DE8619099U1 - Shock wave generator for generating an acoustic shock wave pulse - Google Patents

Description

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Shock wave generator for generating an acoustic shock wave pulse

The invention relates to a shock wave generator for generating an acoustic shock wave pulse.

Such a shock wave generator is known, for example, from DE-OS 33 28 051. This describes a so-called "shock wave tube" for lithotripsy, which comprises an electric coil and a copper membrane separated from it by an insulating foil. If a capacitor is suddenly discharged via the coil, electromagnetic forces are formed which knock the copper membrane away from the coil and thereby emit a shock wave pulse. Adjacent to the copper membrane is a lead path via which the shock wave pulse is passed on to a lens as a focusing device. The focus of the lens is the patient's calculus, which is to be destroyed. Devices of this type have been introduced into medical technology as lithotripters.

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In practice, it has been shown that treatment situations vary from patient to patient . These depend, for example, on the type and size of the calculus to be destroyed, on the geometry of the calculus

(e.g. round or oblong) the distance of the calculus from the skin surface (determined by the position of the stone or the patient’s body size) and the number of calculi. In addition to these different initial situations due to different patients, there are also

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WiI 2 Sir / 07.07.1986

.5.'..''., ¹ J 2 -..·'..* VPA 86P3 23 20£ different conditions arise due to the progress of the treatment. At first relatively large fragments are produced in an extensive zone of action, and in the later course of the treatment predominantly removal and comminution into small particles in a more limited zone of action is desired.

In order to adapt to these different treatment situations, it has been necessary to either change the discharge voltage of the capacitor or to change the distance of the focusing device to the focus location. These measures are not yet sufficient to satisfactorily adapt the shock wave generator to the large number of different treatment situations.

The object of the invention is therefore to design a shock wave generator of the type mentioned at the beginning in such a way that it can be easily adapted to a large number of different treatment situations, so that it enables more effective treatment in lithotripsy in particular.

If it is a shock wave generator with a capacitor connected, this object is achieved according to the invention by providing several capacitors which are used with selectable capacitance to trigger the shock wave pulse.

If it is a shock wave generator with a lens of predetermined beam characteristics as a focusing device for the shock wave pulse on a focus area, the object is achieved according to the invention by providing several lenses with different beam characteristics, each of which can be introduced into the path of the shock wave pulse.

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'..· VJ j.VV VPABBP 3 2 3 2 fit /&Lgr; If it is a shock wave generator with a pre-running distance between the shock wave emitting surface and a focusing device, the above-mentioned task is solved according to the invention in that the length of the pre-running distance can be adjusted by moving the shock wave emitting surface.

With regard to the change in capacitance, investigations into a shock wave tube with a diameter of 12 cm have shown that if the capacitance is reduced from 1 pF to 0.5 pF, for example, the duration of the discharge current can be shortened from 5 us to 3.5 us. An advantageous consequence of this is that the radiated shock wave pulse is correspondingly shorter and the shock wave pulse is shortened after focusing even in the amplified mode. A shorter focused pulse has a lower energy content and a more narrowly defined zone of effect at a comparable pressure amplitude. The result can be a more local removal instead of a shattering.

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The term "beam characteristic ¹ *" in connection with the lenses refers to both the focal length and the type of lens. In the case of calculi close to the skin or in children, a better degree of focus can be achieved with reduced acoustic power by using a lens with a short focal length and a large opening angle than with a lens with a long focal length and a small opening angle. This results in a more gentle treatment overall. Deep-seated calculi,

e.g. in corpulent patients, require a lens with a longer focus in order to achieve an optimal effect. The use of cylindrical lenses (e.g. bicylindrical or spherical/cylindrical) offers advantages in the treatment of extensive concretions or in the event that several adjacent concretions are to be treated at the same time.

f\ The choice of capacitance, lens and/or delay line in conjunction with an appropriate choice of capacitor voltage and the distance of the focusing device from the patient's skin may be adjusted from patient to patient or even for one and the same patient as the treatment progresses.

Further advantages and embodiments of the invention emerge from the description of embodiments based on the figures. They show:

Fig. 1 a block diagram of a shock wave generator

with variable capacity, lens position and \ Lead line,

Fig. 2 shows a shock wave tube with a cross-section showing a design solution for changing the delay line and for adjusting and selecting lenses, and Fig. 3 shows a view along the arrows III-III of Fig. 2. j I Fig. 1 shows a shock wave generator 1 which is specially designed as a shock wave generator and comprises a flat coil 3, a delay line 5 and a focusing device 7. A membrane 11 made of bronze or copper is arranged in front of the flat coil 3 - separated by an insulating foil 9. The delay line 5 between the membrane 11 and the focusing device \

7 is filled with a coupling medium, e.g. water. i

If the flat coil 3 is subjected to a voltage pulse, the membrane 11 is suddenly repelled due to electromagnetic force. This generates an acoustic shock wave pulse on the delay line 5. This shock wave pulse, which is essentially flat on the delay line 5, is focused by the focus

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FS sification device 7 focuses on a focus F. The focus F is placed in the area of a concretion K in the body of a patient P to be treated.

