Abstract: A target object identification method includes acquiring an image to be identified, identifying at least one target area in the image and marking the target area to obtain at least one marked area, performing binarization processing on the marked area, identifying the boundary pixels and effective pixels of the target area in the marked area, and determining a center and a size of the target area according to a position of the boundary pixels and the effective pixels. An area of the marked area is greater than or equal to an area of the target area. The target area is located within the marked area. A color of pixels of the target area after the binarization process is different from a color of pixels outside the target area.

Abstract: An apparatus includes an ultrasonic transmitter, an ultrasonic receiver, and an acoustic delay gradient layer disposed in an acoustic path between the ultrasonic transmitter and the ultrasonic receiver. The acoustic delay gradient layer is configured to cause a reflection from a platen interface of the transmitted ultrasonic signal to reach the first receiver region at a first time and the reflection from the platen interface of the transmitted ultrasonic signal to reach the second receiver region at a second time that is different from the first time. The apparatus can further include a controller configured to set for a first region or portion of the receiver, a first range gate window (RGW). The controller is also configured to set, for a second region or portion of the receiver, a second RGW, and to establish a first temporal delay between the first RGW and the second RGW.

Abstract: First transmission information in which an optimum transmitting voltage and a transmitting waveform are associated with each other for each display mode, and second transmission information in which a plurality of transmitting voltage candidates and pulse-width modulation transmitting waveforms that are pulse-width-modulation controlled to respectively correspond to the plurality of transmitting voltage candidates are associated with each other for each display mode are used to extract a maximum transmitting voltage candidate that does not exceed an optimum transmitting voltage of a first display mode from a plurality of transmitting voltage candidates included in the second transmission information of a second display mode so as to determine a common transmitting voltage used in common for the first display mode and the second display mode based on the optimum transmitting voltage of the first display mode and/or the maximum transmitting voltage candidate.

Abstract: Embodiments of the present disclosure provides an ultrasonic image analysis system which includes an image collection unit which receives and transmits an ultrasonic waveform and obtains two sets of three-dimensional ultrasonic image data; an image analysis unit which registers the two sets of three-dimensional ultrasonic image data to obtain a registration mapping relationship between the two sets of three-dimensional ultrasonic image data; a user interface unit which responds to a treatment done on the two sets of three-dimensional ultrasonic image data by a user through an external hardware device; an image display unit which displays the two sets of three-dimensional ultrasonic image data according to the registration mapping relationship and a result of the treatment of the user interface unit; and an image store unit for storing the two sets of three-dimensional ultrasonic image data and the registration mapping relationship.

Abstract: A hydrogel that adheres to the surface of materials is provided by using as constituent elements a water-soluble main chain monomer, crosslinking agent, polymerization initiator, and adhesive monomer having at least a catechol group in a side chain.

Abstract: A method is provided for the optimization of the process decoding coded ultrasound signals that comprises: defining/selecting a coding function for ultrasound pulses transmitted to a body under examination by means of a predetermined probe; defining the coefficients of a filter decoding the received signal depending on the selected coding function; using said filter coefficients as the setting of the decoding filter corresponding to said predetermined probe for all the ultrasound systems provided in combination with said probe; and wherein the coefficients of the decoding filters are determined by the minimization, by a heuristic iterative process, of the difference between the characteristics of a receive signal, obtained in a real transmit/receive sequence and filtered with a decoding filter, and the characteristics of an ideal receive signal, that is a nominal one, by using as the coefficients of the decoding filter those obtained in the last iterative step.

Abstract: An ultrasound observation device includes a controller. The controller is configured to: generate data on an ultrasound image based on an ultrasound signal; automatically set a second region of interest that is relatively stiff in a first region of interest preset within the ultrasound image; and generate data on first and second elastic images each having a display mode according to stiffness of the corresponding first and second regions of interest.

Abstract: Embodiments include methods and systems for automated eating detection. Systems comprise a continuous glucose monitor (CGM), accelerometer, and processing unit. During a first time period, the processing unit receives glucose readings and a first set of acceleration readings. The processing unit identifies an eating episode if the glucose readings satisfy one or more criteria. Using the identified eating episode and first set of acceleration readings, the processing unit generates an individual model that identifies eating episodes using acceleration readings without using glucose readings. During a second time period, a processing unit uses the individual model and a second set of acceleration readings to identify a second eating episode. Some embodiments may use additional sensor types (for example, PPG or heart rate) to identify eating episodes in the first or second time period, generate the individual model, or any combination thereof.

