Abstract: An ultrasound diagnosis apparatus according to an embodiment includes Doppler processing circuitry and processing circuitry. The Doppler processing circuitry filters a data sequence of reflected-wave data at the same positions across a plurality of frames in a frame direction to collect blood flow information in a predetermined region of interest. The processing circuitry receives a first instruction to change the range of flow rate values to be displayed, in display of the blood flow information. The processing circuitry receives a second instruction to change a setting related to the region of interest. The processing circuitry changes the range of flow rate values in response to the first instruction when receiving the first instruction, and performs an adjustment for maintaining the range of flow rate values when receiving the second instruction.

Abstract: A system and method are provided for generating time resolved series of angiographic volume data having flow information integrated therewith. The method includes generating a series of 3D time-resolved vascular volumes from time resolved x-ray projection data and calculating blood velocity in the vascular volumes x-ray projection data to determine a rate of change of calculated contrast material arrival time at positions along the vascular volumes. The method also includes displaying the 3D time-resolved vascular volumes with a graphical indication of blood velocity in the vascular volumes.

Abstract: Methods, system, and media for identifying one or more ablation locations in an atrial tissue region in an atrial fibrillation (AF) patient with atrial fibrosis are disclosed. Three-dimensional imaging data representing the atria of the patient may be received. A patient-specific model of the atria may be generated from the three-dimensional imaging data. Simulation of the AF on the patient-specific model may be conducted to identify AF-perpetrating regions. One or more ablation locations in the atria may be identified from the AF-perpetrating regions.

Abstract: An apparatus and as method for generating ultrasound. The apparatus comprises: a signal generator arranged to generate a driving signal; and an ultrasound transducer arranged to transmit an ultrasound beam in response to the driving signal received from the signal generator. The signal generator is arranged to combine a carrier wave and a modulating wave having a lower frequency than the carrier wave to generate an amplitude modulated driving signal. The ultrasound beam is suitable for inducing cavitation in a human or animal body tissue.

Abstract: An ultrasonic imaging apparatus includes an ultrasonic probe and a delay amount calculation unit. Each of the delay circuits is configured to allow a first delay amount and a second delay amount to be set for each of the delay circuits, and delays a signal by a delay amount obtained by adding the first delay amount and the second delay amount together. The delay amount calculation unit calculates the first delay amount and the second delay amount such that a sum of the first delay amount and the second delay amount set for each of the delay circuits is equal to or less than a predefined maximum delay amount.

Abstract: According to one embodiment, an X-ray CT apparatus includes a calculator, a transmitter, a data acquisition unit, and a processor. The calculator calculates a difference between imaging time phases of a first contrast agent and a second contrast agent. The transmitter sends information on the difference between the imaging time phases to an injector. The injector injects the first contrast agent and the second contrast agent into the subject at different timings based on the information. The data acquisition unit scans a subject with X-rays at a predetermined imaging timing to acquire detection data corresponding to different X-ray energies. The processor analyzes the detection data acquired at the predetermined imaging timing to generate a plurality of images corresponding to the imaging time phases.

Abstract: A probe transmission device comprises a drive shaft which is provided with a radial hole and an axial hole, wherein the radial hole is in communication with the axial hole. A rope extends into the axial hole via the radial hole. A fixing component is arranged within the axial hole and fixes the rope within the radial hole. The probe transmission device is provided with the radial hole and the axial hole on the drive shaft. The rope extends into the radial hole and is fixed via the fixing component which is arranged with the axial hole. The structure of the present probe transmission is simple. The surface of the drive shaft does not require a component for fixing the rope, and the surface of the drive shaft is smooth. Interference produced by the rope and components on the surface of the drive shaft is avoided.

Abstract: Provided are a portable ultrasound apparatus, a portable ultrasound system, and an ultrasound diagnosis method performed by using the portable ultrasound apparatus. The portable ultrasound apparatus includes at least two probes having different specifications; a first display unit for displaying an ultrasound image; and a second display unit for displaying a control screen.

Abstract: Methods for associating detection information of an ultrasound system includes receiving an ROI (region of interest) and an image display type that are selected by an operator on an image detected by the ultrasound system, performing motion tracking for the ROI to obtain tracking information, configuring the image detected by the ultrasound system and position information of the ROI in a first display area of a display device for displaying, configuring quantitative parameter information related to the image in a second display area of the display device for displaying selecting an image model according to the image display type, and configuring the image model in a third display area of the display device for displaying. The methods can display detection information obtained by the ultrasound system on the display device more intuitively.

Abstract: Embodiments related to medical imaging devices including rigid imaging tips and their methods of use for identifying abnormal tissue within a surgical bed are disclosed.

Abstract: A tracking, and point-of-view-based imaging, device is configured for deriving a position of and a direction from, a location at a distal tip of an elongated instrument, for performing coordinate system transformation in accordance with the position and direction, and for forming, from the location and based on a result of the transformation, a local view that moves with the tip. The device can keep, with the movement, a field of view of the local view fixed but the local view otherwise in synchrony with the position and the direction. From real-time ultrasound imaging, the local view and a more overall view that includes the tip but which does not move with said tip can be displayed. The distal tip can be that of a catheter and can be outfitted with a micromanipulator for surgery aided interactively by the combination of dynamic local and overall imaging.

