and other fluid-filled or gas-filled Cavities is proposed either the catheter manometer sketched in FIG. 1 to be connected at right angles to the attachment of a commercially available injection syringe or the pressure gauge from backwards in the longitudinal direction through the piston rod and the To guide the plunger of the injection syringe. Both possibilities are shown schematically in FIG shown. Here 33 means the cylinder of a hypodermic syringe, 34 the piston rod, 35 the piston, 36 a pressure gauge connected to the extension 37 at a right angle, 38 a pressure gauge connection passed through a hollow piston rod 34 and piston 35. the The syringe, the extension 37 and the hollow needle 39 are free of air bubbles with anti-coagulants Fill liquid. To avoid electrically disruptive eddy currents in the metallic Piston 35 can also be attached to the pressure gauge so that it comes out of the front Piston protrudes. Fig. 3 shows a further proposal for such physiological Experiments in which a lateral blood pressure measurement is necessary. The blood vessel or heart wall 40 is clamped between two small metal plates 41 and 42, wherein 42 is pressed against 41 by the compression spring 43. The tension of the spring 43 is adjusted by moving the clamping device 45 which can be fixed on a tube 44. 41 and 44 are firmly connected to one another.

41 has a small steel point for piercing the wall 40. The pressure gauge 46 (corresponding to 18 in Fig. 1) with the catheter 47 is through tubes 44 to The opening in the plate 41 is pushed forward and fixed to the rear by a stuffing box 48 and sealed.

A special catheter manometer for endoscopic puncture for the purpose of Measurement of blood pressure in large vessels near the heart and in the heart itself is shown in Fig. 4. This arrangement is intended to be viewed in through a bronchoscope or esophagoscope The human trachea or esophagus is inserted and punctured through the wall of the trachea, bronchi or esophagus with the desired hollow organs to be connected. In Fig. 4, 49 denotes a metal pipe, 50 denotes a metal pipe therein inner tube, 51 the hollow needle attached to the front end of 49, 52 the manometer, whose lead wires are guided in 50, 53 a front cone, 54 a rear cone, 55 a stopcock with hose attachment or syringe cone. To use the sterilizable manometer on humans becomes air-bubble-free with anti-coagulant Liquid filled, with 52 in cone 53 (as drawn). After this Puncture and the pressure registration can be withdrawn 52 in cone 54, so that now either X-ray contrast medium for angiocardiography is injected through Hahn 55 or blood can be aspirated for analysis.

The catheter measuring arrangement shown in Fig. 1 can also be in different Modifications are used for other purposes. Is z. B. in Fig. 1 the ring 27 does not exceed, the result is a sphygmograph (pulse generator) of high quality, which, with the membrane 24 placed on the uninjured skin via arteries or veins, the Pulse to be registered.

Finally, in the arrangement of FIG. 1, with the omission of the Membrane 24, the rod 21 a extended and led out to the front, so can small displacements or forces acting on the end of the rod 21 in its longitudinal direction act, measure.

An example is a respiratory movement recorder that can be used externally on the chest called.

It is also suggested to use the elongated and protruding front Rod 21 ci (in Fig. 1) to put a transverse plate, the diameter of which is larger than the outer diameter of the protective tube 56.

This serves the purpose as a speedometer for the arrangement flowing liquids and gases, e.g. B. blood or breath to use. The one mentioned The transverse plate must then be perpendicular to the direction of flow. The hole in the approach 26 must be locked in this case.

PATENTANSPF; UCHE 1. Catheter with built-in transducer for electrical Pressure measurement in the human or animal organism, especially in the heart, characterized in that the ferromagnetic Coil core (18) of the inductive transducer (15, 16) in the middle part of the coil body (14) penetrating helical spring (21) is supported, the protruding ends of which are supported on the bobbin (14).

Claims (1)

2. Catheter according to claim 1, characterized in that the the Bobbin (18) holding Spring (21) at one end against a screwable The adjusting ring (19) is applied. 3. Catheter according to claim 1 or 2, characterized in that the other end of the spring (21) in one by a clamping screw (25) on the bobbin (14) to be fastened retaining ring (20) is seated. 4. Catheter according to claim 1 or the following, characterized in that that the inductive transmitter in a tightly the coils (15, 16) enclosing protective tube (56) made of plastic or a metal with a high specific electrical resistance and is preferably accommodated with a small temperature coefficient. 5. Catheter according to claim 4, characterized in that also the Bobbin (14) made of plastic or metal with a high specific electrical There is resistance. 6. Catheter according to one of claims 1 to 5, characterized in that that the membrane (24) on a front extension (23) of the bobbin (14) through a coupling ring (27) is held. 7. Catheter according to claim 6, characterized in that the coupling ring (27) the membrane (24) protrudes so far that moving parts of the organs do not touch the membrane can touch. 8. Catheter according to claim 1 or the following, characterized in that that a thin steel wire (28) is used to attach the transmitter, which is connected to the Coil body (26) is inextricably connected and at the rear end of the catheter (31) attach is. 9. Injection syringe in connection with a catheter according to claim 1 or following, characterized in that the piston (35) for receiving the catheter is pierced. References considered: U.S. Patent No. 2648 328, 2634721.