A lithotripsy device can comprise a handpiece, a lithotripsy probe extending from the handpiece, an energization source configured to deliver an energy to a distal end of the lithotripsy probe, a suction passage extending from the distal end of the probe and through the handpiece, and a capture device comprising a container comprising a storage space, an entry port configured to couple to the handpiece at the suction passage, and an exit port, and a capture element connected to the container and configured to facilitate capture of stone fragments within the storage space. A method can comprise fragmenting stones with a lithotripsy device, drawing a vacuum through the lithotripsy device to pull stone fragments and waste fluid therethrough, pulling the vacuum through a stone capture device connected to the lithotripsy device, depositing stone fragments within the stone capture device using a capture element, and drawing the vacuum through the device.

A lithotripter is provided for fragmenting a stone inside a patient's body. In one form, the lithotripter includes a motor having at least two modes of operation and is configured to produce first and second waveforms. A wave guide shaft is configured to transmit the first and second waveforms to the stone. In one form, at least one of the first and second waveforms is provided to the stone at a frequency that is about equal to a natural frequency of the stone. In a variation, the lithotripter may include an ultrasonic driver configured to produce an ultrasonic frequency waveform and a sonic driver configured to produce a sonic frequency waveform. The sonic driver is mechanically coupled to the ultrasonic driver. The ultrasonic driver and the sonic driver may be disposed within a driver housing. In another variation, the lithotripter may include a brushless DC motor.

The invention relates to a holding device for a lithotripsy device for fragmenting calculi, the holding device comprising a housing for accommodating assemblies and/or components, and a sonotrode being connectable to the distal end of the housing, arranged within the housing there being an acceleration tube with a longitudinal center axis, a cavity, and with a movable projectile within the cavity for shock excitation of the sonotrode, a proximal-side abutment element arranged at the proximal end, and a distal-side abutment element arranged at the distal end of the acceleration tube, and the holding device being assignable a force generation apparatus for generating a force for moving the projectile back and/or forth, and a vibration excitation apparatus for exciting vibrations of the sonotrode and a vibration damping apparatus being arranged in the housing, wherein the vibration damping apparatus comprises at least one mass and at least two spring elements with two ends each, the at least two spring elements contacting the mass with their respective one end and at least one spring element, with its second end, contacting an inner surface of the housing. The invention also relates to a lithotripsy device.

The invention relates to a holding device for a lithotripsy device for fragmenting calculi, the holding device comprising a housing with a distal end and a proximal end and a sonotrode being connectable to the distal end, arranged within the housing there being an acceleration tube with a longitudinal center axis, a cavity, a proximal end, and a distal end, and with a movable projectile within the cavity for shock excitation of the sonotrode, a proximal-side abutment element arranged at the proximal end, and a distal-side abutment element arranged at the distal end of the acceleration tube, and the holding device being assignable a force generation apparatus for generating a force for moving the projectile back and/or forth between the proximal-side abutment element and the distal-side abutment element, and a vibration excitation apparatus for exciting vibrations of the sonotrode being arranged in the housing, wherein the holding device comprises a vibration compensation apparatus with at least one mass and at least one spring element such that the vibration compensation apparatus makes it possible to decouple the acceleration tube from the excitation of vibrations by means of the vibration excitation apparatus. The invention also relates to a lithotripsy device for fragmenting calculi.

The present system is directed in various embodiments to rotational atherectomy systems and methods generally. More specifically, a method for methodically softening and disrupting calcification within the wall of a biological conduit or lumen. This result is achieved by use of at least one eccentric head that, during high-speed rotation within the exemplary lumen, produces a combination of a low-frequency orbital motion comprising a force that is exerted against the lumen wall, with concomitant deflection of same, and a high-frequency pulsatile frequency, also with concomitant exertion of force against the lumen wall and deflection of same. These force-driven deflections produce shockwaves within the layers of the exemplary artery's wall layers, resulting in systematic disruptions of any calcification within the intimal and/or medial layers of the subject artery. In addition, any calcification within the occlusion is also softened and disrupted, increasing compliance of the vessel and/or lesion.

A surgical instrument including a housing, a transducer assembly, a motor, a hollow sheath, and a blade is disclosed. The transducer assembly may be rotatably supported within the housing and may be configured to selectively generate an ultrasonic motion. The motor may be coupled to the transducer assembly and may be configured to selectively apply rotational motion to the transducer assembly. The hollow sheath may be coupled to the housing and may define a distal cavity. The blade may be coupled to the transducer assembly and may be rotatably supported within the hollow sheath. A distal end of the blade may include a tissue-cutter that may be rotatably supported in the distal cavity. The distal cavity may comprise a friction reducing material. A portion of the tissue-cutter may be arranged to apply the ultrasonic motion to tissue.

An apparatus for performing an endovascular procedure using ultrasonic energy includes a catheter comprising a wave guide including an expandable portion for delivering the ultrasonic energy from a source for performing the endovascular procedure. The expandable portion may comprise a plurality of wires formed of a shape memory material. A retractable sheath may be provided for receiving the plurality of wires in the non-deployed position and for being withdrawn to expose the wires in the deployed position. A linear actuator for moving the plurality of wires in a longitudinal direction or a rotary actuator for rotating the plurality of wires may also be provided.

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 acoustic lithotripsy system can deliver acoustic energy to a target located within a patient. The system may include an acoustic transducer, the acoustic transducer including a first vibrator and a second vibrator. A system may include an impact member, coupled to the acoustic transducer, the impact member operable at a lower frequency than each of the first vibrator and the second vibrator. The system may further include controller circuitry, coupled to the acoustic transducer and the impact member, the controller circuitry including: an acoustic actuation control output, configured to selectively provide to at least one of the first vibrator or the second vibrator, an actuation control signal to control ablation of the target by the selected at least one of the first vibrator or the second vibrator. The first vibrator and/or or the second vibrator may be selected to operate with or without the impact member.

This disclosure disclosed an ultrasonic needle and apparatus used for removal of the vitreous body and other tissues. An ultrasonic vitrectomy needle, comprising: a connector, a connected inner needle, and an outer sheath. The length of the outer sheath at the distal end is slightly longer than that of the inner needle; the sheath distal end is of blind with smooth surface, but there is an open cut at the side of the distal end used for aspirating the vitreous body. The benefits of this disclosure: due to the difficulty if not impossible in the prior arts making a slim long center bore needle for ultrasonic surgical system, this disclosure clears the way to make the ultrasonic vitrectomy a practical reality; the ultrasonic vibration inherent advantages of the quietness, minuscule displacement, liquid repulsion and viscosity reduction improve safety of the surgery; the possibility of integrating ultrasonic vitrectomy and ultrasonic phaco emulsification procedures simplifies the complexity from prior arts, thus brings ease to the ophthalmic surgeries and reduces the cost.