Abstract: Systems and methods of facilitating the viewing of interventional instruments (e.g., needles, catheters, guidewires, vascular filters, biopsy probes) are disclosed herein. In one embodiment, a portable, handheld or cart-based ultrasound imaging machine is connected to an external laser light source that transmits laser light to a tip of an interventional instrument via one or more optical fibers. The laser light is absorbed at the distal tip of the instrument and generates a photoacoustic signal. The ultrasound imaging machine creates an image by combining data from the received photoacoustic signals with ultrasound echo data to show both tissue in a region of interest and the tip of the interventional instrument.

Abstract: Systems and methods for object recognition with limited input are disclosed herein. An example method includes updating a neural network trained to perform object recognition on a first rendition of an object, so that the neural network performs object recognition on a second rendition of the object, using a limited set of input images. The method includes receiving a limited set of model images of the second rendition of the object, accessing a corresponding image mapping, and generating a large number of training images from the limited set, where image mappings include geometric, illumination, and/or obscuration transformations. The neural network is then trained, from this initial small set, to classify the second rendition of the object.

Abstract: Systems and methods for performing shear wave elastography using push and/or detection ultrasound beams that are generated by subsets of the available number of transducer elements in an ultrasound transducer. These techniques provide several advantages over currently available approaches to shear wave elastography, including the ability to use a standard, low frame rate ultrasound imaging system and the ability to measure shear wave speed throughout the entire field-of-view rather than only those regions where the push beams are not generated.

Abstract: An apparatus for evaluating performance of an ultrasonic transducer includes a transducer assembly having an ultrasonic transducer and an acoustic medium and configured to transmit and receive an ultrasonic wave, a storage unit configured to store a reference signal value which represents the performance of the ultrasonic transducer, and a processing unit configured to control the transducer assembly to emit ultrasonic wave and receive a response (echo) signal thereto to measure a magnitude or energy amount of the response signal, the processing unit comparing a measured value with the reference signal value stored in the storage unit to evaluate the performance of the ultrasonic transducer.

Abstract: The present invention relates to a sensor for continuous detection of minute changes of density in fluids and biological fluids, solids and semisolid bodies by use of a transducer. The invention also relates to a method for continuous detection of changes of density of fluids or solids as well as use of the device.

Abstract: There is provided a signal processing apparatus including a signal processor for processing a signal to be received from or to be transmitted to a vibrator constituting a probe, and a controller for controlling a signal processing parameter of the signal processor to lower a performance of the signal processor when a motion parameter showing a characteristic of a motion of the probe is large.

Abstract: Provided is an ultrasound system configured to detect a flow noise signal at a phantom gate and display a visual indictor representing the detected flow noise signal. The ultrasound system transmits ultrasound signals to an object including a sample volume and receives echo signals from the sample volume and at least one phantom gate. The ultrasound system also generates an ultrasound image based on the received echo signals and displays the generated ultrasound image. Furthermore, the ultrasound system detects a flow noise signal at the at least one phantom gate by using the echo signals and displays a visual indicator representing the detected flow noise signal together with the ultrasound image.

Abstract: The present disclosure relates to a method and apparatus for automatic thoracic organ segmentation. The method includes: receiving three-dimensional (3D) images obtained by a computed tomography (CT) system; processing the 3D images to have the same spatial resolution and matrix size; building a two-stage deep learning framework using convolutional neural networks (CNNs) for organ segmentation; adapting the deep learning framework to be compatible with incomplete training data; improving the CNNs upon arrival of new training data; post-processing the output from the deep learning framework to obtain final organ segmentation.

