WO1987003797A1

WO1987003797A1 - Installation for the acoustical and mechanical coupling of pressure waves, especially focussed shock waves on the body of living beings

Info

Publication number: WO1987003797A1
Application number: PCT/DE1986/000513
Authority: WO
Inventors: Wolfgang Eisenmenger
Original assignee: Wolfgang Eisenmenger
Priority date: 1985-12-17
Filing date: 1986-12-16
Publication date: 1987-07-02
Also published as: JPS62502518A; DE3544628A1; EP0253825A1

Abstract

Installation for disintegrating, without touching them, concretions within the body of living beings including a shock wave generator (1) and a chamber filled with a liquid, adjacent to the shock wave generator and surrounded by a flexible bellows (2) or similar device. The open rim (2a) of the bellows (2) is provided with a circular open tube (4), of the suction ring type, with an outer and an inner sealing lip (5b) which can be laid on the body (3) of the patient. By applying a negative pressure within the circular tube (4) the desired sealing is obtained without affecting the liquid within the bellows (2).

Description

Device for the mechanical acoustic coupling of pressure waves, in particular focused shock waves to the body of living beings

The invention relates to a device for mechanically acoustically coupling pressure waves, in particular a device for crushing concrements in the body of living beings, according to the preamble of patent claim 1.

A device of this type is known (DE-OS 32 20 751). In this design, the liquid used for coupling the shock waves is received in a bellows adjoining the shock wave generator, which is either closed by a flexible membrane on the side facing the body or is designed as an open bellows and is provided with a kind of sealing lip which, due to the application of pressure to the transmission fluid located in the bellows, lies close to the body. The first-mentioned possibility of closing the bellows by means of a membrane brings with it the difficulty of finding a suitable membrane which does not influence the transmission of the shock waves into the body and also their focusing. The second possibility has the disadvantage that when negative pressure is applied in the spreading medium, a force that is disadvantageous for the positioning arises between the generator and the patient. Furthermore, it is to be expected that cavitation can occur in the liquid when the shock waves are generated, so that the gas bubble veils which may result thereby obstruct the shock wave. It would also be disadvantageous that when using a shock wave generator that works with coils that are supplied with current (DE-OS 33 12 014), the pressure applied could result in the membrane provided for generating the shock waves no longer lies close enough to the spools. The present invention is therefore based on the object to design a device of the type mentioned in such a way that the coupling of shock waves via a liquid accommodated in a bellows or other flexible hose or tubular body can take place in such a way that the liquid provided for the shock wave transmission in can remain a suitable for those ^'s shock wave transmission state.

To achieve this object, the characterizing features of claim 1 are provided. With this configuration, the tight contact of the flexible liquid space is achieved exclusively by tightly pressing a suction ring, which enables the pressure in the transmission liquid itself to be selected completely independently of the question of the sealing of the bellows to the body. It is advantageous to design the sealing annular chamber as a flexible hose which, for example, can also be made in one piece with the bellows. Such a hose which is open on one side can be pressed sufficiently firmly against the body by the application of pressure so that the desired seal is achieved. In order to prevent the patient's skin and tissue from being drawn into the ring tube as far as possible, it is also possible to fill the open ring tube, for example with foam, or the ring through a porous permeable membrane on the body to close facing side. Support is also possible by means of a longitudinally extending helical spring inserted in the annular chamber or other supporting structures.

In order to avoid that the interior of the bellows or the like, which is flushed through the transmission liquid through supply and discharge openings. contains unwanted air bubbles, ventilation hoses can be introduced from the outside into the area of the shock wave generator and the sealing edge, which can remove any air that has accumulated from the liquid space. The invention also has the advantage that piezoelectric transducers can be arranged uniformly distributed over the circumference in the annular cavity within the sealing edge. The echo pulses received by these transducers and thrown back by the calculus lead to pressure pulses on the piezo transducers. These impulses can be evaluated in a device and, in their entirety, allow the concrement to be located.

