Devices and methods for treating human cranial hair loss using extracorporeal acoustic shock waves are disclosed. The shock wave device optionally includes a proximal surface, a plurality of shock wave generators disposed on the surface, and a coupling assembly configured to transmit shock waves to a user's scalp.

Methods and devices for treating erectile dysfunction are disclosed. Methods are aimed at reducing blood outflow from penile tissue by delivering energy to specific penile tissue that controls blood outflow from the penile tissue and causing remodeling of the specific penile tissue. Devices may be configured to generate RF energy and to apply the generated RF energy to a penis to thereby elevate a temperature of internal penile tissue above a predetermined temperature value while maintaining a penile surface below a predetermined temperature threshold. The predetermined temperature value may be set to initiate synthesis and/or a regeneration of collagen fibers in a collagen-rich penile connective tissue and/or to increase oxygenation of endothelial cells, initiate angiogenesis and neovascularization in a vascular penile tissue. Additionally, electrical penile stimulation is disclosed, possibly applicable in conjuncture with the erectile dysfunction treatment.

An apparatus includes a balloon adapted to be placed adjacent a calcified region of a body. The balloon is inflatable with a liquid. The apparatus further includes a shock wave generator within the balloon that produces shock waves that propagate through the liquid for impinging upon the calcified region adjacent the balloon. The shock wave generator includes a plurality of shock wave sources distributed within the balloon.

A method of operating an ultrasound catheter includes providing an elongate catheter body having at least a first lumen; providing a housing coupled with a proximal end of the elongate catheter body, the housing having an inner cavity; providing a fluid inlet in fluid communication with at least one of the first lumen and the inner cavity; providing a sonic connector coupled to a proximal portion of an ultrasound transmission member; providing vibration absorption O-rings disposed in the inner cavity around at least a portion of the ultrasound transmission member, the plurality of vibration absorption O-rings being located distal to the sonic connector; and delivering fluid to the fluid inlet to supply the fluid at least distally into the first lumen of the elongate catheter body to dissipate heat received from the ultrasound transmission member in the first lumen of the elongate catheter body.

The invention relates to an apparatus for treating a human or animal body by mechanical strokes, wherein an applicator for being placed on the patient's body surface has a basically oblique front area portion in an angle between 30 and 60 to the stroke direction.

The present invention relates to a method for treating the kidney with extracorporeal shockwaves in a noninvasive manner and in particular, to such a method for the treatment of the nephrons about the glomerulus.

Device for shave-free trans-cranial focused ultrasound (FUS) treatment and method for using same, the device including a scalp cover having a first inlet configured to allow supply of a gas into the scalp cover, and an outlet configured to allow outflow of ambient air contained within the scalp cover when the gas is being supplied, such that the ambient air contained within the scalp cover is replaced by the supplied gas.

Devices, systems, kits and methods are provided, that simplify focused ultrasound treatment. Devices comprise a supporting structure and a focused ultrasound (FUS) transducer having a central axis that is affixed to the supporting structure. Devices may further comprise an imaging ultrasound transducer and/or an x-ray aim, that may be attached to the supporting structure along the central axis of the FUS transducer. The FUS transducer is connected to a controller configured to control application of focused ultrasound by the transducer and may be associated with an imaging unit for imaging the treatment region using ultrasound and/or x-ray image data. The devices are hand held and easy to manipulate and aim correctly, utilizing coupling member(s) as well as feedback from the concurrently imaged treatment region.

A method for cooling a transducer of a probe for generating ultrasonic waves, the transducer exhibiting, at the front, a face (4) for emitting ultrasonic waves, and at the rear, a rear face (5), at least the emitting face partially delimiting a cooling chamber (11) wherein a cooling fluid circulates between at least an inlet (15) and at least an outlet (16), the inlet (15) being located at the periphery of the emitting face (4) whereas the outlet (16) is located in the central part of said emitting face. The method includes creating between the inlet (15) and the outlet (16), a circulation of cooling fluid according to a swirling inside the cooling chamber around the axis of acoustic propagation (A).

Disclosed herein is a non-invasive treatment system using intermedium, and an exemplary treatment system is configured to output high-intensity focused ultrasound to remove bone tissue, inject an acoustically-transparent medium into a part where the bone tissue is removed to generate an intermedium, and output therapeutic ultrasound that passes through the intermedium. Accordingly, the bone tissue is removed in a non-invasive way using high-intensity focused ultrasound, and the intermedium is generated at the bone tissue removed site, to increase the penetration of therapeutic ultrasound or generate ultrasound itself, thereby improving an ultrasound treatment effect while minimizing the side effect (for example, infection of dura mater) of invasive surgery methods.