A system that breaks calcium in a liquid includes a catheter including first and second electrodes arranged to receive there-across a high electrical voltage at an initial low current. The high electrical voltage causes an electrical arc to form across the electrodes creating a gas bubble within the liquid, a high current to flow through the electrodes, and a mechanical shock wave. A power source provides the electrodes with the high electrical voltage at the initial current and terminates the high electrical voltage in response to the high current flow through the electrodes.

A system that breaks calcium in a liquid includes a catheter including first and second electrodes arranged to receive there-across a high electrical voltage at an initial low current. The high electrical voltage causes an electrical arc to form across the electrodes creating a gas bubble within the liquid, a high current to flow through the electrodes, and a mechanical shock wave. A power source provides the electrodes with the high electrical voltage at the initial current and terminates the high electrical voltage in response to the high current flow through the electrodes.

According to a high-intensity focused ultrasonic apparatus and a control method, an image of a region to be treated is obtained by means of an imaging device, a working assembly and a target coordinate point in the region to be treated are located by means of an optical tracking device, so that a positioning device can clamp the working assembly to quickly and accurately move to a working position corresponding to the target coordinate point, thereby enabling the working assembly to quickly and accurately release a high-intensity focused ultrasonic pulse to the target coordinate point, which improves not only the treatment accuracy but also the treatment efficiency of the high-intensity focused ultrasonic apparatus.

A histotripsy therapy system configured for the treatment of tissue is provided, which may include any number of features. Provided herein are systems and methods that provide efficacious non-invasive and minimally invasive therapeutic, diagnostic and research procedures. In particular, provided herein are optimized systems and methods that provide targeted, efficacious histotripsy in a variety of different regions and under a variety of different conditions without causing undesired tissue damage to intervening/non-target tissues or structures.

A catheter that fits within a blood vessel wall includes electrodes aligned along a longitudinal axis of the catheter that produce unfocused shock waves that propagate radially toward the blood vessel wall for treatment.

A catheter that fits within a blood vessel wall includes electrodes aligned along a longitudinal axis of the catheter that produce unfocused shock waves that propagate radially toward the blood vessel wall for treatment.

Methods and systems for tuning lithotripsy frequency to target size are disclosed. In one embodiment, a lithotripsy system for comminuting a stone in a body includes: a burst wave lithotripsy (BWL) therapy transducer configured to transmit smooth ultrasound waves within a burst of ultrasound waves toward the stone; and a controller configured to determine operating frequency of the ultrasound waves of the therapy transducer. The operating frequency of the ultrasound waves is determined as:

[00001]$f=\mathrm{Const}.\frac{c}{d}$ where: d is a diameter of the stone, f is the frequency of the ultrasound waves, c is a wave speed in the stone, and Const. is a predetermined constant.

A method for mechanically capturing and removing a thrombus from a blood vessel includes contacting the thrombus with an inner catheter. A self-expanding body is advanced toward the thrombus, wherein the self-expanding body has a proximal end fixed to a distal end of an elongate catheter. The self-expanding body is preferably made from nickel-titanium and includes a tapered proximal end portion and an open distal end. The self-expanding body preferably has a mesh structure. The self-expanding body is allowed to self-expand in the blood vessel. At least a portion of the thrombus is captured by the self-expanding body and the captured thrombus is then retrieved into a lumen of an aspiration catheter. Negative pressure is applied through the lumen of the aspiration catheter during retrieval of the captured thrombus. A thrombolytic drug may be delivered into the blood vessel before capturing and removing the thrombus.

A method for mechanically capturing and removing a thrombus from a blood vessel includes contacting the thrombus with an inner catheter. A self-expanding body is advanced toward the thrombus, wherein the self-expanding body has a proximal end fixed to a distal end of an elongate catheter. The self-expanding body is preferably made from nickel-titanium and includes a tapered proximal end portion and an open distal end. The self-expanding body preferably has a mesh structure. The self-expanding body is allowed to self-expand in the blood vessel. At least a portion of the thrombus is captured by the self-expanding body and the captured thrombus is then retrieved into a lumen of an aspiration catheter. Negative pressure is applied through the lumen of the aspiration catheter during retrieval of the captured thrombus. A thrombolytic drug may be delivered into the blood vessel before capturing and removing the thrombus.

Human and animal biofilms and pathogens are treated with extracorporeal acoustic pressure shock waves at a location of prosthesis or implant in a body.