An ultrasound probe arrangement comprises a holder for application to a surface, a housing mounted over the holder and a probe carrier. The housing has an inner guide surface which comprises a portion of a sphere and the probe carrier comprises a disc having an outer guide surface around the outer rim of the disc which comprises a portion of sphere. The probe carrier is slidable within the housing with the inner and outer guide surfaces in contact. An ultrasound probe is carried by the probe carrier and makes contact with the surface, e.g. skin. This arrangement enables the probe to be held in a desired orientation so that a clinician can work hands-free. The disc design enables different probe designs to be used with the same basic holder and housing design.

A system for monitoring blood flow in a patient comprises a first unit having an ultrasound transducer and a fastener for fastening the unit to the patient. A controller subsystem comprises the first unit and a separate second unit. The controller subsystem is configured to: control the ultrasound transducer to transmit plane-wave pulses into the patient in a propagation direction; sample reflections of the plane-wave pulses, received at the ultrasound transducer, from a region within the patient, to generate pulse-Doppler response signals; and process the pulse-Doppler response signals to estimate a series of values, over time, of a measure proportional, but not equal, to the total blood volume flow passing through the region. A monitoring subsystem is configured to monitor the series of values over time and to generate a signal if a set of one or more of the values satisfies a predetermined criterion.

A system comprising a multi-modal ultrasound probe configured to operate in a plurality of operating modes associated with a respective plurality of configuration profiles; and a computing device coupled to the handheld multi-modal ultrasound probe and configured to, in response to receiving input indicating an operating mode selected by a user, cause the multi-modal ultrasound probe to operate in the selected operating mode.

Aspects of the technology described herein related to controlling, using control circuitry, modulation circuitry to modulate and delay first ultrasound data generated by first ultrasound transducers positioned at a first azimuthal position of an ultrasound transducer array of an ultrasound device and second ultrasound data generated by second ultrasound transducers positioned at a second azimuthal position of the ultrasound transducer array of the ultrasound device, such that the first ultrasound data is delayed by a first delay amount and the second ultrasound data is delayed by a second delay amount that is different from the first delay amount. The first and second ultrasound data received from the modulation circuitry may be filtered and summed. The ultrasound transducer array, the control circuitry, the modulation circuitry, the filtering circuitry, and the summing circuitry may be integrated onto a semiconductor chip or one or more semiconductor chips packaged together.

A portable surface acoustic wave (SAW)-generating system, a transdermal patch, and methods of treatment with improved transdermal administration of drugs are provided. Application of the transdermal patch comprising a therapeutically effective amount of the cannabis id, such as a cannabis drug, to the skin in combination with SAW results in a synergistic effect on delivery and absorption of the at least one drug as compared to topical administration of the drug via the transdermal patch without the surface acoustic waves generated by the portable SAW-generating system.

Apparatus, system and methods are described for providing a health care provider (HCP) with an enhanced reality perceptual experience for surgical, interventional, therapeutic, and diagnostic use. The apparatus, system and methods make use of a combination of sensors and audio visual data to cross-correlate information, and present the correlated information to the HCP on to one or more platforms for use during a diagnostic, interventional, therapeutic, or surgical procedure.

Beamforming circuitry for an ultrasound device is disclosed, that may directly calculate the position in receive line space for an incoming ultrasound data sample given the time of flight (ToF) of that ultrasound data sample. In some embodiments, this may be done without initially buffering the ultrasound data sample received from the particular receive datapath multiplexed to the beamforming circuitry. The beamforming circuitry may then associate the ultrasound data sample with that position in receive line space, and in particular, with a memory address corresponding to that location. Thus, when the beamforming circuitry multiplexes between different receive datapaths, it may not need to buffer ultrasound data samples from different receive datapaths prior to saving the data to memory.

The present disclosure relates to an apparatus for facilitating medical imaging of a subject. The apparatus comprises a medical imaging device receiver configured to receive a medical imaging device, at least one auxiliary equipment receiver configured to receive an auxiliary equipment for placement at a target portion of the subject, and a sound wave manipulation module arranged to direct transmission of sound waves between the medical imaging device and the subject, wherein an image of the target portion is formed by the medical imaging device for guiding placement of the auxiliary equipment. In particular, the medical imaging device is an ultrasound probe, the auxiliary equipment is a needle, catheter or endoscope, while the sound wave manipulation module comprises a sound wave deflection surface arranged to alter a direction of transmission of at least part of the sound waves. The present disclosure also relates to a method of deploying the apparatus.

An ultrasound controller unit (22) for controlling an ultrasound transducer unit (24) in acquiring ultrasound data for the purpose of deriving one or more physiological parameter measurements. The controller is adapted to control weighting coefficients applied to transmit and receive signals of each of a plurality of transducer elements (26) of the transducer unit. The controller is adapted to detect any artifact in received data affecting (e.g. obscuring) the output path of one or more of the transducers, and to identify the affected transducer elements. The weighting coefficients of the non-affected transducer elements are then adjusted so as to minimize an estimated noise component in the parameter measurement, if derived using only the non-affected transducer elements. Measurements of the one or more parameters are then derived by collecting data from the non-affected transducers only, these being configured with the optimized weighting coefficients.

The invention relates to a method of identifying, from a number of ultrasound images (34) acquired during an ultrasound examination of a subject (6), the ultrasound image best suited to analyze a pre-determined anatomical structure of the subject. The method comprises the steps of (a) Providing a number of ultrasound images (34) acquired during an ultrasound examination of the subject; (b) Deriving at least one biometric parameter (96) related to the anatomical structure from a physical examination of the subject, (c) Retrieving a reference image (38) showing a target view of the anatomical structure (35); (d) For each of the number of ultrasound images (34), calculating an image similarity index between the ultrasound image and the reference image, (e) For at least the ultrasound image(s) having the best image similarity index, determining (100) a biometric parameter from the ultrasound image, and calculating a biometric similarity index, i.e. a measure of the agreement between the biometric parameter, as determined from the ultrasound image, and the corresponding biometric parameter as derived from the physical examination; and (f) selecting the optimal ultrasound image based on the biometric similarity index, and optionally on the image similarity index.