The embodiments herein provide a system for calibration-free cuff-less evaluation of blood pressure. The system includes an ultrasound-based arterial compliance probes and a controller unit connected to the said probe. The ultrasound transducers are configured to measure the change in arterial dimensions, pulse wave velocity, and other character traits of an arterial segment over continuous cardiac cycle, which is then used to evaluate blood pressure parameters without any calibration procedure using dedicated mathematical models. The pressure sensor/force sensor/bio-potential transducers/accelerometric sensors are configured to measure a pressure acting on a skin surface at a measurement site, an internal arterial transmural pressure level, an applied pressure or a hold-down pressure on the skin surface or an arterial site, biopotential and/or plethysmograph signal, arterial vibrations acting on the measurement site as a function of the arterial pressure and the mechanical characteristics and/or a function of the applied/hold-down pressure and/or function of external factors.

An ultrasound imaging apparatus includes: a processor configured to set a detection position for detecting a shear wave that is generated due to an ultrasound wave that is applied to an observation target by an ultrasound transducer of an ultrasound probe, calculate feature data between the ultrasound transducer and the detection position, set a threshold in accordance with the feature data, acquire contact pressure between the ultrasound probe and the observation target, and determine whether the contact pressure is equal to or smaller than the threshold.

At least one embodiment of a method for a method of detecting an abnormality along a portion of a dental arch using scanning material comprising an ultrasonic periodontal probe configured for emitting ultrasound signals within at least one emitting cone and for receiving corresponding echoed ultrasound signals, the method comprising moving the probe along a portion of the dental arch, while moving the probe along the portion of the dental arch: emitting an ultrasound signal within the emitting cone; measuring echoed ultrasound signals; detecting at least one anatomical structure to be investigated; measuring at least one predetermined feature of the at least one detected anatomical structure to obtain a value of the measurement of the at least one predetermined feature characterizing the detected anatomical structure; detecting an abnormality as a function of a threshold and the value of the measurement of the predetermined feature of the at least one detected anatomical structure.

At least one embodiment of a method for scanning material using a dental ultrasonic imaging probe comprising an ultrasonic device configured for emitting ultrasound signals within at least two emitting cones and for receiving corresponding echoed ultrasound signals, the at least two emitting cones extending in different directions, the method comprising: receiving an item of information relating to a direction for emitting an ultrasound signal; selecting one of the received corresponding echoed ultrasound signals or the ultrasound signals to be emitted as a function of the received item of information.

At least one embodiment of an ultrasonic periodontal probe, the ultrasonic periodontal probe comprising a grip portion having a longitudinal axis, a support member comprising a part having a longitudinal axis different from the longitudinal axis of the grip portion, and an ultrasonic device fastened to the grip portion via the support member, wherein the ultrasonic device is configured for emitting ultrasound signals within at least two emitting cones and for receiving corresponding echoed ultrasound signals, the at least two emitting cones extending in opposite directions with regard to a plane comprising the longitudinal axis of the grip portion.

An ultrasound diagnostic apparatus (1) includes a gel layer thickness calculation unit (9) that calculates a thickness of a gel layer by analyzing an ultrasound image; a tissue recognition unit (10) that recognizes a tissue of a subject by analyzing the ultrasound image; and a press state determination unit (11) that determines a press state of an ultrasound probe (21) against a body surface of the subject on the basis of a shape change of the tissue recognized by the tissue recognition unit (10) in a case where the calculated thickness of the gel layer is equal to or less than a thickness threshold value.

An ultrasound scanning control method applied to an ultrasound scanning device is provided. The ultrasound scanning device includes an execution mechanism. The execution mechanism includes a mechanical arm and a probe. The ultrasound scanning control method includes: controlling the mechanical arm to drive the probe to move according to a set scanning trajectory; and controlling the probe to collect an ultrasound image. A target region is identified from the collected ultrasound image. The scanning trajectory is adjusted when a position of the target region in the ultrasound image is not a predetermined position, and the mechanical arm is controlled to drive the probe to move according to the adjusted scanning trajectory.

A patient bearing system and a robotic system are disclosed. The patient bearing system includes a patient bearing and at least one ultrasound transducer with an ultrasound head at least partly located in the patient bearing and being spatially located to transmit ultrasound signals to a target space. The ultrasound head is at least partly located in the patient bearing. The robotic system includes a patient bearing system and a robot configured for at least partly operate the system and the computer system is programmed for performing image acquisitions and analysis of a body part at least partly located in target space.

System for non-invasive measuring of an intracranial reserve space (ICRS) parameter of a mammalian subject, comprising a multi-frequency ultrasound probe configured, beginning at a start time, to emit and receive ultrasound waves into and the subject's head and to produce a signal of brain tissue pulsation; an instrument configured to non-invasively partially occlude an internal jugular vein (IJV) starting at the start time and including a second ultrasound probe producing a second signal; and a computer system configured to receive the signal, the second signal and the start time, the computer system also configured, using one or more processors, to derive from the signal an intracranial brain tissue pulsation waveform and from the second signal images of the IJV, and to determine a length of time from the start time to a subsequent time at which the waveform is sufficiently compressed so as to exhibit a predefined decline in variability.

A laser interlock system and allows laser radiation to be generated when an inspector and a subject correctly wear safety glasses and during use of a photo-acoustic imaging apparatus, thereby protecting the eyes of the inspector and the subject and preventing unnecessary power consumption. The laser interlock system includes a sensing unit to sense whether or not contact between a user and safety glasses occurs, a light source unit to generate a laser, and a control unit that determines, based on an output value from the sensing unit, whether or not the user is wearing the safety glasses normally, and generates an interlock signal to turn on or off the light source unit for selective laser generation according to the determination.