Abstract: A system and method for selecting a patient-specific frequency for ultrasound therapy of a target within the patient are provided. The method includes: (a) for at least one segment of an ultrasound transducer and for each of a plurality of ultrasound frequencies within a test range, sonicating the target and measuring a parameter correlated with an amount of ultrasound energy absorbed in the target; and (b) for each said at least one segment, selecting for subsequent ultrasound therapy, among the frequencies within the test range, a frequency corresponding to a value of the measured parameter that itself corresponds to a maximum amount of ultrasound energy absorbed in the target.

Abstract: Focused-ultrasound systems and methods involve simultaneously determining multiple ultrasound parameters (e.g., applied acoustic power, frequency, phases, position, activation pattern, beam shape, wave shape, etc.) associated with the transducer array for generating optimal treatment effects both at the target region (e.g., causing a sufficient temperature increase for tissue necrosis to occur) and non-target region (e.g., having a clinically insignificant temperature increase to avoid damage to the non-target tissue). A computational model may simulate the treatment effects (e.g., the temperature, peak intensity, focus shape, location of the hot spot, etc.) of these ultrasound parameters on the target and/or non-target regions. Based on the simulation results, the computational model may simultaneously determine the optimal values of the multiple ultrasound parameters—i.e.

Abstract: Various approaches to focusing an ultrasound transducer includes causing the ultrasound transducer to transmit ultrasound waves to the target region; causing the detection system to indirectly measure the focusing properties; and based at least in part on the indirectly measured focusing properties, adjusting a parameter value associated with at least one of the transducer elements so as to achieve a target treatment power at the target region.

Abstract: Various approaches to generating and maintaining an ultrasound focus at a target region include configuring a controller to cause transmission of treatment ultrasound pulses from a transducer having multiple transducer elements; cause the transducer to transmit focusing ultrasound pulses to the target region and generate an acoustic reflector therein; measure reflections of the focusing ultrasound pulses from the acoustic reflector; based at least in part on the measured reflections, adjust a parameter value associated with one or more transducer elements so as to maintain and/or improve the ultrasound focus at the target region.

Abstract: A system for delivering ultrasound energy to an internal anatomical target includes an ultrasound transducer having multiple transducer elements collectively operable as a phased array; multiple driver circuits, each being connected to at least one of the transducer elements; multiple phase circuits; a switch matrix selectably coupling the driver circuits to the phase circuits; and a controller configured for (i) receiving as input a target average intensity level and/or an energy level energy to be applied to the target and/or a temperature level in target, (ii) identifying multiple sets of the transducer elements, each of the sets corresponding to multiple transducer elements for shaping and/or focusing, as a phased array, ultrasound energy at the target across tissue intervening between the target and the ultrasound transducer, and (iii) sequentially operating the transducer-element sets to apply and maintain the target average energy level at the target.

Abstract: Various approaches for heating a target region substantially uniformly include identifying one or more locations of one or more hot spots in the target region and/or surrounding regions of the target region during an ultrasound sonication process; computing a temporal variation to an output parameter of at least one of the transducer elements based at least in part on the identified location(s) of the hot spot(s); and operating the at least one transducer element to achieve the temporal variation of the output parameter so as to minimize the hot spot(s).

Abstract: Various approaches for heating a target region substantially uniformly include identifying one or more locations of one or more hot spots in the target region and/or surrounding regions of the target region during an ultrasound sonication process; computing a temporal variation to an output parameter of at least one of the transducer elements based at least in part on the identified location(s) of the hot spot(s); and operating the at least one transducer element to achieve the temporal variation of the output parameter so as to minimize the hot spot(s).

Abstract: MRI interference with a co-existing ultrasound system may be reduced or avoided by carrying out RF-sensitive operations of the treatment system only when gradient field activity of the MRI system is suppressed.

Abstract: Various approaches to focusing an ultrasound transducer includes causing the ultrasound transducer to transmit ultrasound waves to the target region; causing the detection system to indirectly measure the focusing properties; and based at least in part on the indirectly measured focusing properties, adjusting a parameter value associated with at least one of the transducer elements so as to achieve a target treatment power at the target region.

