DE3833862A1 - COMBINED SHOCK WAVE SOURCE - Google Patents

Description

The invention relates to a device for generating focused shock waves according to the generic term of Claim 1. Under shock waves here too understood weaker pressure pulses, their intensity sufficient to change in bodies of living things to cause, e.g. Movement of stones or Tissue heating.

From DE-PS 23 51 247 is a lithotripter with a punctiform shock wave source and an image system (a reflector). This device forms the preamble of claim 1.

From DE-OS 31 19 295 is a lithotripter known source. This is either as Ball dome designed self-focusing or just. Imaging systems are then used for focusing such as reflectors, lenses or electrical controls the different zones of the shock wave source needed.

From the German utility model 88 02 995 is a Lithotripter with two shock wave sources known. To the  one shock waves are generated extracorporeally and through the skin to the stone, to the other the shock waves at the end of an optical fiber nearby of the stone.

The object of the invention is to be flexible and much side shock wave source, especially for the litho propose tripsie that have the positive characteristics of the individual shock wave sources known per se like high flexibility and high smashing performance united.

This object is achieved by one Device with the features of claim 1. Ausge Events of the invention are the subject of sub claims.

The core of the invention is the double use of the Abbil system by shock waves that differ from two where sources come from.

In a preferred embodiment, the second push is a flat, circular oscillator (e.g. a disk covered with piezoceramic elements). The Imaging system is a rotationally symmetrical body with flat back and curved front. This Body is designed to be for the point source as a reflector and for the extensive shock wave source works together with the medium in the reflector as a lens, so that with suitable dimensioning and choice of material both sources have a common object-side focus have. The second shock wave source and the imaging bodies are preferably rotationally symmetrical trained, in particular the body has one Rotating ellipsoidal front surface. The first Shock wave source is preferably in the  Axis of symmetry of the two aforementioned components.

A common focus and ideal geometric Imaging properties (no spherical aberration) exist when ellipsoid eccentricity and object refractive index match. In addition to the The system's focal length determines the latter Condition the selection of suitable materials and the geometric shape.

The imaging system - for example when the reflector is filled with water - preferably consists of a metallic material with which the double action (lens and reflector) can be achieved. The imaging system is flush with the flat shock wave (e.g. the piezoceramic transducer or the transducer), which can be achieved by gluing or friction welding. In the middle of this body there is a central, axial opening in which, for example, the first shock wave source (the electrode) is arranged. The ellipsoid of revolution formed by the front surface of the imaging body can be closed off for use with a water cushion for coupling to the patient's body.

The flat transducer can be segmented. This segmentation can e.g. with a piezokera Mix transducers consist of individual elements (mosaic-like design) around the transducer before Zer to protect interference from high-voltage pulses. The Mechanical termination of the piezo oscillator is included chosen so that broadband acoustic pulses as possible (Shock waves) are generated.

The flat transducer can also be a dynamic one Have focus. This can be done in the segmented  Execution can be achieved in that the individual Elements are controlled radially offset in time. This makes it possible to use different foci to achieve the focus of the two shock wave systems to vary or in the case of non-ideal focusing the ellipsoid of revolution the error by electronic Control to compensate. The flat swinger can also be curved itself. This is e.g. then advantageous if the ellipsoid eccentricity and the object-side refractive index of the lens are different, so that for one or the other shock wave system results in a non-ideal focusing, which without elec tronic aids is corrected. Here is the The shape of the transducer is either concave or convex choose, depending on whether the eccentricity is greater or is smaller than the refractive index.

The imaging body can also have such curvatures have different foci within reach. This always occurs when the eccentricity and the refractive index are different. This can be beneficial be used if different in the application Focus lengths are required, due to different Stone layers or patient sizes may be necessary.

By integrating two bumps according to the invention wave sources with different properties separate electrical supply in one treatment new treatment strategies are possible. Among other things, this gives rise to the possibilities

• a) with the piezo system in the low-energy range and pre-treat different work cycles or to operate ultrasound
• b) by alternately controlling the two sources  or targeted temporal offset of the two pulses the stone destruction by the combined application to improve.

The invention is illustrated by a figure.

The figure shows a device for crushing stones in the body of a patient P. The device is arranged opposite the patient's body in such a way that the second focal point ( F 2 ) coincides with the location of the stone in the patient P. The device contains a first shock wave source, here the electrode E , the spark of which generates a shock wave lies in the focal point F 1 of an imaging body K. The body K has a rotationally elliptical symmetry and guides all shock waves generated in its focal point F 1 into the second focal point by reflection on its front side. This is indicated by the wave normal N 1 in the figure. The device contains a second shock wave source, here the piezoceramic vibrator S. This shock wave source is rotationally symmetrical and flat. The shock waves generated by the vibrator S run through the imaging body K , the front interface of which deflects the shock waves to the focal point F 2 . An exemplary shock wave is represented by the normal N 2 . The components of the electrical current and voltage supply for the two shock wave sources E and S are not shown, wherein one or both of the sources can also be strong ultrasound transmitters.

The components for the introduction are also not shown the shock waves in the patient's body, as well Versions with concave or convex curved surfaces against shock wave sources. The shape of the shock wave sources  corresponds to the back of the image Body.

Claims (8)

1. Device for generating focused shock waves, in particular for non-contact lithotripsy, with a first punctiform shock wave source and an imaging system, such as a reflector, characterized in that a second, planar shock wave source is provided and that the imaging system also generates those from the second shock wave source Shock waves focused. 2. Device according to claim 1, characterized by a behind the first shock wave source (electrode E ) arranged circular circular vibrator ( S ) as a second shock wave source and a rotationally symmetrical body ( K ) with a flat back and curved front side as an imaging system, the body ( K ) acts as a reflector for the point source and as a lens for the plane transducer ( S ). 3. Device according to claim 1 or claim 2, characterized in that the mapping system consists of a metallic material.   4. Device according to one of claims 2 or 3, characterized in that the oscillator ( S ) is segmented. 5. Device according to one of the preceding Claims, characterized in that the second shock wave source a dynamic Fo kissing has. 6. Device according to one of the preceding claims, characterized in that the second shock wave source ( S ) is curved in its upper surface and that the imaging system ( K ) on its back corresponds to the contour of the second shock wave source. 7. Device according to one of the preceding claims, characterized by such curvatures of the imaging system that the waves emitted by two shock wave sources are directed to different foci ( F 2 ). 8. Device according to one of the preceding claims, characterized in that the front surface of the imaging system (body K ) has rotational symmetry, in particular is designed as an ellipsoid of revolution, and that the first shock wave source (electrode E ) is arranged in the axis of symmetry of the imaging system ( K ).