The present invention relates to a reflector for an acoustic shock or pressure wave head, wherein the reflector comprises an acoustically reflective surface formed by a body of rotation, said body of rotation being formed by rotation of an elliptical segment about a rotation axis which extends through a focal point of the ellipse and encloses an angle α between 0.1° and 30° with the main axis of the ellipse.

A method is disclosed for removing a vascular occlusion, such as a clot, from a blood vessel. A tubular sheath is inserted into the vessel and a self-expanding Nitinol mesh filter is deployed from a distal end of the tubular sheath at a location proximal to a clot. An inner catheter is advanced through the tubular sheath and through the mesh filter for contacting the clot. An expandable agitation element is provided along a distal end portion of the inner catheter for cutting or chopping the clot, thereby facilitating removal of the clot and improving blood flow through the vessel. Resulting clot particles are captured by the mesh filter. Negative pressure may be applied along a proximal end portion of the sheath for aspirating remaining particles. Certain embodiments of the method are well-suited for treating deep vein thrombosis and do not require the use of thrombolytic drugs.

A method is disclosed for removing a vascular occlusion, such as a clot, from a blood vessel. A tubular sheath is inserted into the vessel and a self-expanding Nitinol mesh filter is deployed from a distal end of the tubular sheath at a location proximal to a clot. An inner catheter is advanced through the tubular sheath and through the mesh filter for contacting the clot. An expandable agitation element is provided along a distal end portion of the inner catheter for cutting or chopping the clot, thereby facilitating removal of the clot and improving blood flow through the vessel. Resulting clot particles are captured by the mesh filter. Negative pressure may be applied along a proximal end portion of the sheath for aspirating remaining particles. Certain embodiments of the method are well-suited for treating deep vein thrombosis and do not require the use of thrombolytic drugs.

This invention relates generally to an ultrasound device configured to generate a frustum-shaped beam capable of fragmenting a plurality of biomineralizations located within a patient's body in combination with synthetic cavitation nuclei. The ultrasound device includes a transducer assembly comprising a plurality of ultrasound transducer elements, and a multi-channel amplifier circuit. Each channel of the multi-channel amplifier circuit is configured to actuate a distinct subset of the plurality of transducer elements. The multi-channel amplifier circuit is configured to operate in each of a plurality of states, each state of comprising a set of frequencies at which each channel of the multi-channel amplifier circuit is configured to actuate the distinct subset of transducer elements. The multi-channel amplifier circuit is further configured to switch between the plurality of states, thereby causing the plurality of ultrasound transducer elements to produce a frustum-shaped beam.

The present invention relates to a device, system and a method for high pressure shockwave treatment of biological tissue having a large treatment zone and in particular to such a device, system and method in which a large biological treatment area in treated in a non-drug, non-surgical treatment protocol utilizing ballistic shockwave generating device.

The present invention relates to a device, system and a method for high pressure shockwave treatment of biological tissue having a large treatment zone and in particular to such a device, system and method in which a large biological treatment area in treated in a non-drug, non-surgical treatment protocol utilizing ballistic shockwave generating device.

A system and method for controlling acoustic energy deposition in various media or objects are disclosed. The system and method can generate an acousto-mechanical or acousto-elastic effect in the various media or objects. The acousto-mechanical or acousto-elastic effect can induce a fragmentation of the media or objects.

A system and method for controlling acoustic energy deposition in various media or objects are disclosed. The system and method can generate an acousto-mechanical or acousto-elastic effect in the various media or objects. The acousto-mechanical or acousto-elastic effect can induce a fragmentation of the media or objects.

An apparatus for generating focused shockwaves and ultrasound waves comprises a concave reflector holding a cylindrical coil at its center axis. A power generator comprising a combined shockwave and ultrasound generator device is connected to the coil for alternatingly providing an ultrasound signal and a shockwave signal to the coil such that the coil alternatingly generates ultrasound waves and shockwaves.

An apparatus for generating focused shockwaves and ultrasound waves comprises a concave reflector holding a cylindrical coil at its center axis. A power generator comprising a combined shockwave and ultrasound generator device is connected to the coil for alternatingly providing an ultrasound signal and a shockwave signal to the coil such that the coil alternatingly generates ultrasound waves and shockwaves.