The flat coil 3 is connected at one end to a reference potential 13 such as ground and at its other end to a spark gap 15. The spark gap 15 is provided with an auxiliary electrode 17, with the help of which it is ignited. The auxiliary electrode 17 is controlled by a trigger device (not shown). The spark gap 15 is also connected to a capacitor bank 19. In the schematically shown embodiment, the capacitor bank 19 consists of a capacitor C ₁ and a capacitor C ₂ . The capacitor C ₁ has, for example, the capacitance 1 pF and the capacitor C ₂ has the value 0.5 pF. Either the capacitor C ₁ or the capacitor C ₂ is connected to the spark gap 15 via changeover switches 21, 21a. Alternatively, the capacitor bank 19 can consist of a large number of different capacitors C ₁ , one of which can be optionally connected to the spark gap 15. Alternatively, the capacitor bank 19 can also consist of a number of identical capacitors C ₁ which can be connected in parallel or in series via switching means, so that different capacitances are obtained. A mixed form of different capacitors C ₁ is also possible, with the simultaneous possibility of setting up parallel and/or series circuits.

A control contact 22 of the switch 21 is connected to a first control and feedback device 23, which is connected to a computer 25 for determining a parameter of the shock wave pulse, such as its pressure, its pulse duration or its focus geometry. The first control and feedback device 23 sets a desired capacitance on the capacitor bank 19.

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The focusing device 7 comprises several lenses, which can be optionally introduced into the course of the shock wave pulse. A second control and feedback device 29 serves to move, rotate and detect the lenses and to feed back this data to the computer 25.

The possibility of moving the membrane 11 to change the length of the pre-run section 5 is indicated by a double arrow 31. A structural implementation for changing the length of the pre-run section 5 is explained in more detail in Fig. 2. The position of the membrane 11 is also controlled, recognized and evaluated by the computer 25 via a third control and feedback device 33.

According to the embodiment shown, the computer 25 has four inputs to which a status signal relating to the capacitance selection, the capacitor voltage, the lens _selection and the length of the delay line is applied. From this information, the computer 25 forms an output signal A which corresponds to the resulting value of a parameter of the shock wave pulse. Such a parameter can be, for example, the peak pressure of the shock wave pulse, its pulse duration or its focus geometry. The computer 25 has an output 35 via which the output signal A is passed on to an image device 37. The image device 37 can be a device for displaying the X-ray or ultrasound image.

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in the examination area of patient P, with the values of the parameters of the shock wave pulse displayed in the image.

The advantage of the shock wave generator 1 shown is the high variation potential with regard to its operating data. The duration and amplitude of the shock wave pulse as well as the extent of the focus zone - e.g. the -6 dB zone in relation to the pressure maximum - can be influenced via the adjustable capacity of the capacitor bank 19. By moving the shock wave radiation surface, in the exemplary embodiment by moving the membrane 11, the length of the delay section 5 is changed. The steepness of the shock wave pulse at the location of the focusing device 7 can thus be continuously changed. The possibility of exchanging the focusing device 7 for another is particularly advantageous. For example, at the beginning of treatment with an extensive concretion K, a cylindrical lens with a line focus can be used. At a later point in time, a spherical lens with a point-like focus area is switched to in order to achieve a better effect on the now smaller fragments.

In Fig. 2, identical parts are provided with the same reference numerals.

Fig. 2 shows essentially constructive design examples for changing the length of the lead section 5 and

for replacing the focusing device 7. The flat coil 3 with insulating foil 9 and the membrane 11 is

as a closed coil carrier 40. The coil carrier 40 is attached to several rods 42a, 42b, at least one of which is designed as a threaded rod 42a and which are held by a support frame 43. By turning the threaded rod along the

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f~) curved double arrow 44, the coil carrier 40 and thus the radiation surface for the shock wave pulse (* surface of the membrane 11) is displaced along the longitudinal axis L of the shock wave generator 1. If the focusing device 7 is located at a predetermined coordinate on the longitudinal axis L, the length of the delay section 5 changes by displacing the coil carrier 40 via the threaded rod 42a. The cylindrical casing delimiting the delay section 5 is designed as a flexible bellows 45 so that changes in the distance can be easily compensated.