Abstract: An ultrasound imaging system (100) includes a transducer array (102). The transducer array includes a first set of transducer elements (206 or 208, 302 or 304) and a second set of transducer elements (208 or 206, 304 or 302). The first and second sets of transducer elements includes long axes and are angularly offset from each other by a non-zero angle with respect to the long axes. The ultrasound imaging system further includes a velocity processor (120) that processes echoes received by the first and second sets of transducer elements and determines an axial and two transverse flow velocity components based on the received echoes.

Abstract: The ultrasound examination system automatically detects a lesion, based on a dynamic image including a plurality of frame arrays that are temporally continuous and are output from the ultrasound examination apparatus with an ultrasonic probe being manipulated. Detection accuracy of the ultrasound examination system can be increased. A feature extractor in a frame checker extracts cubic higher-order local autocorrelation features from each frame of a plurality frames that constitute a dynamic image of a human body part as obtained from an ultrasound examination apparatus while an examiner manipulates an ultrasonic probe on the examinee. A final determinator determines that the frame in question is a normal frame when a speed determinator determines that the speed of the ultrasonic probe is not a normal speed even though the frame in question can be determined as an abnormal frame containing a lesion.

Abstract: A control system for delivering energy waveform radiation to influence in vivo tissue is described. For the system, the energy waveform radiation is generated by a radiation unit and is directed along a pathway to the tissue and a registration unit is provided to identify a start place relative to the in vivo tissue. Also, a monitor is provided to compare the start place with a base reference to measure an error signal between the start place and base reference. With this measured error signal, a controller operates the radiation unit using input from the monitor to effectively attain and maintain a zero error signal. More specifically, the controller can provide operational parameter inputs to the radiation unit for configuring the waveform radiation including a radiation frequency, f, and a volume intensity level, v, for the radiation and an exposure time interval, ti.

Abstract: Disclosed is a method for determining a positional pattern of an irradiation unit for irradiating a patient with treatment radiation. Optimal order data describing an order of the irradiation unit positions for which the statistical value is optimal is determined. The optimal order data is determined based on irradiation unit position data describing irradiation unit positions of the irradiation unit for which the imaging device has a free viewing direction onto the position of the patient, position orders data describing all possible orders of the irradiation unit positions for which the imaging device has a free viewing direction onto the position of the patient, and intersection angle data describing a statistical quantity of the intersection angles between free viewing directions of the imaging unit for irradiation unit positions which are immediately subsequent in the order described by the position orders data.

Abstract: A tracking system for a target anatomy of a patient can include a medical device having a body (281) having a distal end (290) and at least one channel (292) formed therein, where the body is adapted for insertion through an anatomy (105) to reach a target area (430); an accelerometer (185) connected to the body and positioned in proximity to the distal end; an imaging device (295) operably coupled with the body; and a light source (297) operably coupled with the body, where the accelerometer is in communication with a remote processor (120) for transmitting acceleration data thereto, where the imaging device is in communication with the remote processor for transmitting real-time images thereto, and where an orientation of the medical device and calibration of direction with respect to the anatomy is determined by the processor based on the acceleration data.

Abstract: A method for obtaining an elastic feature of an object includes inducing a first shear wave in the object by transmitting a first push ultrasound signal which is generated by a probe of an ultrasound apparatus and a first grating lobe signal which relates to the first push ultrasound signal toward the object, transmitting a tracking ultrasound signal to an area of the object where the first shear wave has propagated, receiving, from the object, a reflection signal which relates to the tracking ultrasound signal, measuring a first shear wave parameter which indicates a shear wave characteristic of the first shear wave based on the reflection signal, and obtaining an elastic feature of the object by using the first shear wave parameter.

Abstract: The present invention is a method, system, and apparatus used to transmit information to an individual and or receiver who is not located at the actual ultrasound procedure that may monitor, communicate, and assist in the procedure in real time as well as provide protocols for specific procedures; wherein the ultrasound machine communicates to a receiver operational information such as but not limited to audio, visual, performance, and so forth; wherein the information may be received in real time to another party not located at the site of the procedure who may assist with the procedure, training, protocols, and so forth; and wherein the receiver may then transmit back to the ultrasound machine specific directions as well as communicate with the ultrasound operator.

Abstract: The invention generally relates systems and methods to for producing an image from a rotational intravascular ultrasound device. A method can include alternately transmitting complementary Golay codes to a plurality of transducers in a intravascular ultrasound device; receiving echoes of the complementary codes from the transducers; performing pulse compression of the echoes that comprises weighting the received echoes and summing an odd number of weighted echoes, wherein a center echo is given a weighted value of 1.0 and weighted sums of its neighbors constitute complementary echoes of a Golay pair; and producing an image from the compressed echoes. A system can include a processor; and a plurality of beam modules coupled to the processor, each module comprising: a receiver for receiving a trigger signal from the processor; a complex programmable logic device programmed with a Golay code; a high voltage switching transmitter; and an ultrasound transducer.

Abstract: Disclosed examples include heart rate monitor systems and methods to estimate a patient heart rate, in which a processor filters digital photoplethysmogram (PPG) sample values representing transmission or reflection of a light signal in the patient during a time window, performs motion compensation processing on the filtered values, computes a gain value for individual segments of the time window using the motion compensated values, applies the individual gain values to the motion compensated values of blocks associated with the corresponding segments, and determines a heart rate estimate value representing the patient heart rate according to the frequency content of the adjusted values.