DE3703335A1 - Lithotripter with polyvinylidene fluoride film as locating element - Google Patents

Abstract

The lithotripter for breaking up a concretion (19) in the human body (17) comprises a shock wave source (1) which emits shock wave pulses and a focusing device (11). In front of the focusing device (11), viewed in the direction of propagation of the shock wave pulses, is a polyvinylidene fluoride film (30). The polyvinylidene fluoride film (30) is provided with piezoelectrically activated areas which form a linear ultrasonic array with elongated ultrasonic transducer elements. The ultrasonic transducer elements are connected to a memory which stores the echo signals received in each case in response to a shock wave pulse. By providing the echo signals of the individual ultrasonic transducer elements with predetermined delay times in the manner of a synthetic antenna, an obliquely positioned (that is to say pivoted) reception beam can be simulated. A focus point (F2) corresponds to the obliquely positioned reception beam on the concretion side of the lens (11). By differently timed activation, this focus point (F2) can be pivoted about the area of the concretion (19) in a sector shape. In this way, positional monitoring of the concretion (19) with the aid of the diagnostically usable frequency portions of the reflected signals of the shock wave pulse is possible. Preferably, a second polyvinylidene fluoride film (32) is provided for observations perpendicular to the plane of observation of the first array. <IMAGE>

Description

The invention relates to a lithotripter with a shock wel lengenerator for generating a shock wave pulse, the one plane wavefront, and with an acoustic lens, which focuses the shock wave pulse on a focus point.

Such a device for crushing concrement is at known for example on DE-OS 33 28 039. There is as Shock wave source used a shock wave tube, which a electrical coil, an insulating film and a copper membrane includes. If a current pulse is applied to the coil, so creates eddy currents in the upstream membrane, which Knock the membrane away from the coil. In the adjacent over carrier medium, e.g. B. water, a shock wave forms. This is focused by an acoustic lens whose focal point point after an adjustment process in the concretion of the pati ducks. For example, a never comes as a concretion renstein into consideration.

The location of the concrement is of great importance. The bigger the accuracy is the greater the therapeutic Success and the smaller the burden on the patient. It is known to make the location with X-ray equipment. Indeed can not because of the radiation exposure during the whole shock wave treatment, the position of the stone can be checked. X-rays are only taken from time to time to check the position of the stone. For a continuous You are therefore already monitoring the stone position proceeded to the location of the calculus with ultrasound to make. For example, from DE-PS 34 27 001 Location and positioning method known, in which means the concrement is located by an ultrasonic transducer  given marker marks and then one mechanical correlation of the position of the calculus with the Focal point of the shock wave system is made.

Furthermore, it is known from DE-OS 31 19 295, the location the concretion with the shock wave source itself. in the system described there, the shock wave source is an arrangement voltage from a variety of piezoelectric transducer elements. There through there is the possibility of the shock wave pulse itself or its frequency components in the diagnostic range to locate the concrement. This procedure can however only with a shock wave source whose shock waves in the pulse with piezoelectric elements is called be applied.

The principle of the so-called synthetic antenna is from the publications US-PS 43 25 257, Proc. 6th boarding school Symp. Acoustical Holography, Plenum Press, New York (1975), p. 193 ("Digital Computer Simulation Study of a Real-Time Collection, Post-Processing Synthetic Focusing Ultrasound Cardiac Camera") and the article "Acoustic Imaging by Wave Field Extrapola tion: Part II: Practical Aspects" by J. Ridder, AJ Berkhout and LF v .d. Whale known.

The object of the invention is to provide a lithotripter type mentioned so that an ultrasonic Locating the calculus using the impact sent wave pulse as an ultrasonic transmission signal regardless of special training of the shock wave source is possible.

This object is achieved in that a PVDF film with piezoelectrically activated areas linear ultrasound array with elongated ultrasound wall lerelemente form between the shock wave generator and the Lens is arranged.  

An advantageous embodiment of the invention provides that a second PVDF film with piezoelectrically activated area chen, which is a second linear ultrasound array with long stretched ultrasound transducer elements form between the Shock wave generator and the lens is arranged, the the two linear arrays are preferably perpendicular to one another.

The advantage of the new lithotripter is that the PVDF film un depending on the design of the shock wave source used in the Reproductive path of the shock wave pulses can be arranged. The PVDF film only serves as the receiving film for the im diagnostic frequency range of e.g. 3 to 4 MHz Frequency components of the reflected echoes that occur when striking of the shock wave impulse on the calculus.

Further advantages and refinements of the invention result from the description of an embodiment using the Figure.

The figure shows a lithotripter with a lens and vorgela PVDF film as a receiving array for location.