The invention is illustrated in the drawing using exemplary embodiments and is explained below. Show it:

1 shows a schematic longitudinal section through a device according to the invention for the mechanical acoustic coupling of a shock wave generator for crushing concrements in the human body,

2 is a perspective sectional view through the open ring hose acting as a sealing ring in a first embodiment,

3 is a partial section similar to FIG. 2, but in a second embodiment,

4 shows a partial section similar to FIG. 2 but in a further embodiment,

5 shows a schematic representation of the arrangement and mode of operation of piezoelectric transducers in the lip profile of the ring tube,

6 shows a diagrammatic representation of the echo pulses picked up by the transducers of FIG. 5 depending on the position of the concrement, 7 is a schematic representation of the circuit of the converter of FIG. 5,

FIG. 8 shows the schematic representation of a display of the echo pulses evaluated according to FIG. 7 on a screen and

9 shows the schematic representation of the evaluated pulse displays on two screens, which show a stereographic view with a spatial image of the position of the concrement and the focus to be aligned thereon.

In Fig. 1, a flexible bellows 2, for example made of rubber or a similar material, is tightly connected to a shock wave generator 1, as described, for example, in DE-OS 33 12 014, the 'inside' of which space is supplied via a feed line, for example a feed hose 8, with a liquid which is suitable for shock wave transmission and which can leave the interior again via the outlet hose 9. This flushing of the interior serves on the one hand to dissipate heat, but on the other hand it also enables a volume compensation which is necessary if the open edge 2a of the bellows.2 is to be adapted to the skin 3a of the body 3 in such a way that that, for example, a concretion 10, for example the stone of a kidney 11, should be in the focus of the known shock wave generator 1 in the human body 3. On the open edge 2a of the bellows 2 there is an annular chamber in the form of a flexible hose 4 which is open on one side and which, for example, is vulcanized in one piece onto the fold sheet 2 or can be tightly attached in another way. The hose 4 is each provided with a sealing lip 5b directed towards the interior of the bellows 2 and with an outwardly directed sealing lip 5a, both of which are pressed tightly against the skin 3a of the body 3 when the Interior 12 of the hose 4 is connected via a connecting line 13 to a vacuum source, not shown.

The ring-shaped hose 4 is thereby held firmly on the body and it is possible both to fill the transmission fluid into the bellows 2 without it being able to run out at an undesired point, but it is also possible to push the shock wave generator 1 into the for treatment to bring necessary position. The bellows 2 can deform accordingly in its length or position without its end, which is firmly seated on the body 3, being influenced by the edge 2a.

In the embodiment shown in FIG. 1, the skin 3a of the body 3 will pull into the space 12 under the pressure present in the annular space 12, which in some circumstances can lead to an undesirable influence on the patient's skin. In order to avoid this, the open part of the hose 4 facing the body 3 can also be closed off according to FIG. 4 by a "porous permeable membrane 17 or the like, which can prevent the skin 3a from being sucked in excessively. It is possible However, as shown in FIG. 3, in the embodiment of the hose 4 shown, which is open to the body 3, it also fills the annular interior 12 with a porous material, for example with foam 16, which supports the application from negative pressure, but prevents the skin 3a from being sucked in excessively, as shown in Fig. 2, it is also possible to insert an annular helical spring 15 into the annular space 12 of the hose, which can likewise prevent the skin from being sucked into the annular space 12.

For example, a vacuum pump can be connected to the connecting line 13, which is already provided, for example, in the electromagnetic shock wave generator 1 used to apply the shock wave membrane to the coil arrangement. If the width of the annular space 12 within the hose 4 is chosen, for example, with a centimeter and as the diameter Provided for this hose 4 of about 12 cm, an effective pressing force in the area of the ring seal of about 36 kp can be achieved. This force could not be applied by mechanical stress on a patient. It is sufficient to achieve an adequate seal.

5 schematically shows that a plurality of piezoelectric transducers 20 to 35 are arranged in the annular space 12 of the hose 4 and are distributed uniformly over the circumference of the circle formed by the hose 4. The transducers can, for example, be partially or fully vulcanized into the hose 4. Due to the chosen arrangement ^', therefore, the converter together with the hose 4 to the patient's skin and can echo pulses as are indicated by the arrows 37, which are reflected from the calculus 11, to record. These echo pressure pulses lead to the generation of current pulses in each of the transducers 20 to 35, as are indicated schematically in FIG. 6. The shockwave pulse emitted to locate the concrement 11 or another concretion 11 'can take place from the generator 1 with somewhat weakened energy. However, it would also be possible, for example, to apply only one of several coils assigned to the generator 1 to generate a pressure surge. The resulting echo pulses 37 can be evaluated accordingly and used to locate the calculus 11.

