Method and apparatus for producing shock waves for medical applications

BACKGROUND OF THE INVENTION

The invention relates to a method and an apparatus for producing shock waves for medical applications.

For various medical indications, shock waves are used that are produced in a fluid volume and focused on the areas of the patient to be treated. Various methods and apparatuses are known for producing the shock waves.

In one embodiment, the shock waves are produced by electromagnetic means. An electrical impulse in a coil is used to a deflect a diaphragm by producing a pressure pulse in the adjacent fluid volume. If the coil is a flat coil, this produces an even pressure wave, which is focused by means of acoustic lenses located in the fluid volume. If the coil and the membrane are curved, then the pressure wave that is produced is focused by the curved diaphragm surface. If a cylindrical coil is used, the cylindrically expanding pressure wave is reflected and focused by a correspondingly shaped rotation surface.

A further known method for producing the pressure waves is to use piezoelectric elements. The piezoelectric elements can be located on a rotation surface, so that pressure waves produced by these elements are focused.

Finally, a method is known to produce the shock waves by electro hydraulic means. In this process, an electric spark discharge is ignited in the fluid volume, which produces a plasma bubble. The shock wave, which expands spherically, is focused by reflecting on suitable rotation surfaces.

In all of these known methods, the shock wave is triggered by an electrical impulse. The required electrical impulses generally are characterized by short rise times and high energy, so that electromagnetic shielding problems arise, which can have adverse effects, especially in the presence of further electrical devices or patient-related apparatuses e.g. pacemakers. Some of the known devices also display high electrical power dissipation, which necessitates expensive cooling systems. Consequently, there exist an unfulfilled need for a method and an apparatus for producing shock waves for medical application, which ensures better degree of efficiency and less electromagnetic shielding problems.

BRIEF SUMMARY OF THE INVENTION

The underlying idea of the invention consists in producing a pressure pulse by mechanical means in a work space filled with fluid and transferring this pressure pulse to the fluid, in order to produce the shock wave in this fluid. To produce the pressure pulse in the work space, a fluid can be injected under high pressure into the work space, as for example in the process of injection used in diesel engines. Another object of the invention is to allow a piston moved by mechanical means to act upon the volume of the work space in order to increase the pressure in the work space by pulses.

The work space and the fluid volume in which the pressure wave is produced are separated by a partition. Preferably, a closed partition is used that can be moved, e.g. on bearings, or made of a flexible material. The pressure increase in the work space causes a displacement in the partition, which in turn produces the shock wave in the adjacent fluid volume. It is also possible to use a partition with openings. The pressure increase by pulses in the work space causes the fluid to be pressed from the work space through the openings of the partition into the fluid. The fluid, which penetrates the fluid volume under pressure, produces pressure waves in the fluid, which build up the desired shock waves.

The form of the partition enables different ways of producing pressure waves in the fluid volume, which said pressure waves form shock waves in the fluid and are focused in a suitable manner. In principal, the same geometrical arrangements can be used for this purpose as the state of the art used for shock waves produced by electrical means.

BRIEF DESCRIPTION OF THE DRAWING

These and other features, aspects and advantages of the present invention will become better understood with reference to the following description, appended claims, and accompanying drawing, where:

FIG. 1 depicts a schematic representation of an apparatus designed in accordance with the invention.

FIG. 2 depicts a schematic representation of a design in which, the partition is designed as a focusing rotation surface

FIG. 3 depicts is a schematic representation of a design, in which the work space has a cylindrical shape and is located in the fluid volume

LIST OF REFERENCE NUMBERS

• • 10 work space
  • 12 arrow for pressure increase
  • 14 partition
  • 16 fluid volume
  • 18 arrows for pressure transfer
  • 20 acoustic lens
  • 22 focus
  • 24 reflector

In the drawing, the principle of producing the shock waves is depicted only schematically. Equivalent parts are indicated by the same reference numbers.

DETAILED DESCRIPTION OF THE INVENTION

The invention summarized above and defined by the enumerated claims may be better understood by referring to the following detailed description, which should be read in conjunction with the accompanying drawing. This detailed description of a particular preferred embodiment, set out below to enable one to practice the invention, is not intended to limit the enumerated claims, but to serve as a particular example thereof.

FIG. 1 illustrates a closed work space 10, which is filled with a fluid. The fluid can be a gas or a liquid. As symbolized by an arrow 12, the pressure in the work space 10 is increased by pulses by mechanical means. For this purpose, a liquid can be injected under high pressure into the work space 10, as for example in the injection pumps of a diesel engine. Alternatively, the volume of the work space 10 can be acted upon by a piston that is moved mechanically, in order to increase the pressure in the work space 10.

The work space 10 is separated by a partition 14 from a fluid volume 16, in which the shock waves are produced. In the sample embodiment of FIG. 1, the partition 14 is designed as a flat partition. The partition 14 can be a more or less rigid plate, e.g. made of metal or plastic, which is mounted flexibly, thus making it moveable. Likewise, the partition 14 can be made of a flexible material, so that it can bend and move.

The pressure increase by pulses in the work space 10 causes a deflection of the partition 14, as symbolized by the arrows 18. The deflection of the partition 14 produces an even pressure wave in the fluid volume 16, which said pressure wave increases to a shock wave during the expansion in the fluid volume 16. The shock wave is focused by means of an acoustic lens 20, as indicated by the broken lines 22.

The partition 14 can alternatively be designed as a rigid wall that is interrupted by openings uniformly distributed on a grid. In this case, the pressure increase by pulses in the work space 10 causes the fluid, preferably a liquid, to be pressed under pressure through the openings of the partition 14 into the fluid volume 16. The fluid streams penetrating the individual openings produce spherical pressure waves in the fluid volume 16, which combine to an even pressure wave due to the uniform distribution of the openings in the partition 14.

FIG. 2 shows a design in which, the partition 14 separates the work space 10 from the fluid volume 16, designed as a focusing rotation surface, e.g. as a rotation parabola or rotation ellipsoid, which partially encloses the fluid volume 16. Here also the partition 14 can be flexible, flexibly mounted or provided with openings in a grid. If the pressure in the work space 10 is increased by pulses, as indicated by the arrow 12, then the partition 14 is deflected or fluid streams penetrate the openings of the partition 14 into the fluid volume 16. This produces pressure waves in the fluid volume 16, which said pressure waves produce a focused shock wave due to the focusing surface form of the partition 14.

FIG. 3 shows a design, in which the work space 10 has a cylindrical shape and is located in the fluid volume 16. The partition 14 forms the surface area of the cylindrical work space 10. The fluid volume 16 is partially enclosed by a reflector 24, which is designed as a focusing rotation surface.

If the pressure in the work space 10 is increased by pulses, then the flexible partition 14 is deflected radially, producing a cylindrically expanding pressure wave, which is focused by means of the reflector 24. Here also the cylinder surface area of the partition 14 can alternatively be rigid and provided with openings, so that fluid streams can be pressed through the surface area of the partition 14 into the fluid volume in order to produce the cylindrical pressure wave.

The work space 10 in this embodiment can be designed as a double-walled hollow cylinder, whereby the outer surface area forms the partition 14 and a rigid inner surface area forms a cylindrical interior area in which, for example, the head of a diagnostic device can be inserted or in which irradiation by X-rays or ultrasonic waves is possible.