The information processing apparatus performs processing of causing a display device (21) to display an ultrasound image (U), which is generated by transmitting ultrasound beams (UB) from a transducer array (13) toward the inside of a living body (30) and receiving ultrasound echoes generated in the living body (30). The information processing apparatus includes: a blood vessel aggregate detection unit (72) that detects, from the ultrasound image (U), a blood vessel aggregate region (Ra) including a blood vessel aggregate in which three or more blood vessels (B) are aggregated; and a highlight display unit (54) that highlights and displays the blood vessel aggregate region (Ra) in the ultrasound image (U).

Techniques for non-invasive detection of compartment syndrome (CS) in a subject, includes an apparatus having a structural body configured to be held in a human hand. The structural body includes a subject contact element that is not in contact with the human hand and is configured to contact but not penetrate a skin layer of a subject. The apparatus also includes an optical sensor configured to detect oxygen saturation at a plurality of depths of a subject in contact with the subject contact element. The optical sensor includes at least one light emitting diode (LED) and multiple photo detectors at corresponding different distances from the LED.

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

Embodiments provide an ultrasound treatment system. In some embodiments, the system includes a removable transducer module having an ultrasound transducer. In some embodiments, the system can include a hand wand and a control module that is coupled to the hand wand and has a graphical user interface for controlling the removable transducer module, and an interface coupling the hand wand to the control module. The interface may provide power to the hand wand or may transfer a signal from the hand wand to the control module. In some embodiments, the treatment system may be used in cosmetic procedures on at least a portion of a face, head, neck, and/or other part of a patient.

Disclosed is a system and a method to analyze spectrophotometry and ultrasound images and data in a complex way to diagnose malignant skin tumors in early stages. The system consists of a high-frequency portable ultrasonic imaging device for in vivo skin examinations, an optical spectrophotometer with light sources of different wavelengths for skin chromophore registration, and a complex data processing algorithm providing an advisory diagnostic evaluation. This enables automatically aggregating data and quantitative estimates obtained by different imaging techniques for melanocyte-derived skin tumors, facilitating the decision support for acceptance of the final clinical diagnosis and treatment planning. The system allows simultaneous analysis of images recorded by devices with different physical principles, automatic separation of the tumor area and evaluation the depth of the tumor penetration into the superficial tissue, which is essential for the selection of further testing and treatment tactics, and the planning of surgical removal procedures.

Methods and systems for treating skin, such as stretch marks through deep tissue tightening with ultrasound are provided. An exemplary method and system comprise a therapeutic ultrasound system configured for providing ultrasound treatment to a shallow tissue region, such as a region comprising an epidermis, a dermis or a deep dermis. In accordance with various exemplary embodiments, a therapeutic ultrasound system can be configured to achieve depth with a conformal selective deposition of ultrasound energy without damaging an intervening tissue. In addition, a therapeutic ultrasound can also be configured in combination with ultrasound imaging or imaging/monitoring capabilities, either separately configured with imaging, therapy and monitoring systems or any level of integration thereof.

A method and system for noninvasive face lifts and deep tissue tightening are disclosed. An exemplary method and treatment system are configured for the imaging, monitoring, and thermal injury to treat the SMAS region. In accordance with an exemplary embodiment, the exemplary method and system are configured for treating the SMAS region by first, imaging of the region of interest for localization of the treatment area and surrounding structures, second, delivery of ultrasound energy at a depth, distribution, timing, and energy level to achieve the desired therapeutic effect, and third to monitor the treatment area before, during, and after therapy to plan and assess the results and/or provide feedback.

A method for quantifying viscoelasticity of a medium includes: obtaining a position-time graph of vibration propagation after the medium is subjected to a vibration excitation, determining an angle with maximum signal energy in the position-time graph by using angle projection, where the angle with the maximum signal energy corresponds to a slope of the position-time graph and the slope of the position-time graph is the propagation velocity of the vibration in the medium. Since the propagation velocity of the vibration in the medium is related to the viscoelasticity of the medium, a viscoelasticity parameter of the medium can be quantitatively calculated after the slope of the position-time graph is obtained. The method does not need to select a feature point from the position-time graph to calculate the slope of the position-time graph, and can efficiently and accurately quantifies viscoelasticity of the medium.

Embodiments of the invention introduces a method and system for focusing ultrasonic energy through intervening skull tissue into a target site within a target brain tissue region under the skull, includes a transducer emitter array, a transducer receiver array, a processor receiving echo signals from the receiver to determine correction factors for the transducer elements to compensate for refraction occurring due to intervening tissue. The correction factors may include phase correction factors, and the phases of excitation signals provided to the transducer elements may be calibrated focusing based upon the phase correction factors to focus the ultrasonic energy to the tissue at the target site.

Disclosed are an ultrasound imaging system for analysis of a body composition and an operation method of an ultrasound imaging system which is designed for analysis of a body composition. An ultrasound imaging system may include: a scan device into which an object is insertable; an ultrasonic probe connected to a part of the scan device; a controller configured to control the ultrasonic probe to emit a transmission ultrasonic signal to the object at multiple positions at the scan device, and receive a reflection ultrasonic signal reflected from the object; and an image processor configured to generate multiple 2D ultrasound images based on reflection ultrasonic signals received at the multiple positions at the scan device, respectively, and generate a 3D ultrasound image based on the multiple 2D ultrasound images.