6, in which the circumference U with the transducers 20 to 35 evenly distributed thereon and the time t and the pulse strength associated with each transducer are plotted upward in a coordinate system, the behavior of the reflected echo pulses 37 and the response of the transducers triggered by them clearly. It is initially assumed that, when the focus of the generator 1 is correctly aligned with the concretion 11, this concretion 11 lies on the axis of symmetry of all transducers 20 to 35, which also corresponds to the axis of the generator 1 and the hose 4. In this case receive all individual transducers 20 to 35 by the echo pulses 37 pressure surges of the same order of magnitude. These echo impulses reach the transducers after the time t_, which is fixed at a predetermined incremental distance from the transducers at predetermined dimensions of the hose 4. If this is the case, the correct position of the calculus 11 in the focus can be determined by an evaluation device, which will be described schematically. If the pulses reach the transducers 20 to 35 at a time t - which is less than t _{R /} then the concretion 11 lies in front of the focus 10, ie still in the area of the dash-dotted envelopes 38 of the shock wave which is centered in the focus 10. If the echo signals reach the transducers at time t ₂ , then the concretion lies behind focus 10. In all cases (t, t-, t), however, the concretion is arranged on the axis of symmetry of the transducers when the individual pulses, as in t indicated, all converters 20 to 35 are the same size

If this is not the case, for example as at time t. or indicated at time t_, the deviation of the position of the calculus 11 from this axis of symmetry can also be determined from the inequality of the echo signals. At times t. and t-, it is also determined at the same time that the concrement is too close to the generator or too far away from it. A corresponding correction is therefore necessary to be able to smash the concrement. In the embodiment shown, the concrement 11 lies on the axis of symmetry 60 of the annular space 12. In this case, the axis of symmetry 60 coincides with the axis of symmetry 60 'of the generator 1. However, if the concrement, as indicated by 11 ', lies outside the axis of symmetry 60 of the annular space, then the generator axis of symmetry 60' must be pivoted by the spatial angle β. The resulting change in position between the annular space 12 and the generator 1 must be in the evaluation as well .as a change of the distance between the center point 63 of the _(Ring¬ be taken berücksich¬ space 12 and the center 64 of the generator. 1 This can be done by a Position transmitter 61 is connected between the annular space 12 and the generator. Such position sensors, which are mechanically coupled, are known. Inductive, ohmic or capacitive position sensors of a known type can be used. It is more elegant, however, if, in addition to the echo pulses, the direct primary pulses directly incident on the converters 20 to 35 from the generator 1 are also detected in the evaluation device 41 and used as reference signals for determining the position of the generator 1. This is indicated schematically in FIG. 6 at time t-, where the axes of symmetry 60 and 60 'coincide, or at time t _Q , where there is a change in position of the generator 1 relative to the annular space 12.

FIG. 7 shows that all transducers 20 to 35 are each connected to an evaluation device 41 via connecting lines 39 and 40, which result from the different echo signals explained with reference to FIG. 6, their position in time and their course - After taking into account a possible change in position of the generator 1 to the annular space 12 - the position of the concrement 11 relative to the focus 10 is determined. In the sense of arrow 42, this evaluation device 41 can send signals to a display device

Issue 43, which is indicated schematically in Fig. 8. This display device 43, which can be a two-dimensional screen, for example, is provided with a crosshair 44, the center of which corresponds to the focus 10. If the evaluation device 41 determines that the concrement 11 is in focus, the display 45 in the form of a luminous dot or the like. given that the operator shows the correct location of the calculus. The smashing can begin.

If the evaluation device 41 determines that the concrement 11 is at the same distance from the generator 1 as the focus 10 •, but is not arranged on the axis of symmetry, then a display similar to the display 45 can take place, which, however, is 'indicated as 45' is on a radius around the crosshair

