In a wave focusing device and a wave emitting device having the wave focusing device, the wave focusing device has a plurality of filters and focuses a wave by a phase overlap. The plurality of filters includes a first filter formed on a substrate, a second filter formed on the substrate and overlapping with the first filter in a first area, and a third filter formed on the substrate and overlapping with the second filter in a second area. A size of the first area is substantially same as that of the second area. A first portion of the second filter in the first area is inverted to a second portion of the second filter in the second area, with respect to a first axis. A wave passing through the wave focusing device is focused at a center of each of the first, second and third filters.

An ultrasonic treatment apparatus includes a movement unit moving in accordance with at least one of an acting state of a load to a treatment section from a jaw and an opening angle of the jaw relative to the treatment section, a movement detector detecting a moving state of the movement unit, and a peak detecting section detecting a target peak of an ultrasonic impedance value. The ultrasonic treatment apparatus includes a control section controlling the peak detecting section to a detection disallowed state where a detection of the target peak is not executed when the movement unit is not placed within a prescribed range based on a detection result in the movement detector.

An ultrasonic treatment apparatus includes a movement unit moving in accordance with at least one of an acting state of a load to a treatment section from a jaw and an opening angle of the jaw relative to the treatment section, a movement detector detecting a moving state of the movement unit, and a peak detecting section detecting a target peak of an ultrasonic impedance value. The ultrasonic treatment apparatus includes a control section controlling the peak detecting section to a detection disallowed state where a detection of the target peak is not executed when the movement unit is not placed within a prescribed range based on a detection result in the movement detector.

Embodiments disclosed herein relate to a garment system including a flexible compression garment, at least one sensor, and at least one therapeutic stimulation delivery device operable responsive to sensing feedback from the at least one sensor, effective to provide therapeutic radiation to a body part of a subject. Embodiments disclosed herein also relate to methods of using such garment systems.

A stereotactic device wearable by a patient for low-intensity focused-ultrasound neuromodulation has a support frame shaped to be fitted around a head of the patient, a first movable component having an arched shape and having a first end and a second end engaged with the support frame at respective first and second coupling points. A second movable component has an engagement portion with the first movable component adapted to allow the second movable component to move integrally with the first movable component and to slide along the first movable component to take a plurality of positions between a first position in which the second movable component is proximal to the first end and a second position in which the second movable component is proximal to the second end. A low-intensity focused-ultrasound neuromodulation module housed in a support portion of the second movable component has a low-intensity focused-ultrasound sonication probe.

A histotripsy therapy system configured for the treatment of brain tissue is provided, which may include any number of features. In one embodiment, the system includes an ultrasound therapy transducer, a drainage catheter, and a plurality of piezoelectric sensors disposed in the drainage catheter. The ultrasound therapy is configured to transmit ultrasound pulses into the brain to generate cavitation that liquefies a target tissue in the brain. The drainage catheter is configured to detect the ultrasound pulses. An aberration correction algorithm can be executed by the system based on the ultrasound pulses measured by the drainage catheter to automatically correct for an aberration effect caused by the ultrasound pulses passing through a skullcap of the patient.

Embodiments of the invention provide a thermal ablation system. The thermal ablation comprises a thermal ablation apparatus configured to perform thermal ablation on a targeted tissue according to plan data of a treatment during a therapy mode of the thermal ablation system, a MR apparatus configured to perform a T2* weighted MR imaging for the targeted tissue to assess a therapeutic response of the thermal ablation during an assessment mode of the thermal ablation system, a control apparatus configured to switch the thermal ablation system between the therapy mode and the assessment mode. The thermal ablation apparatus is activated to perform the thermal ablation in the therapy mode, and the thermal ablation apparatus is deactivated to terminate the thermal ablation and the MR apparatus is activated to perform the T2* weighted MR imaging in the assessment mode.

A method for delivering ultrasound therapy using open-loop controls comprises inserting a distal tip of a therapeutic ultrasound applicator into a patient's urethra, the distal tip including an ultrasound transducer; acquiring ultrasound images of the patient's urethra and prostate with an ultrasound imaging probe; aligning the distal tip of the therapeutic ultrasound applicator with the patient's prostate using the ultrasound images; delivering therapeutic ultrasound energy to the patient's prostate, with the ultrasound transducer, according to a treatment plan, the treatment plan including a predetermined limited angular range for the therapeutic ultrasound energy that avoids the patient's rectum and neurovascular bundles, wherein the therapeutic ultrasound is delivered without temperature feedback data.

Acoustic generating systems are provided. The acoustic generating systems include a handpiece that provides for adjustment of the penetration depth. In preferred embodiments, the adjustment of the penetration depth is provided by adjustment between a fixed part of the handpiece and an adjustable part of the handpiece. In even more preferred embodiments, adjustment of the penetration depth is provided through a plurality of interchangeable adjustable parts each configured to provide for a different penetration depth when coupled to the fixed part. Preferred embodiments further include an optical system that provides imaging of the treatment surface and is capable of adjusting to the change in penetration depth to continue to provide imaging of the treatment surface. In some embodiments, the interface between the fixed part and adjustable part of the handpiece passes through a chamber that holds a liquid acoustic coupling medium.

A system and method for MR imaging is disclosed. The method causes an RF coil assembly and plurality of gradient coils to apply a fast spin echo (FSE) pulse sequence comprising a preparation segment and a plurality of refocusing segments. The FSE pulse sequence generates a pair of echoes is generated in each of the plurality of refocusing segments that comprises a first echo generated by magnetization pathways having an even number of phase inversions and a second echo generated by magnetization pathways having an even number of phase inversions. MR signals are acquired from the first echo and the second echo and an image of at least a portion of a subject of interest is reconstructed from the acquired MR signals.