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.

A wireless system and method for measuring and analyzing blood in a user's body is provided. The system includes a processing, power, and communication component (PPC) having a hardware unit and first housing enclosing the hardware unit; a probe having a piezoelectric crystal and second housing enclosing the piezoelectric crystal; a dock having a sensor and third housing enclosing the sensor. The second housing is spaced apart from the first housing. The third housing is adapted to removably couple to the first housing. The piezoelectric crystal can transmit an ultrasound wave into the body, receive a return ultrasonic wave, convert the return wave into an electrical signal, and transmit the signal to the sensor. The sensor is configured to receive and then transmit the electronic signal to the hardware unit, which is configured to wirelessly transmit a data set based on the electronic signal to a computer device.

The invention relates to a temperature distribution determination apparatus for determining a temperature distribution within an object (20), while an energy application element (2) applies energy to the object, especially while an ablation procedure for ablating a tumor within an organ is performed. A time-dependent first ultrasound signal is generated for an ultrasound measurement region within the object and a temperature distribution within the object is determined based on the generated time-dependent first ultrasound signal and based on a position of the energy application element (2) relative to the ultrasound measurement region tracked over time. This can ensure that always the correct position of the energy application element, which may be regarded as being a heat source, is considered, even if the energy application element moves, for instance, due to a movement of the object. This can lead to a more accurate determination of the temperature distribution.

Described here are systems and methods for improved ultrasound attenuation coefficient estimation (“ACE”) techniques. In one aspect, noise can be suppressed by using signal-to-noise ratio (“SNR”) as a quality control metric for restricting depth ranges for ACE. In this way, the proper depth range for each frequency component can be adaptively changed with sufficient SNR for ACE. In another aspect, elevation focusing normalization is used to reduce errors associated with diffraction effects when estimating attenuation coefficient. In another aspect, methods for suppressing noise in ACE techniques is provided. Noise can be suppressed based on a noise field computed from measurements obtained without ultrasound transmission, based on a unique combination of consecutive image frames, based on singular value decomposition (“SVD”) clutter filtering cutoff values, or combinations thereof.

A method for conditioning a breathing tube for use in lung function diagnostics and a breathing tube made by such a method. This method is characterized by heating at least a section of a fully assembled breathing tube by a heating source to a temperature of at least 40° C., wherein heating is performed during a first time period, the first time period lasting between 0.1 seconds and 5 seconds wherein the section includes at least one window covered by a mesh.

Systems, devices, and methods for automated, fast lung pulse detection are provided. In an embodiment, a system for detecting pneumothorax (PTX) includes an ultrasound probe in communication with a processor. The processor is configured to generate, using the ultrasound imaging data received from the ultrasound probe, an M-mode image including a pleural line of the lung. Using the M-mode image, the processor generates a difference image comprising a plurality of difference lines generated by subtracting adjacent samples of the M-mode image. The processor analyzes the difference image to determine whether the difference image includes a periodic signal corresponding to the heartbeat of the patient and outputs a graphical representation of detecting the lung pulse based on determining that the difference image includes the periodic signal corresponding to the heartbeat.

An instrument system that includes an elongate instrument body and an optical fiber sensor is provided. The optical fiber sensor includes an elongate optical fiber that is coupled to the elongate instrument body, wherein a portion of the optical fiber is coupled to the elongate instrument body in a manner to provide slack in the fiber to allow for axial extension of the elongate instrument body relative to the optical fiber.

An ultrasound apparatus includes a touch screen configured to display, on an ultrasound image, a touch recognition region of an object used as a measurement mark; and a controller configured to move the object and the touch recognition region, in response to an input for touching and dragging the touch recognition region, to detect, from a portion of the ultrasound image which corresponds to the touch recognition region, a line formed by connecting points at which a brightness variation of a pixel is greater than a threshold value, and to move the object to a position of the detected line by using coordinates of the detected line.

The invention is directed to systems and methods for determining a fundamental pulse wave velocity value for a vessel with minimized effect of reflections originating from the vessel network connected distal to the respective vessel.

Aspects described herein disclose devices, systems, and methods for use in contexts such as minimally invasive surgery (MIS). A device is provided herein having a proximal portion and a distal portion, and an ultrasound transducer may be disposed within the distal portion and configured to scan tissue and identify certain portions of a patent's anatomy during the scanning process. The results of the detection may be presented to an operator of the device aurally and/or visually, such as in a 3-D volumetric image. By scanning the tissue, identifying the anatomy, and presenting the results to an operator, unnecessary damage to elements of the patients anatomy may be avoided or lessened. In some aspects, multiple transducers may be positioned on the device to increase the scanning range and/or scanning accuracy of the device. The device may provide an inner channel for the passage of surgical tools while scanning tissue.