44 lies, which is also the lateral removal of the concrement from focus. The display 46, which can take the form of a circle, for example with certain symbols, which are indicated here in the form of a cross, shows that the concretion in front of the focus 10 lies on the axis of symmetry. The circular display 47, which can be provided with symbols, for example in the form of small circles, indicates that the concretion is behind the focus on the axis of symmetry, while the two displays 48 and 49 show that the concretion (display 48) before Focus and laterally offset to the axis of symmetry, while the display 49 indicates that the concrement has been located behind the focus and laterally offset to the axis of symmetry. The position of the circular displays 48, 49 to the crosshair 44 is such that the angle of the deviating position is also detected. Of course, it would be possible to provide a continuously illuminated display and a flashing display instead of the display using symbols such as crosses or small circles, both display types being assigned to the position of the concretion in front of or behind the focus. A differently colored or different distance identifier is also possible. By looking at the display device 43, the operator therefore has the possibility of shifting the focus 10 by another arrangement of the generator 1 until the display 45 occurs, the position of the generator relative to the converters 20 to 35 in FIG Evaluation device 41 must also be taken into account. As a result of this measure, the annular space 12 with the transducers is apparently, ie computationally, tracked to the generator in such a way that the axes of symmetry 60 and 60 'coincide again.

Another possibility, as indicated schematically in FIG. 9, is that the evaluation device 41 emits two evaluation signals 50 and 51, which are displayed on separate screens 52 and 53. Both screens, each provided with a crosshair, together draw a spatial image of the position of the concrement 11, which by using known polarizing glasses 54, with the both screens are viewed together, each with a polarization film in front of them, can be brought to coincidence. A spatially stereoscopic representation of the concrements is then created together with the focus of the shock wave generator, which is indicated as a spatial crosshair. The operator then has the direct possibility of bringing the focus 10 of the arrangement into congruence with the concrement 11. In contrast to the previously described type of correction, with this type of display the generator, although it is being moved, is apparently, ie computationally, held in its starting position.

Claims

Expectations

1. A device for the mechanical acoustic coupling of pressure waves, in particular of focused shock waves for the contact-free destruction of concretions in the body of living beings, with a shock wave generator and a liquid adjacent to it, or the like by a flexible bellows. is enclosed and adjoins the body, characterized in that the open edge (2a) of the bellows (2) facing away from the shock wave generator (1) is provided with a circumferential, pressurized annular chamber (4) for sealing lips (5a, 5b) Apply to the body both on the inside of the bellows (2) and on the outside.

2. Device according to claim 1, characterized in that the annular chamber is designed as a flexible hose (4).

3. Device according to claims 1 and 2, characterized gekenn¬ characterized in that the hose (4) is open on one side.

4. Device according to claims 1 to 3, characterized gekenn¬ characterized in that the hose (4) with supporting structures (15, 16) is filled.

5. Device according to claim 4, characterized in that foam rubber (16) is provided as the supporting structure.

6. Device according to claim 4, characterized in that a helical spring (15) extending in the hollow annular space (12) of the hose (4) is provided as the supporting structure.

7. Device according to claims 1 and 2, characterized gekenn¬ characterized in that the hose (4) on the side facing away from the shock wave generator (1) is closed by a porous or permeable membrane (17).

8. Device according to claim 1, characterized in that in the interior of the bellows (2) on the side of the shock wave lengenerator (1) facing and / or on the side of the annular chamber (4) ventilation hoses (6, 7) are introduced .

9. Device according to claim 1, characterized in that in the annular chamber (4) piezoelectric transducers (20 to 35) are brought an¬.

10. The device according to claim 9, characterized in that three or more piezoelectric transducers (20 to 35) are evenly distributed over the circumference of the annular space (12).

11. The device according to claim 9 and 10, characterized gekenn¬ characterized in that the piezoelectric transducers (20 to 35) are connected to an evaluation device (41), the arrival and size of the echo signals from the calculus (11) with respect to the position of the Focus (10) compares and makes this position of the concrement (11) visible on a display device (43).

12. The device according to claim 11, characterized in that two screens (52, 53) are provided as the display device are, which when viewed together give a spatially steroscopic image of the concrement arrangement and the position of the focus (10).

13. The device according to claim 11, characterized in that the evaluation device (41) is a position transmitter (61) vorge¬ switched, the distance between the center (63) of the annular space (12) and center (64) of the generator (1) and determines the spatial angle (j->) between the axis of symmetry (60 of the annular space (12) and the axis of symmetry (60 ', 60) of the generator (1).

14. Device according to claim 11, characterized in that the evaluation device (41) takes over the function of a position sensor and determines the relative position between the annular space (12) and generator (1) in that, in addition to the echo signals, those received directly from the transducers Generator signals are detected and serve as reference signals for determining the relative position.