DE202007000308U1 - Flexible probe for a shock wave lithotripter - Google Patents

Abstract

flexible Probe acting as a waveguide for an intracorporeal shockwave lithotripter is provided, which has a probe body (14) on the proximal end of the probe (11) comprises a probe foot (16) and at the distal end End of the probe body (14) a probe tip (17) for the shattering of body stones through the shock waves communicated with the probe tip (17) characterized in that the probe body (14) made of a fiber-reinforced Plastic is formed.

Description

The The invention relates to a flexible probe serving as a waveguide for one intracorporeal shockwave lithotripter is provided.

From the DE 43 13 768 A1 is a device for the mechanical fragmentation of body crumbs, a so-called shock wave lithotripter, known. This device comprises a probe which is inserted with the distal end into the body and positioned to the body calculus for its destruction. At the proximal end of the probe, a probe foot is provided, which is acted upon by shock pulses by an electromagnetic drive. The shock pulses generated by the initiated impact energy, which pass through the probe as a shock wave, exit at the probe tip and are used to break up body crumbs.

The Probes of the shock wave lithotripter can be introduced directly into a ureter. A large scope is the use in flexible endoscopes for intracorporeal fragmentation of body stones, such as urinary, bladder or kidney stones, dar.

For transmission high kinetic impact energy So far, metal probes have been used whose diameter is mostly in a range of 1 to 2 mm. When using such metal probes, which resulted in flexible endoscopes is flexibility in the use of endoscopes usually impaired, since such metal probes only a small amount of bending allow without experiencing a permanent deformation. Such lasting Deformations have an adverse effect on the transmission of the shockwaves. About that In addition, there was a risk of breakage as soon as a strongly curved Metal probe was subjected to one or more shock pulses.

To avoid this danger is from the US 5,449,363 a probe, which is flattened along the bend of the endoscope, so that the bending ability is increased. Such a device has the disadvantage that the flexibility in handling is limited because only two Biegerungen are made possible by such a flattening, which are offset by 180 ° to each other.

From the DE 198 14 364 C2 shows a flexible metal probe, which has between the proximal and distal ends of partial lengths in which the probe diameter decreases steadily from a nominal diameter at the probe foot to a smaller nominal diameter and steadily in the vicinity of the probe tip to a nominal diameter of the probe approximated larger diameter increased. Such a flexible metal probe is expensive to manufacture.

Of the The invention is therefore based on the object, a flexible probe to create which cost is to produce and a high Biegefä ability and optimal transmission the initiated impact energy allows.

These The object is achieved by the flexible probe according to the features of claim 1.

The Departure from the metal probes used and used so far and the use of a flexible probe with a probe body, the made of a fiber-reinforced Plastic, has amazingly shown that the use of a fiber-reinforced Plastic without adversely affecting the shock wave course and the work result in shattering body calculus. The use of fiber reinforced Allows plastics, that the shock wave generated with a steep rising edge of the Passes through the probe body and almost without weakening exits at the probe tip. At the same time, the probe body allows a fiber reinforced Plastic a bend while maintaining the qualitative shock wave course, in particular the steep rising edge of the shock wave. This allows the in the probe introduced impact energy be transferred to the probe tip in an optimal manner even at a bend. Such fiber reinforced Plastics also have the advantage that despite a greater bending and the introduction of high impact energies a fracture hazard is prevented.

To a preferred embodiment of the device is provided that the probe body of the Flexible probe made of carbon or glass fiber reinforced plastic is made. Such a fiber reinforcement by glass fibers or Carbon or carbon fibers allow a high tensile and compressive load of the probe body, which occurs due to the initiated impact energy. By the initiated impact energy becomes a shock wave which manifests itself as compression and expansion movements while represent the wave propagation and absorbed by the probe body and forwarded from the proximal to the distal end. simultaneously but is a high bending ability given, the transfer the shockwave from the proximal to the distal end with little effect done by the degree of bending.

According to a further advantageous embodiment of the invention, it is provided that the fibers or fiber components in the probe body are aligned parallel to the longitudinal axis of the probe body. As a result, high-quality and flexible probes can be produced that withstand high tensile and compressive loads.

