Provided is an object information acquiring apparatus, having: an ultrasound transmitting element; a plurality of transducers each detecting a first acoustic wave generated by light, which is radiated into an object, and outputting a first electric signal, and detecting a second acoustic wave generated by an ultrasound wave, which is transmitted from the ultrasound transmitting element and which is scattered inside the object, and outputting a second electric signal; a support supporting the plurality of transducers so that directivity axes of the transducers are concentrated; and a processor acquiring property information on the object based on the first electric signal and the second electric signal respectively.

Virtual Dermatopathology Regional Hub (VDRH) receives one or more of the Detailed Virtual Tissue Models generated at one or more of the Virtual Dermatology Workstations and selectively communicates each to at least one pathology site. Each pathology site includes one or more Dermatopathology Information Processing Workstations (DIPWs). Thereafter, the VPM receives from the one or more of the pathology sites a plurality of pathology reports generated using said DIPWs and respectively corresponding to the plurality of DVTMs. The VPM then selectively communicates the pathology reports to the imaging facility which generated respectively the DVTM upon which each said pathology report is based.

A radiotherapy system including a radiotherapy component, a structural imaging component, a functional imaging component, and a workstation coupled to the radiotherapy component, the structural imaging component, and the functional imaging component. The workstation includes a processor which combines the structural imaging data and the functional imaging data to produce a fused model for a least a portion of the region of interest, to generate a plan for radiotherapy treatment of the region of interest based on the fused model, and apply, via the radiotherapy component, the radiotherapy treatment.

The present invention relates to a visualization apparatus (1) comprising a signal processor (2) for processing measurement signals from an ultrasound measurement (3) and a rendering device (4) coupled to a processor for rendering a representation for discerning a region of tissue with changed property (42) upon energy application to the tissue from a region with unchanged property (41) within two extremities (44,47) of the representation indicative of two boundaries defining the tissue thickness. The rendering of the tissue with changed property (42) and the tissue with unchanged property (41) with different visual aspects is readily absorbable by a person who applies energy to the tissue.

According to the present invention, when measurement of a distance (fetal head biparietal diameter) on an ultrasonic image is started, a first mobile marker for designating a start point and a standard range display graphic are displayed. The standard range display graphic is a graphic that is centered on the first mobile marker and comprises two circular graphics having radii that are configured to be a lower limit and upper limit of a fetal head biparietal diameter standard range. A user can designate the start point while recognizing, via the standard range display graphic, an end point candidate range. Subsequently, an end point can be designated while recognizing the end point candidate range via a stationary standard range display graphic.

Embodiments of portable cranial anatomy injury evaluation systems, apparatus, and methods are described generally herein where the system and apparatus may include multiple signal generation devices including photonic, acoustic, and electrical signals. Other embodiments may be described and claimed.

The present disclosure provides using ultrasound technology and artificial intelligence to enhance MSR assessment by making the assessment more objective, reproducible, and recordable to allow a more precise and/or personalized approach to the medical practice of individual patients via using multiple ultrasound functions and artificial intelligence to improve the accuracy and consistency of assessing reflexes and allowing MSR data to be combined with other patient medical information for improved diagnosis and management of a patient's condition.

The present invention relates to ultrasound imaging, and in particular to a device for imaging bodily tissue under load. The device has a platform (10), for at least partially supporting a part of the body (2), at least one ultrasound device (20) for imaging of the part of the body (2) in contact with the platform (10), and means (32) for measuring the pressure exerted on the platform (10).

Systems, devices, and methods are provided to provide workflow assistance to an operator during a medical imaging procedure, such as a Doppler ultrasound evaluation of a body vessel of a subject. A sensor such as a gyroscope (128) may be integrated in an external ultrasound probe (102). Workflow assistance may be provided to position the ultrasound probe (102) to make accurate flow measurements of fluid within the vessel, such as by coupling system color flow information with gyroscope angles. The workflow assistance may also assist a user in identifying a perpendicular orientation of the ultrasound to be used as a reference in making Doppler measurements. The system may also be used to create a vessel map.

A system and method for ultrasound treatment of skin laxity are provided. Systems and methods can include ultrasound imaging of the region of interest for localization of the treatment area, delivering ultrasound energy at a depth and pattern to achieve the desired therapeutic effects, and/or monitoring the treatment area to assess the results and/or provide feedback. In an embodiment, a treatment system and method can be configured for producing arrays of sub-millimeter and larger zones of thermal ablation to treat the epidermal, superficial dermal, mid-dermal or deep dermal components of tissue.