Systems and methods for cavitation-guided opening of a targeted region of tissue within a primate skull are provided. In one example, a method includes delivering one or more microbubbles to proximate the targeted region, applying an ultrasound beam, using a transducer, through the skull of the primate to the targeted region to open the tissue, transcranially acquiring acoustic emissions produced from an interaction between the one or more microbubbles and the tissue, and determining a cavitation spectrum from the acquired acoustic emissions.

An ultrasound therapy probe includes a housing; a therapy transducer disposed in the housing to produce acoustic waves for therapy; a lens coupled to the housing to focus the acoustic waves from the therapy transducer for delivery to a patient; and a phase change material disposed within the housing and in thermal communication with the therapy transducer. The phase change material has a phase transition temperature or temperature range within a range of 25 C. to 40 C. at which the phase change material changes from a first phase to a second phase, where the first and second phases are not gaseous phases. The phase change material forms a thermal reservoir for managing thermal energy arising from the ultrasound therapy probe.

An electromagnetic shockwave transducer includes a double-faced coil of wire wound around an insulator. The coil has a first coil face on one side of the insulator and a second coil face on an opposite side of the insulator. Coil ends of the coil are electrically coupled to a current source, which produces a current pulse in the coil so as to produce a force between the coil faces.

Methods for performing non-invasive thrombolysis with ultrasound using, in some embodiments, one or more ultrasound transducers to focus or place a high intensity ultrasound beam onto a blood clot (thrombus) or other vascular inclusion or occlusion (e.g., clot in the dialysis graft, deep vein thrombosis, superficial vein thrombosis, arterial embolus, bypass graft thrombosis or embolization, pulmonary embolus) which would be ablated (eroded, mechanically fractionated, liquefied, or dissolved) by ultrasound energy. The process can employ one or more mechanisms, such as of cavitational, sonochemical, mechanical fractionation, or thermal processes depending on the acoustic parameters selected. This general process, including the examples of application set forth herein, is henceforth referred to as Thrombolysis.

Systems and methods for cavitation-guided opening of a targeted region of tissue within a primate skull are provided. In one example, a method includes delivering one or more microbubbles to proximate the targeted region, applying an ultrasound beam, using a transducer, through the skull of the primate to the targeted region to open the tissue, transcranially acquiring acoustic emissions produced from an interaction between the one or more microbubbles and the tissue, and determining a cavitation spectrum from the acquired acoustic emissions.

A blood clot obstruction of a coronary artery causing myocardial infarction is treated by sonothrombolysis by transmitted therapeutic ultrasound to the coronary artery in synchronism with the heart cycle. Therapeutic transmission may be at the same phase of consecutive or non-consecutive heart cycles. To allow for microbubble replenishment, two or more different patterns of therapeutic energy may be used. A coronary artery and its downstream microvasculature may be treated at the same time by using different heart cycle timing or different beam patterns or both for the two therapeutic sites.

Methods for performing non-invasive thrombolysis with ultrasound using, in some embodiments, one or more ultrasound transducers to focus or place a high intensity ultrasound beam onto a blood clot (thrombus) or other vascular inclusion or occlusion (e.g., clot in the dialysis graft, deep vein thrombosis, superficial vein thrombosis, arterial embolus, bypass graft thrombosis or embolization, pulmonary embolus) which would be ablated (eroded, mechanically fractionated, liquefied, or dissolved) by ultrasound energy. The process can employ one or more mechanisms, such as of cavitational, sonochemical, mechanical fractionation, or thermal processes depending on the acoustic parameters selected. This general process, including the examples of application set forth herein, is henceforth referred to as Thrombolysis.

An ultrasound imaging and therapy device includes an array of concentric annular ultrasound transducers, and an ultrasound imaging device situated inside an innermost transducer of the plurality of concentric annular ultrasound transducers, wherein it further comprises a mechanical linkage allowing a tilting movement of the array of concentric annular ultrasound transducers with respect to the ultrasound imaging device and in that the ultrasound imaging device protrudes in an axial direction from the array of concentric annular ultrasound transducers; whereby the ultrasound imaging device can be kept stationary and in direct or indirect contact with a patient's skin while the array of concentric annular ultrasound transducers is tilted so as to move a focal point of ultrasound waves generated by the concentric annular ultrasound transducers within an imaging region of the ultrasound imaging device.

Methods for performing non-invasive thrombolysis with ultrasound using, in some embodiments, one or more ultrasound transducers to focus or place a high intensity ultrasound beam onto a blood clot (thrombus) or other vascular inclusion or occlusion (e.g., clot in the dialysis graft, deep vein thrombosis, superficial vein thrombosis, arterial embolus, bypass graft thrombosis or embolization, pulmonary embolus) which would be ablated (eroded, mechanically fractionated, liquefied, or dissolved) by ultrasound energy. The process can employ one or more mechanisms, such as of cavitational, sonochemical, mechanical fractionation, or thermal processes depending on the acoustic parameters selected. This general process, including the examples of application set forth herein, is henceforth referred to as Thrombolysis.

Methods for performing non-invasive thrombolysis with ultrasound using, in some embodiments, one or more ultrasound transducers to focus or place a high intensity ultrasound beam onto a blood clot (thrombus) or other vascular inclusion or occlusion (e.g., clot in the dialysis graft, deep vein thrombosis, superficial vein thrombosis, arterial embolus, bypass graft thrombosis or embolization, pulmonary embolus) which would be ablated (eroded, mechanically fractionated, liquefied, or dissolved) by ultrasound energy. The process can employ one or more mechanisms, such as of cavitational, sonochemical, mechanical fractionation, or thermal processes depending on the acoustic parameters selected. This general process, including the examples of application set forth herein, is henceforth referred to as Thrombolysis.