Abstract: An apparatus is disclosed for thermal therapy in a male prostate patient. The apparatus includes a long tubular element that is to be inserted into a patient's urethra so that a first tip end of it reaches up into the patient's diseased prostate. The elongated portion includes a narrow cylindrical tube within which an ultrasonic array is disposed along the long axis of the cylinder. Fluid is pumped into and out of a treatment zone of said patient as needed to control a temperature of a region in said treatment zone. A motorized driver is used to controllably rotate said elongated portion and the ultrasound array therein about the long axis of the apparatus so as to deliver acoustic energy to said diseased tissue. Various control and monitoring components may be used in conjunction with the present apparatus to design, control, and terminate the therapy.

Abstract: Ultrasound B-mode images are reconstructed directly from transducer channel signals using a convolutional neural network (CNN). The CNN is trained with a dataset including, as inputs, simulated transducer array channel signals containing simulated speckle and, as outputs, corresponding simulated speckle-free B-mode ground truth images. After training, measured real-time RF signals taken directly from an ultrasound transducer array elements prior to summation are input to the CNN and processed by the CNN to generate as output an estimated real-time B-mode image with reduced speckle.

Abstract: The present disclosure relates to a handheld device and an according method for optoacoustic imaging of an object, comprising an irradiation unit for irradiating the object with electromagnetic radiation, for example, light, and a detector unit for detecting acoustic, for example, ultrasonic, waves generated in the object upon irradiation with electromagnetic radiation, wherein the detector unit comprises an array of detector elements. In order to facilitate an acquisition of high-quality tomographic optoacoustic images from different depths within the object at a simple overall design, the handheld device may be provided with a recess, in which the irradiation unit and the array of detector elements are provided, wherein the detector elements are arranged in the recess such that the surface normals of at least a part of the detector elements are directed to a region of interest on or within the object.

Abstract: Systems and methods for assisting the placement of a catheter within a vessel of a patient via an ultrasound imaging system are disclosed. The systems and methods described herein relate to an automatic size comparison tool to enable a clinician to determine, prior to insertion of the catheter, whether a particularly sized catheter will fit within a designated vessel of the patient without violating a user-defined rule setting a maximum percentage of the vessel that may be occupied by the catheter. This in turn ensures that the catheter is properly sized for the vessel in which it is placed, according to user-defined preferences. Though described herein as implemented in connection with an ultrasound imaging system, in other embodiments the system and methods described herein can be included with other devices as well.

Abstract: A Doppler ultrasound instrument (10) includes ultrasound pulse control and data acquisition electronics (12, 24, 26) for acquiring Doppler ultrasound data, an N-channel connector port (14) for simultaneously operatively connecting up to N ultrasound transducer patches (16) where N is an integer equal to or greater than two, and an electronic processor (30) programmed to concurrently determine up to N blood flow velocities corresponding to up to N patches operatively connected to the N channel connector port. The blood flow velocity for each patch may be determined by: determining transducer blood flow velocities for ultrasound transducers (60) of a transducer array of the patch; and determining the blood flow velocity for the patch as a highest determined transducer blood flow velocity or as an aggregation of highest determined transducer blood flow velocities.

Abstract: A biopsy assembly for collecting tissue samples by means of a biopsy needle when introduced in a body cavity. The biopsy assembly comprises an elongated member (101), with a longitudinal axis (102), configured with: a first needle guide (203), arranged to guide a needle in a direction transverse to the longitudinal axis (102), and a second needle guide (204, 303) arranged to guide a needle in a direction along the elongated member (101).

Abstract: The pumping of arterial blood into the cerebral spinal fluid (CSF) of a patient's brain creates cycle pressure undulations in the CSF and the brain itself. Brain injuries can create abnormal changes in this pressure waveform. Accordingly, the disclosed technology includes an ultrasound based device for monitoring this brain movement in the CSF (“pulsatility”) to diagnose and monitor brain injury.

Abstract: A method of diagnosing the occurrence or non-occurrence of a blood vessel blockage or hemorrhage comprises non-invasively applying ultrasound to a location on a patient's body, where the ultrasound is applied in an alternating and pulsed fashion, administering acoustic amplifiers to the patient, monitoring a feedback acoustic response signal of the acoustic amplifiers triggered by the ultrasound, and determining a diagnosis based at least in part on a relationship between an acoustic response signature of the acoustic response signal and a baseline acoustic response signature.