Abstract: Various approaches to stimulating neural activity in one or more target regions associated with one or more brain diseases or disorders include transmitting the first sequence of ultrasound pulses to the target region(s); measuring a physiological parameter indicative of the neural activity at the target region(s) resulting from the ultrasound pulses; and based at least in part on the measurement, adjusting a parameter value associated with one or more transducer elements so as to achieve a target objective of the neural activity.

Abstract: Treatment of target tissue in a target volume having multiple target regions includes causing an ultrasound transducer to transmit a first series of ultrasound waves having a first frequency to a first one of target regions; and causing the ultrasound transducer to transmit a second series of ultrasound waves having a second frequency, different from the first frequency, to a second one of the target regions, different from the first one of the target regions, based on one or more different anatomical characteristics (such as focal lengths) between the first and second ones of the target regions.

Abstract: Systems and methods for predicting a phase correction of ultrasound waves transmitted from one or more transducer elements and traversing a patient's skull into a target region utilizing data of the patient's skull include predicting a first beam path of the ultrasound waves traversing the skull based at least in part on the target location; computationally determining structural characteristics of the skull along the first beam path based on the acquired imaging data; and predicting a second beam path of the ultrasound waves traversing the skull based at least in part on the determined structural characteristics, thereby accounting for refraction resulting from the skull.

Abstract: Various approaches for reducing microbubble interference with ultrasound waves transmitted from multiple transducer elements and traversing tissue onto a target region include measuring microbubbles in high-throughput areas of ultrasound exposure and reducing the amount of microbubbles using the ultrasound waves.

Abstract: Skull inhomogeneity may be quantified in accordance with the skull density measured in skull images acquired using a conventional imager; the quantified inhomogeneity may then be used to determine whether the patient is suitable for ultrasound treatment and/or determine parameters associated with the ultrasound transducer for optimizing transskull ultrasound treatment.

Abstract: Skull inhomogeneity may be quantified in accordance with the skull density measured in skull images acquired using a conventional imager; the quantified inhomogeneity may then be used to determine whether the patient is suitable for ultrasound treatment and/or determine parameters associated with the ultrasound transducer for optimizing transskull ultrasound treatment.

Abstract: A method for transcostal ultrasound treatment of tissues includes determining rib locations, e.g., based on ultrasound reflections off the ribs or acoustic radiation force signals, and transcostally focusing ultrasound into the tissue while minimizing damage to the ribs.

Abstract: Various approaches to generating and maintaining an ultrasound focus at a target region include configuring a controller to cause transmission of treatment ultrasound pulses from a transducer having multiple transducer elements; cause the transducer to transmit focusing ultrasound pulses to the target region and generate an acoustic reflector therein; measure reflections of the focusing ultrasound pulses from the acoustic reflector; based at least in part on the measured reflections, adjust a parameter value associated with one or more transducer elements so as to maintain and/or improve the ultrasound focus at the target region.

Abstract: Various approaches for detecting cavitation signals from a target region of a patient during a focused ultrasound procedure include an ultrasound transducer; an imaging device for acquiring physiological characteristics of multiple anatomical regions through which the cavitation signals from the target region travel; a controller configured to select one or more of the anatomical regions based at least in part on the physiological characteristics thereof and map the selected anatomical region(s) to one or more corresponding skin regions; and one or more cavitation detection devices attached to the corresponding skin region(s).

Abstract: In ultrasound therapy, the frequency of sonications can be optimized, within a certain frequency range, to maximize the absorption or the acoustic intensity at the target in a manner specific to the patient.

Abstract: A system for delivering ultrasound energy to an internal anatomical target includes an ultrasound transducer having multiple transducer elements collectively operable as a phased array; multiple driver circuits, each being connected to at least one of the transducer elements; multiple phase circuits; a switch matrix selectably coupling the driver circuits to the phase circuits; and a controller configured for (i) receiving as input a target average intensity level and/or an energy level energy to be applied to the target and/or a temperature level in target, (ii) identifying multiple sets of the transducer elements, each of the sets corresponding to multiple transducer elements for shaping and/or focusing, as a phased array, ultrasound energy at the target across tissue intervening between the target and the ultrasound transducer, and (iii) sequentially operating the transducer-element sets to apply and maintain the target average energy level at the target.