No new adjustment of the shock wave generator 1 is necessary if the patient P changes. Since the focusing device 7 is stationary, the arrangement of the focusing device 7, focus point F and calculus K remains unchanged. A coupling layer 46 that may be present remains unchanged on the patient P when the coil carrier 40 is moved.

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In Fig. 3, in conjunction with Fig. 2, the possibility of selecting and exchanging the focusing device 7 is shown. Two lenses 7a, 7b are mounted on a quarter-circle-shaped holder 48 as focusing screens.

The lenses 7a, 7b have | r , , different bundle characteristics (focal length, focus range). The holder 48 has a pivot point 50. j It is held there so that it can rotate about an axis D parallel to the longitudinal axis . The pivot point 50 is simultaneously the center point.

point of a hole 52. Through the hole 52 is a ]

Pin 54 is guided, the axis of which runs parallel to the longitudinal axis L I of the shock wave generator 1 and is simultaneously the axis of rotation D around which the holder 48 can rotate. The pin 54 is connected to the shaft of a motor 56.

The adjustment of the lenses 7a, 7b and the feedback as to which lens 7a, 7b is inserted can be carried out via the motor 56. i

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(~) The holder 48 can also be designed as a full circular disk with a large number of poking devices or lenses 7. Alternatively, it is possible to design the holder as a slide or carriage and to insert the lenses - similar to the slides in a slide projector - into the course of the shock wave impulse.

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Claims (12)

claims 1 ' :.J &Igr;&Ogr; -:..::..: VPAMP 3 23 2BE ·*·* · ff s «it·· 1. Shock wave generator for generating an acoustic shock wave pulse by connecting a capacitor, characterized in that several capacitors (C ₁ , C ₂ ) are provided which are used with selectable capacitance to trigger the shock wave pulse. 2. Shock wave generator for generating an acoustic shock wave pulse, in particular according to claim 1 ₁ with a lens of predetermined beam characteristics as a focusing device for the shock wave pulse on V ) a focus area, characterized in that several lenses (7a, 7b) with different beam characteristics are provided, one of which can be inserted into the path of the shock wave pulse. 3. Shock wave generator for generating an acoustic shock wave pulse, in particular according to claim 1 or 2, with a delay line between the shock wave emitting surface and a focusing device, characterized in that the delay line (5) can be adjusted in its length by moving the shock wave emitting surface. 4. Shock wave generator according to one of claims 1 to 3, characterized in that the capacitors (C ₁ , C ₂ ) are combined to form a capacitor bank (19) with adjustable capacitance. 5. Shock wave generator with a longitudinal axis according to one of claims 2 to 4, characterized in that the lenses (7a, 7b) are arranged on a carriage which can be moved transversely to the longitudinal axis (L). JJ 4 · tit« « III ttt i ti ItI ti it' Il II* · Il 111· ■ · 1 ■ &bull; · · ■ a ■ .:.*..* *.. 1 Ii -·.."..· VPAMP 3 23 2OE 6. Shock wave generator with a longitudinal axis according to one of claims 2 to 4, characterized in that the lenses (7a, 7b) are arranged on a holder (48) which is rotatable about an axis (D) can be rotated parallel to the longitudinal axis (L). 7. Shock wave generator according to one of claims 1 to 6, characterized in that the discharge voltage of the capacitor (C) is adjustable. 10 8. Shock wave generator according to one of claims 1 to 7, characterized in that a first capacitor (C,) with 0.5 pF and a second capacitor ( ) capacitor (C ₂ ) with 1 pF. is provided, and that the capacitance for triggering the surge pulse is formed from at least one of these capacitances. 9. Shock wave generator according to one of claims 2 to 8, characterized in that the Lenses (7a, 7b) have different focal lengths. 10. Shock wave generator according to one of claims 2 to 9, characterized in that the lenses (7a, 7b) have different focus areas. _ 25 / &lgr; 11. Shock wave generator according to claim 10, characterized in that the focus areas are spherical and/or cylindrical. 12. Shock wave generator according to one of claims 1 to 11, characterized in that a control device (25) is provided, at the input of which a status signal relating to the capacitance selection, capacitor voltage* lens selection and/or length of the delay line (5) is applied and at the output (35) of which a calculated result If ■· * M i * ·· t* I ■· «It it 11 * * I &igr;· ·&igr;· « · * &igr; *· ti &igr; ttt * * *«* · · in &igr;*· it t· te* 4* ti ·· Il The value of a parameter of the shock wave pulse (such as its pressure, pulse duration or focus geometry) 13, Shock wave generator according to one of claims 1 to 12, characterized in that it comprises a shock wave tube with a metal membrane (11). 10