A medical imaging element support unit is for use in fixing a medical imaging element (26) releasably against a region of skin of a subject. The includes a support body (14), having a base for engaging with skin of a subject in use and having a coupling means (22) for releasably coupling the medical imaging element (26) to the support body in use. A pneumatic positioning mechanism facilitates adjustment of a position of the medical imaging element relative to the support body, this being fluidly supplied by an air pump mechanism. The same air pump mechanism facilitates releasable fixation of the support body (14) to the skin, through creation of a configurable suction force at the skin engagement surface.

A probe holder includes a casing and an elastic structure including an inner cover and a retainer unit. The retainer unit includes an enclosing wall, and a rib array protruding from an inner face of the enclosing wall. The rib array holds a cable end with a rear end of a probe head being supported by a support face of the inner cover.

A system useful for performing ultrasound elastography of organs such as the liver allows efficient and robust data acquisition. The system may be applied to perform real-time, noninvasive ultrasound imaging of the liver in humans. Steady-state, shear wave absolute elastography is used to measure the Young's modulus of the liver tissue. This method involves the use of an external exciter or vibrator to shake the tissue and generate a shear wave. Accurate placement of an ultrasound transducer facilitates measurement of the tissue motion due to the shear wave. The stiffness of tissues in the region being imaged may be computed from the measured tissue motions. The following innovations address both vibrator and transducer placement, as well as some specific methods to ensure adequate wave propagation, in order to obtain accurate and consistent measurements.

Implementations described and claimed herein provide systems and methods for managing one or more patients. In one implementation, an imaging window is determined based on a location of a probe. A primary image cross-section for the imaging window is identified for the imaging window. At least one image is generated along the primary image cross-section using patient data captured using the probe. The at least one image is compared to an expected image contour scaffold of the primary image cross-section. The probe is commanded to fine-tune an imaging plane based on the comparison until the at least one image matches the expected image contour scaffold of the primary image cross-section.

The invention relates to a method for obtaining a numerical model, the numerical model associating at least one objective measurement to a subjective sensation, the method comprising the steps of: a) imaging the at least one area of the brain by using unfocused waves produced by a transcranial ultrasound probe (20), to obtain at least one acquired image of the activity of the area, b) evaluating a physical quantity representative of the activity of the at least one area based on the acquired images, to obtain at least one objective measurement, c) obtaining from the subject at least one numerical value representative of a subjective sensation, and d) determining the numerical model by using the obtained objective measurement and the obtained numerical value.

According to various embodiments, there is provided a device including a processor configured to control a robotic system to autonomously position a transducer at a plurality of locations adjacent a subject's skull and to autonomously locate a window on the subject's skull within which an artery can be located, from which artery a signal can be returned to the transducer, the signal having an energy level exceeding a predefined threshold.

Prostate biopsy systems are provided that include a 3D ultrasound probe support configured to receive an ultrasound probe for transperineal imaging. One or more template grids can have a plurality of apertures extending therethrough to receive and guide a biopsy needle along a trajectory associated with respective apertures when the template grid is fixed to the support and the biopsy system is positioned in the perineal area of a patient. Patient-specific template grids can also be developed and produced. This system enables fully transperineal prostate biopsy (i.e. both imaging and needle placement are perineal) and eliminates the need for an external racking device for image fusion as well as needle tracking. In addition, it reduces the infection risk associated to transrectal approach.

Arrangements described herein relate to systems, apparatuses, and methods for a disposable kit containing medical items configured for a medical device including a head cradle to support a head of a subject, the disposable kit includes a container that encloses a head cradle pad configured to be affixed to the head cradle, at least one fiducial marker configured to be disposed on a location at the head of the subject, and at least one enclosure configured to cover a portion of the medical device.

A method of non-destructive evaluation of mechanical properties of a material using ultrasonic waves in a monostatic configuration is disclosed. The method comprises remotely scanning a sample of the material without directly contacting the sample, measuring an acoustic impedance of the scanned sample, and calculating mechanical properties of the material using the acoustic impedance.

An ultrasound image system is provided. The ultrasound image system includes an ultrasound probe and a processing circuit. The ultrasound probe includes a substrate, a first transducer array and a second transducer array. The first transducer array is fixed disposed on the substrate and configured to receive a first ultrasound signal The second transducer array is fixed disposed on the substrate and configured to receive a second ultrasound signal. Each of the first transducer array and the second transducer array includes a plurality of ultrasound transducer elements arranged along a first direction. The ultrasound transducer elements of the first transducer array are interleaved with the ultrasound transducer elements of the second transducer array. The processing circuit is coupled to the first transducer array and the second transducer array and is configured to generate an ultrasound image signal according to the first ultrasound signal and the second ultrasound signal.