An electrodynamic shock wave source 1 is shown in the figure. The shock wave source 1 comprises an electrical coil 3 , in front of which a copper membrane 7 is arranged, separated by an insulating film 5 . A voltage pulse U can be applied to the coil 3 . A water inlet section 9 connects to the copper membrane 7 . In the water flow path 9 there is a lens 11 as a focusing device. The water supply section 9 is closed by a coupling membrane 13 . A cylindrical tube part 15 , which is closed on one end of the shock wave source 1 and on the other end of the coupling membrane 13 , forms a housing. This is filled with the coupling liquid water.

The coupling membrane 13 is applied to the skin surface of a patient th 17 . The shock wave source 1 is positio ned so that the focus F of the lens 11 coincides with the location of the calculus 19 to be disruptive, for example a kidney stone. When viewed in the direction of propagation, a first PVDF film 30 is located in front of the lens 11 . The PVDF film 30 is perpendicular to the central axis 25 , which is formed by the shock wave generator 1 and the lens 11 , aligned.

The PVDF film 30 is provided with piezoelectrically activated areas which form a linear ultrasound array with elongated ultrasound transducer elements. The longitudinal axes of all parallel transducer elements are, for example, perpendicular to the paper plane. It is expedient to provide a second PVDF film 32 with piezoelectrically activated areas which form a second linear ultrasound array with likewise elongated ultrasound transducer elements. The two linear arrays should be perpendicular to each other. The second PVDF film 32 is expediently to be arranged closely adjacent and parallel to the first PVDF film 30 .

If a shock wave impacts the concrement 19 or possibly an air bubble, echoes are reflected, which are used in the range between approx. 3 to 4 MHz for a diagnostic ultrasound device. The ultrasound array formed on the first PVDF film 30 works on the principle of the synthetic antenna, as is known, for example, from the publications mentioned at the beginning. The echoes resulting from the ultrasound transmission pulse (shock) are received by the ultrasound transducer elements of the linear ultrasound array. The high-frequency echo signals are stored in a memory. Then the echo signals are synthetically assigned delay times that correspond to an inclined, swiveled receiving beam for plane waves. This inclined received beam is collected on the patient side of the lens 11 in a focus point F 2 . Is an axis perpendicular to the main axis 25 by different, linearly dependent on x time allocation of the echo information of the individual transducer elements and shifting the center of the active aperture, so that the center on the connecting line between the focus F 2 and the center C of the lens 11 to lies, the focus F 2 can be varied in the paper plane around the focus F of the lens 11 in the area which was still "sufficiently illuminated" by the shock wave. This creates an electronic sector scan with the fulcrum in the center of the lens C. Dynamic reception focusing is also possible. Accordingly, the second ultrasonic array formed by the second PVDF film 32 is used, the scanning plane of which is perpendicular to the paper plane. In this way, a spatial overview of the position of the calculus 19 in comparison to the focal point F of the lens 11 can be obtained from a single shock wave pulse.

In the present case, the imaging takes place according to the known principle of the synthetic antenna. What is important, however, is the interaction of the above-mentioned components with flat, tilted and displaced ver waves and the effect of the lens 11 .

The advantage of this device is that the shock wave pulse itself is used for ultrasound location of the concrement 19 and for monitoring its position. This can be done with a suitable arrangement of the PVDF film 30 regardless of the type of shock wave source 1 . This automatically monitors the sound access. The shock echo also contains information about the success of the therapy. The impact focus is also shown.

Preferably, the foils 30 , 32 are rotatable about the central axis 25 , so that a larger volume is achieved.

Claims (4)

1. Lithotripter with a shock wave generator for generating a shock wave pulse that has a flat wavefront, and with an acoustic lens that focuses the shock wave pulse on a focal point, characterized in that a PVDF film ( 30 ) with piezoelectrically activated areas that a Form a linear ultrasound array with long-placed ultrasound transducer elements, is arranged between the shock wave generator ( 1 ) and the lens ( 11 ). 2. Lithotripter according to claim 1, characterized in that the PVDF film ( 30 ) is aligned perpendicular to the central axis ( 25 ) between the shock wave generator ( 1 ) and the lens ( 11 ). 3. lithotripter according to claim 1 or 2, characterized in that a second PVDF film ( 32 ) with piezoelectrically activated areas forming a second linear ultrasound array with elongated ultrasound transducer elements between the shock wave generator ( 1 ) and Lens ( 11 ) is arranged, wherein the two linear arrays are perpendicular to each other. 4. Lithotripter according to one of claims 1 to 3, characterized in that the PVDF film ( 30 , 32 ) is rotatable about the central axis ( 25 ).