Of Furthermore, it is preferably provided that the probe body of a shell is surrounded. This shell is designed for example as a shrink tube. It is preferred a teflon sleeve or a shrink tube used to protect both probe body as well as to protect the human body, provided this flexible probe is introduced directly into a ureter or the like.

The Probe tip of the flexible probe preferably has an insert or Attachment element on. This will make the free, made of fiber-reinforced plastic Probe end from damage while the smash of body stones protected and increases the life of the flexible probe. A cost-effective design of the mission or Attachment element is characterized by the use of a metallic Material allows.

to simple and inexpensive Production of such a flexible probe with a preferably metallic insert or attachment element is provided that this as U-shaped or pot-shaped Element is formed. This can safely cover the probe tip be and easy mounting and fixation allows.

The One or attachment element is preferably on the probe tip of the probe body glued on, pressed or clamped. This will be a quasi one-piece connection created between the input or attachment element as well as the probe body, so that the transmission the shockwave from the probe body on the insert or Aufsatzele element for acting on the Körperkonkrement without any adverse effect. The insert element may also be preferred in the preparation of the probe body as Insert part to be processed integrated.

To a further preferred embodiment of the insert or attachment element it is envisaged that their body concrement facing end side ground on one side or has a concave face. As a result, the scoring and / or smashing effect on the body calculus becomes elevated.

The flexible probe preferably has a probe body from the probe foot to the Probe tip with a constant or one to the probe tip tapering Probe diameter on. This diameter of the probe body can in a range of, for example, 0.5 to 3 mm and due high bendability take strong bends.

Of Furthermore, it is preferably provided that the probe body via its Length one bendability of at least 90 °. Due to the round cross-section of the probe body this bending ability is not restricted in direction, so that both a strong bending ability and the bending in several, mutually adjoining directions can be done.

The Invention and further advantageous embodiments and further developments The same will be described below with reference to the drawings Examples closer described and explained. The features to be taken from the description and the drawings can individually for applied to one or more in any combination according to the invention become. Show it:

1 a schematic sectional view of a flexible probe and

2 a schematic sectional view of an alternative embodiment of a probe tip of the flexible probe according to 1 ,

In 1 is a schematic sectional view of a flexible probe according to the invention 11 shown. Such a probe 11 is used in intracorporeal shockwave lithotripsy. Such a flexible probe 11 may be introduced directly into a ureter for disintegration of ureteral or bladder stones or into endoscopes for disintegration of, for example, kidney stones or the like. The flexible probe 11 is not limited to these exemplified applications.

The flexible probe 11 includes a probe body 14 , which at one end has a probe foot 16 and at the opposite end a probe tip 17 includes. The design of the probe foot 16 is dependent on a used drive for generating a shock pulse. To drive such a flexible probe 11 can be provided an electromagnetic drive, for example, from the DE 43 13 768 A1 is known, wherein the shock pulse by the impact of a mass body on the probe foot 16 generated and the impact energy in the flexible probe 11 is initiated. An alternative embodiment of the electromagnetic drive is for example a pneumatic drive of a mass body. Alternatively, a hydraulic drive can be provided. In addition, an ultrasonic transducer can also be provided which has a corresponding impact part on the probe foot 16 the flexible probe 11 acting directly or indirectly. Alternatively, a non-contact shock pulse generation vorgese be by a drive, as this example, in the DE 198 41 628 C3 is disclosed.

The probe body 14 is made of a fiber-reinforced plastic. Such fiber reinforced plastics have increased mechanical strength, which enables the stresses required to transfer the high impact energy to be absorbed and transmitted. A first embodiment of the invention provides that carbon fibers or carbon fibers are provided. Such fibers can be incorporated as a single fiber or as a fabric, roving, nonwoven or the like as a precursor in the plastic. The same applies to a second embodiment of the invention, in which glass fibers are provided. As an alternative to the two aforementioned types of fiber, asbestos, boron, metal or synthetic fibers can be provided, which together with the plastic form a composite material. In the case of plastics, thermoplastic elastomers are preferably used.