Abstract: A patient data capture and processing system that comprises general programmable medical device (GPMD) and a patient medical device controller (PPS). The patient server is configured to program the function data store of the GPMD, and obtain the data acquired by the GPMD, via the communications connection, wherein the data is stored in patient data records, and wherein the patient server is further configured to extract and output clinically significant events.

Abstract: A system for cardiac treatment includes a monitoring probe having a probe distal end, a magnetic field generator coupled to the probe distal end, a catheter having a catheter distal end, a magnetic sensor coupled to the catheter distal end, and a console. The monitoring probe is configured for insertion into an esophagus of a patient. The catheter is configured for insertion into a heart of a patient. The console is configured to drive the magnetic field generator to emit magnetic fields, to receive signals from the magnetic sensor in response to the magnetic fields, and to estimate respective distances between the catheter distal end and the probe distal end based on the signals.

Abstract: An ultrasound apparatus includes: a display unit configured to display, on an ultrasound image, a measuring device image including a plurality of measuring points which indicate points on the ultrasound image that are to be measured, and an adjusting portion for adjusting the plurality of measuring points; an input unit configured to receive a touch input for changing a position of the adjusting portion; and a controller configured to adjust a position of at least one of the plurality of measuring points based on the changed position of the adjusting portion, and to obtain a measurement value based on positions of the plurality of measuring points including the at least one measuring point, the position of which is adjusted, wherein the plurality of measuring points are disposed apart from the adjusting portion.

Abstract: A method and apparatus for estimating the frequency of a dominant periodic component in an input signal by modelling the input signal using auto-regressive models of several different orders to generate candidate frequencies for the periodic component, generating synthetic sinusoidal signals of each of the candidate frequencies, and calculating the cross-correlation of the synthetic signals with the original signal. The frequency of whichever of the synthetic signals has the highest cross-correlation with the original signal is taken as the estimate of the frequency for the dominant periodic component of the input signal. The method may be applied to any noisy signal which has a suspected periodic component, for example physiological signals such as photoplethysmogram signals, and in the estimation of heart rate and breathing rate from such physiological signals.

Abstract: A clutter reduction effect using adaptive beam forming is uniformly obtained with respect to the entire image even in an imaging condition in which the number of bundled signals is greatly distributed in an ultrasonic image. A received signal processing unit includes a summing unit that bundles the plurality of received signals for a predetermined imaging point or a plurality of signals obtained by processing the received signals, and a weighting unit that obtains a coherence value among the plurality of signals summed in the summing unit, and weights the plurality of signals before being summed in the summing unit or a signal obtained through summing in the summing unit, with a weight corresponding to the coherence value. The weighting unit weights the coherence value nonlinearly in a predetermined direction in the subject, and weights the plurality of signals before being summed in the summing unit or the signal obtained through summing in the summing unit by using the nonlinearly weighted coherence value.

Abstract: The present disclosure provides systems and methods for ultrasound imaging using a modified variable sampling beamforming technique. Unlike conventional methods of variable sampling beamforming, in which in-phase and quadrature samples are obtained for each pixel location, in various example embodiments of the present disclosure, the pixel locations are quadrature-spaced such that for each 5 sample point, an adjacent sample point along an A-line is employed as the quadrature sample. The samples at each array element may be triggered according to the time of flight between a first pixel location and the location of the array element, such that successive samples, corresponding to successive pixel locations along the selected A-line, are obtained such that adjacent samples are spaced by a 10 time interval corresponding to a quarter of an odd number of wavelenghths of the beamformed transmit pulse, and such that only one sample is acquired per pixel.

Abstract: Described herein are devices and methods useful in automating ultrasound imaging. The device include a base coupled with soft robotics, which may be attached to an ultrasound transducer probe in order to robotically manipulate the probe to perform an ultrasound scan. The device has an adjustable structure configured to hold the probe on a walking soft robot. The device can be configured to be attached to, or worn by, the patient. With soft robotic actuation and locomotion, the holder can move and position the probe during a real time ultrasound scanning procedure. Furthermore, the holder may be equipped with sensors to sense and map pressure and location. The position of the holder can be robotically monitored and controlled so as to achieve consistency and reproducibility between ultrasound scans. Due to the wearable nature of the holder, the scans may be conducted while the patient is in motion, thereby providing a portable solution for ultrasonic imaging.

