A method for spatial resolution enhanced imaging is provided. The method includes determining a target region of a subject being imaged; estimating an achievable spatial resolution; selecting an increased spatial resolution that is greater than a predetermined spatial resolution and equal to or less than the achievable spatial resolution; and acquiring image data of the target region with the increased spatial resolution. A method for enhancing the contrast between the region of interest and other tissue region in the image data acquired with the increased spatial resolution and other tissue region in image data acquired with the predetermined spatial resolution due to the intrinsic partial volume effect is also provided.

Markers for use in bodily tissue take a variety of forms, and may include a plurality of ultrasound reflective elements, for example hollow shells filled with air, and a hydrogel that binds the ultrasound reflective elements. The hydrogel may be natural or artificial and may be cross-linked. An ultrasound system advantageously injects variance in a drive signal, that varies a frequency or phase of an ultrasound interrogation signal from a nominal frequency or nominal phase. The amount of variation is preferable one to six orders of magnitude less than the nominal frequency or phase. The ultrasound system can present or detect a twinkling artifact at least in a Doppler mode of operation, resulting from interaction of the varying interrogation signal with the ultrasound reflective elements.

Ultrasound-based estimation of disease activity, such as for NAS or other activity index for NAFLD for liver disease, is provided. Ultrasound measures acoustic scatter and shear wave propagation parameters, such as measuring acoustic backscatter coefficient, shear wave velocity, and shear wave damping ratio. A score for the disease activity is determined from these scatter and shear wave propagation parameters. The physician may be assisted by relatively inexpensive and rapid ultrasound as compared to biopsy or MRI based scoring in scoring activity of a disease, such as NAFLD. Ultrasound imaging is more readily available and less expensive and MRI, and is non-invasive.

An embodiment of the invention provides a system for automatically deriving a parameter of a human heart from ultrasound results. A first neural network is arranged to receive a plurality of echocardiographic images and to classify the images into one of at least a two-chamber view and a four-chamber view. A second neural network is arranged to receive echocardiographic images comprising a two- or four-chamber view and to identify the endocardial border of the left ventricle (LV) for each view. End-systole and end-diastole images are then identified and a parameter such as LV volume, ejection fraction, global longitudinal strain and regional longitudinal strain is calculated.

The invention provides a flow device for creating a flow of bubbles of a contrast medium. The device comprises a pump which is configured to provide a flow of the medium and an elongated insertion tube attached to the pump at a proximal end. The elongated insertion tube forms a flow path between the proximal end and an outlet at a distal end.

An imaging method for mapping a human or animal tissue area includes generating a plurality of cavitation bubbles in a liquid in the tissue area by ultrasound pulses being irradiated into the tissue area by at least one ultrasound source. A center of a focus area of the irradiated ultrasound pulses is positioned within a first subarea of the tissue area. The first subarea is separated from a second subarea of the tissue area by a tissue boundary, and/or a flow of liquid is present in the first subarea. A spatial distribution and/or movement of the plurality of cavitation bubbles developing in the tissue area on account of a pressure field caused by the irradiated ultrasound pulses is mapped by an imaging modality.

Systems and methods for improving soft tissue contrast, characterizing tissue, classifying phenotype, stratifying risk, and performing multi-scale modeling aided by multiple energy or contrast excitation and evaluation are provided. The systems and methods can include single and multi-phase acquisitions and broad and local spectrum imaging to assess atherosclerotic plaque tissues in the vessel wall and perivascular space.

An ultrasonic intracranial sonothrombolysis pressure amplitude is pre-quantified by using an ultrasound-scanner control unit (110) having an increasing and/or decreasing mode and designed for: with respect to a current mode, interrogating a blockage site iteratively so as to progressively and respectively increase or decrease a pressure amplitude of ultrasound being emitted to the site at which bubbles (144) for oscillating that is caused by the emitted ultrasound are present; iteration to iteration, deriving, from echoes of the emitted ultrasound, a magnitude of an energy of a signal; and automatically identifying, for the quantifying, an iteration that, in comparison with a just-previous iteration, fails to increase the magnitude. The interrogating may span a region that contains or goes through: the obstruction; another part of the blood vessel; and bubble circulation within a neighboring vessel and a neighboring capillary (136). The deriving can be based on an ultraharmonic signal, with band-pass filtering being utilized to extract the ultraharmonic signal from returning signals differenced to remove stationary content.

Systems and methods for improving soft tissue contrast, characterizing tissue, classifying phenotype, stratifying risk, and performing multi-scale modeling aided by multiple energy or contrast excitation and evaluation are provided. The systems and methods can include single and multi-phase acquisitions and broad and local spectrum imaging to assess atherosclerotic plaque tissues in the vessel wall and perivascular space.

Disclosed is a system and method for the placement of elongate medical members within a patient’s body using coaptive ultrasound that combines magnetic guidance with ultrasound visualization of the medical member in the patient’s body. A coaptive ultrasound probe adaptor magnetically attracts an elongate medical member within the patient with sufficient force so as to allow the operator to manually guide the member to its intended location. The adaptor mates with an ultrasound probe to provide the medical operator ultrasound feedback of the position of the member, thus allowing internal placement without the need for more specialized medical equipment.