The probe tip 17 preferably comprises a attachment element 19 which, viewed in cross-section, comprises a U-shaped or cup-shaped geometry. This attachment element 19 is on the probe body 14 put on and glued to it. This is the tip of the probe body 14 completely surrounded and protected. At the same time a quasi one-piece connection can be created. Alternatively, the attachment element 19 be pressed or clamped. The attachment element 19 is preferably formed of metal. Alternative materials suitable for disintegration of body crumbs may also be used.

The probe body 14 is through a shell 21 surround. This shell 21 is designed as a shrink tube and is preferably flush with the attachment element 19 and probe foot 16 at. Preference is given to a paragraph-free transition between an outer periphery of the shell 21 and an outer periphery of the attachment element 19 on the one hand and the outer circumference of the shell 21 and an outer periphery of the probe foot 16 on the other hand.

Alternative to the attachment element 19 may also be provided an insert element, which during the manufacture of the probe body 14 or subsequently at least partially integrated. For example, a cross-sectionally T-shaped insert element may be provided, which is in a blind hole at the tip of the probe body 14 is used to the frontal tip of the probe body 14 cover and protect.

The probe body 14 has a constant diameter. The total diameter of the probe body 14 in the shell 21 For example, it covers a range of 0.5 to 3 mm.

The attachment and attachment of the probe foot 16 can the attachment or arrangement of the attachment element 19 at the probe tip of the probe body 14 correspond.

In 2 is an alternative embodiment of a probe tip 17 to 1 shown. The attachment element 19 has an obliquely ground end face 24 on, whereby the scoring and smashing of the Körperkonkremente is improved. Alternatively, a concave end face may be provided.

The combination of the fiber-reinforced plastic probe body 14 with a metallic probe tip 17 moreover has the advantage that during the shattering of body crumbs in the transmission of the impact energy, the probe tip 17 a wobble about the longitudinal axis of the probe body 14 to a small extent, which causes the probe tip 17 migrates into a hole in the body calculus and strengthens the scoring and shattering effect of the body calculus. In particular, by the unilaterally ground front side 24 this effect is increased.

Such flexible probes 11 can be provided in various lengths of, for example, 300 to 1000 mm. By in the 1 and 2 shown construction of such a flexible probe 11 is a flexible producible flexible probe 11 achieved, which can also be used as disposable items. Such flexible probes 11 can be replaced after a single use.

Claims (10)

Flexible probe intended as a waveguide for an intracorporeal shockwave lithotripter, comprising a probe body ( 14 ) located at the proximal end of the probe ( 11 ) a probe foot ( 16 ) and at the distal end of the probe body ( 14 ) a probe tip ( 17 ) for the disintegration of body concrements by the with the probe tip ( 17 ) mediated shock waves, characterized in that the probe body ( 14 ) is formed of a fiber reinforced plastic. Flexible probe according to claim 1, characterized in that the probe body ( 14 ) is made of carbon or glass fiber reinforced plastic. Flexible probe according to claim 1 or 2, as characterized in that the fibers in the probe body ( 14 ) parallel to the longitudinal axis of the probe body ( 14 ) are aligned. Flexible probe according to one of the preceding claims, characterized in that the probe body ( 14 ) from a shell ( 21 ), in particular a Teflon sheath or a shrink tube is surrounded. Flexible probe according to one of the preceding claims, characterized in that the probe tip ( 17 ) as an insert or attachment element, preferably made of metal, and on the probe body ( 14 ) is provided. Flexible probe according to claim 5, characterized in that the on or attachment element ( 19 ) is designed as a U-shaped or cup-shaped element. Flexible probe according to claim 5 or 6, characterized in that the input or attachment element ( 19 ) on the probe body ( 14 ) is glued, pressed or clamped. Flexible probe according to claim 5 to 7, characterized in that a front side ( 24 ) of the input or attachment element is ground on one side or concave. Flexible probe according to one of the preceding claims, characterized in that the probe body ( 14 ) from the probe foot ( 16 ) to the probe tip ( 17 ) a constant or to the probe tip ( 17 ) has a tapered diameter. Flexible probe according to one of the preceding claims, characterized in that the probe body ( 14 ) comprises a bendability of at least 90 °.