Abstract: According to one embodiment, an ultrasonic diagnostic apparatus comprises plurality of processing circuitry and control circuitry. The control circuitry comprises a plurality of processing circuitry interfaces, a plurality of internal memories, and a control information interface. The plurality of processing circuitry interfaces respectively connected to the plurality of processing circuitry. The plurality of internal memory respectively connected to the plurality of processing circuitry interfaces. The control information interface configured to transfer control information associated with at least reception of the ultrasonic wave to at least one of the plurality of internal memories.

Abstract: A system and method for integrating diagnosis and treatment for internal tissues includes imaging (202) at least a portion of an internal organ of a subject using a first technology capable of differentiating tissue types, and targeting (205) and accessing biopsy sites using images of the first technology fused with images of a second technology capable of real-time image updates. Treatment of a biopsy site is planned (207) using the images of the first technology. Instruments for treating the biopsy site are guided (210) by fusing (208) the images of the first technology with the images of the second technology.

Abstract: If a lesion included in a specification target image is a texture lesion, a probability image calculation unit calculates a probability value indicating a probability that each of a plurality of pixels of the specification target image is included in a lesion area. An output unit calculates, as a candidate area, an area including pixels whose probability values are equal to or larger than a first threshold in a probability image obtained from the probability image calculation unit and, as a modification area, an area including pixels whose probability values are within a certain probability range including the first threshold. An input unit detects an input from a user on a pixel in the modification area. A lesion area specification unit specifies a lesion area on the basis of the probability image, the candidate area, the modification area, and user operation information.

Abstract: An ultrasonic diagnostic imaging system has a thin two dimensional array transducer probe which is taped or belted to a patient to image a target region during radiotherapy. The radiotherapy procedure is conducted based upon planning done based on images of the target region acquired prior to the procedure. The array transducer is operated by an ultrasound system to produce three dimensional images of the target region by electronic beam steering, either during or between fractions of the treatment procedure. The ultrasound images are used to adjust the treatment plan in response to any movement or displacement of the target anatomy during the treatment procedure.

Abstract: The invention relates to an ultrasound system for imaging a volumetric region comprising a region of interest comprising: a probe having an array of CMUT transducers adapted to steer ultrasound beams in a variable frequency range over the volumetric region; a beamformer coupled to the array and adapted to control the ultrasound beam steering and provide ultrasound image data of the volumetric region; a transducer frequency controller coupled to the beamformer and adapted to vary operation frequencies of the CMUT transducers within the frequency range, which frequency controller is arranged to set the operation frequency to a first frequency for the ultrasound beam steered in the volumetric region; an image processor responsive to the ultrasound image data, based on which it is adapted to produce an ultrasound image.

Abstract: Disclosed is an ultrasound diagnostic apparatus. The ultrasound diagnostic apparatus includes a holder implemented to hold a probe; an object sensor for detecting physical changes around the holder; an electromagnetic wave sensor for detecting electromagnetic waves around the holder; and a controller for determining a port name for a probe held in the holder, based on sensing values from the object sensor and electromagnetic wave sensor.

Abstract: A transducer assembly includes: a microelectromechanical systems (MEMS) die including a plurality of piezoelectric elements; a complementary metal-oxide-semiconductor (CMOS) die electrically coupled to the MEMS die by a first plurality of bumps and including at least one circuit for controlling the plurality of piezoelectric elements; and a package secured to the CMOS die by an adhesive layer and electrically connected to the CMOS die.

Abstract: To provide a photoacoustic probe capable of acquiring subject information for reducing generation of artifacts without increasing the number of wires connected to the outside. Provided is a probe including a plurality of ultrasonic transducers, wherein the ultrasonic transducers are divided into a plurality of groups, two adjoining ultrasonic transducers belong to different groups, and the probe includes a group selection unit configured to switch signals of the ultrasonic transducers to be outputtable for each of the groups.

Abstract: Method and systems for of evaluating a mechanical property of a material by applying force to the material sufficient to physically displace a portion of the material, measuring displacement of the material, adaptively adjusting the force when the displacement measured is not within a predetermined range of displacement values, wherein the force is increased or decreased depending upon whether the measured displacement is below or above the predetermined range, respectively, and computing a mechanical property value resultant from the displacement of the material.

Abstract: Methods of treating a subject suffering from a disease or a disorder associated with hyperproliferating cells. The method includes non-invasively administering to the subject ultrasound at a low intensity in a dose effective to selectively prevent the growth of the hyperproliferating cells or to eliminate the hyperproliferating cells in the subject, while substantially not affecting the cell viability of normal cells of the subject. The low intensity is pre-determined to be lower than a cavitational threshold intensity for a selected frequency.

Abstract: A method for imaging includes acquiring surface image data for a target using a first imaging modality. A visual representation of the target based on the surface image data is generated. Internal image data for the target is acquired using a second imaging modality. During acquisition of the internal image data, the visual representation of the target based on the acquired internal image data is updated.

Abstract: Methods, apparatus, systems and articles of manufacture to analyze time series data are disclosed. An example method includes sub sampling time series data collected by a sensor to generate one or more candidate samples of interest within the time series data. Feature vectors are generated for respective ones of the one or more candidate samples of interest. Classification of the feature vectors is attempted based on a model. In response to a classification of one of the feature vectors, the classification is stored in connection with the corresponding candidate sample.

Abstract: Systems and methods are provided for injury characterization including detecting matches of an individual subject's record (such as an athlete's record) with collections of other subjects records, based on serial, longitudinal patterns, for facilitating athlete health and training, preventive and rehabilitation medicine, and risk management in athletics.

Abstract: Systems and methods are provided for indicating recommended settings for data acquisition in a medical scanner. A scan protocol including a first parameter is identified. A first subset of values is determined for the first parameter as a function of the scan protocol. A first plurality of values is displayed for the first parameter with the first subset of values highlighted. A first selection is received of a first selected value for the first parameter. Image data is generated using the first selection.

Abstract: An ultrasound transducer may be driven by a driver circuit having one or more charge pumps and a multi-level inverter. The one or more charge pumps are configured to drive the ultrasound transducer only during output transitions of the inverter.

Abstract: An ultrasound imaging system (100) including a disinfection system is disclosed. The disinfection system may include one or more ultraviolet light sources (115). The UV light sources may be included in a display (105). The disinfection system may be configured to operate when the display is parallel to a control panel (120) of the ultrasound imaging system. The disinfection system may provide indications of the disinfection status of the ultrasound imaging system.

Abstract: An electrophysiology catheter is provided. In one embodiment, the catheter includes an elongate, deformable shaft having a proximal end and a distal end and a basket electrode assembly coupled to the distal end of the shaft. The basket electrode assembly has a proximal end and a distal end and is configured to assume a compressed state and an expanded state. The electrode assembly further includes one or more tubular splines having a plurality of electrodes disposed thereon and a plurality of conductors. Each of the plurality of conductors extends through the tubular spline from a corresponding one of the plurality of electrodes to the proximal end of the basket electrode assembly. The tubular splines are configured to assume a non-planar (e.g., a twisted or helical) shape in the expanded state.

Abstract: Ultrasonic sonothrombolysis systems to produce two acoustic pressure levels of insonation during stroke therapy, mid/high acoustic pressure insonation directed to the site of a blood clot where microbubbles are present to induce microbubble-mediated blood clot lysis, and low acoustic insonation directed to the region surrounding the site of the blood clot where microbubbles are present to stimulate microvascular reperfusion of the surrounding tissue. The systems simultaneously produce blood clot lysis at the site of an occlusion and stimulate reperfusion of tissue affected by the occlusion.

Abstract: A control computer includes a computer memory and a computer processor programmed to execute instructions stored in the memory to perform a lidar calibration test. The instructions include collecting texture data output by a lidar sensor, the texture data representing a detected texture of an interior surface of a first jig disposed about the lidar sensor, comparing the texture data output by the lidar sensor to a known texture of the interior surface of the first jig, determining that the lidar sensor needs to be calibrated as a result of comparing the texture data to the known texture, and calibrating the lidar sensor by uploading updated values for use with the lidar sensor.