Abstract: Described embodiments include an apparatus that includes an electrical interface and a processor. The processor is configured to receive via the electrical interface, from a plurality of sensors, a first signal that indicates a location of an intrabody tool inside a body of a subject, and a second signal that indicates a phase, of a physiological motion cycle of the subject, at which the first signal was acquired. The processor is further configured to acquire, using a magnetic resonance imaging (MRI) scanner, a set of multiple images at the location indicated by the first signal, over a portion, of a subsequent physiological motion cycle of the subject, that includes the phase indicated by the second signal. Other embodiments are also described.

Abstract: A system and method utilizing thermoacoustic imaging to estimating tissue temperature within a region of interest that includes an object of interest and a reference which are separated by at least one boundary located at least at two boundary locations. The system and method use a thermoacoustic imaging system that includes an adjustable radio frequency (RF) applicator configured to emit RF energy pulses into the tissue region of interest and heat tissue therein and an acoustic receiver configured to receive bipolar acoustic signals generated in response to heating of tissue in the region of interest; and one or more processors that are able to: process received bipolar acoustic generated in the region of interest in response to the RF energy pulses to determine a peak-to-peak amplitude thereof; and calculate a temperature at the at least two boundary locations using the peak-to-peak amplitudes of the bipolar acoustic signals and a distance between the boundary locations.

Abstract: An ultrasound diagnosis apparatus which is connectable to a wireless probe that acquires first data by scanning an object is provided. The ultrasound diagnosis apparatus includes a controller which is configured to recognize an occurrence of a first event, to automatically terminate a first communication connection to the wireless probe via a first communication network, and to control an automatic start of a second communication connection to an external apparatus via the first communication network; and a communicator which is configured to exchange data with the wireless probe and/or with the external apparatus by using the first communication network under the control of the controller.

Abstract: Automatic detection of valve disease from analysis of Doppler waveforms exploiting the echocardiography annotations is provided. In various embodiments, a frame is selected from a medical video. The selected frame depicts a valve of interest. A Doppler envelope is extracted from the selected frame. Based on the frame and the Doppler envelope, one or more measurements indicative of a disease condition are extracted.

Abstract: A method of controlling an analysis of electromagnetic (EM) signal of a human subject. The method comprises positioning an EM transducer unit in front of a skin area above a target intrabody volume of a human subject, the EM transducer unit having at least one EM transducer, a pressure applying unit that applies a variable pressure on the skin area, and a pressure sensor, measuring at least one pressure parameter indicative of the variable pressure using the pressure sensor, capturing EM signal using the at least one EM transducer, and performing an analysis of the EM signal to infer at least one intrabody parameter of the target intrabody volume. The analysis is controlled according to the at least one pressure parameter.

Abstract: An optical imaging method for analyzing an ex vivo tissue sample of a subject is provided. The method includes obtaining the ex vivo tissue sample, preparing the ex vivo tissue sample onto a sample receptacle of an optical imaging system, and emitting excitation light toward the ex vivo tissue sample. The method also includes acquiring imaging data of light emitted by the ex vivo tissue sample in response to the excitation light, analyzing the imaging data to determine whether the ex vivo tissue sample contains pathologic tissue, and generating an output indicating to an operator whether the ex vivo tissue sample contains pathologic tissue.

Abstract: A device and method are described for navigating and positioning a central venous catheter into the venous system using two different modes of location. For example, a peripherally inserted central catheter (“PICC”) may be navigated and positioned within the superior vena cava. A light emitting element is used in the first mode to navigate the PICC to the superior vena cava. To improve visibility during navigation, the light emitted from the light emitting element may include a narrow range of wavelengths that generally matches the wavelengths of light that are transmissable through a light absorbing material defining the wall of the catheter. A conductive medium is used in the second mode to monitor an ECG signal in order to position the PICC in the superior vena cava. One advantage of this procedure is that X-ray visualization can be eliminated to reduce the danger associated with X-rays.

Abstract: A blood pressure measurement apparatus includes circuitry configured to: detect a pulse of a subject, and obtain a photoplethysmography signal; and obtain estimated blood pressure of the subject based on the photoplethysmography signal. The circuitry receives parameter information, generates time information based on the photoplethysmography signal, applies a blood pressure estimation equation to the time information and the parameter information to calculate the estimated blood pressure, receives basic blood pressure information for the subject and the time information, and performs learning processing of applying a learning operational equation to statistical time information, which is obtained by performing statistical processing on the time information, and the basic blood pressure information to update the parameter information.

Abstract: A system and method for noncontact ultrasound imagery capable of generating images in a manner that is safer for eyes and skin is provided. A photoacoustic excitation source may be employed to direct light signals with wavelengths of 1400-1600 nanometers into the patient to generate acoustic disturbances that induce propagating photoacoustic waves. The acoustic disturbances may be translated in defined directions to cause coherent summation of the propagating photoacoustic waves and, thereby, generate a resultant acoustic and/or elastic wave to probe structures within the patient. Vibrations created by the scatter of the resultant wave are detected at the surface of the patient and ultrasound images of the structures within the patient may be generated. Detection of the vibrations may be performed using a laser vibrometer. The excitation and detection systems may be used separately or in combination. Ultrasound images can be generated without physically contacting the patient.

Abstract: An animal, specimen, or imaging phantom is imaged in precise increments over at least 360 degrees. The animal, specimen, or imaging phantom is supported within a subject holder. The subject holder has an elongated portion or tube for holding securely the animal, specimen or imaging phantom. The subject holder is connected to an actuator motor driver. The actuator motor driver causes the subject holder to rotate at the precise increments, and an image of the animal, specimen, or imaging phantom is captured at each increment. The subject holder limits movement of the subject being imaged at each increment.

Abstract: A computer-implemented method of visualizing blood flow through a patient using magnetic resonance imaging (MRI) includes receiving an image of the portal venous system of the patient's liver at a full field of view. A reduced field of view is defined which encompasses the portal venous system of the patient's liver and excludes extraneous anatomy in the full field of view. A navigator area is defined in the full field of view and outside of the reduced field of view. Transmit channels are used to selectively excite the reduced field of view and the navigator area throughout a cardiac cycle of the patient. Measurement data is acquired in response to the selective excitation. The acquired data is used to generate time-resolved 3D datasets. Additionally, a 3D visualization of blood flow though the portal venous system is generated based on the time-resolved 3D datasets.

Abstract: Various approaches for reducing microbubble interference with ultrasound waves transmitted from multiple transducer elements and traversing tissue onto a target region include measuring microbubbles in high-throughput areas of ultrasound exposure and reducing the amount of microbubbles using the ultrasound waves.

Abstract: A device and method for ablating tissue is disclosed comprising the steps of acquiring an anatomical image of a patient, correlating the image to the patient, guiding an ablating member within the patient while tracking the position of the ablating member in the patient, positioning the ablating member in a desired position to ablate tissue, emitting ablating energy from the ablating member to form an ablated tissue area and removing the ablating member from the patient.

Abstract: Superconducting quantum interference device (SQUID) sensor module and a magnetoencephalography (MEG) measuring apparatus. The SQUID sensor module includes a fixed block having one end fixed to the sensor-mounted helmet, a bobbin having one end combined with the other end of the fixed block and having a groove in which a pick-up coil is wound, a bobbin fixing or attachment structure or material fixed to the other end of the fixed block via a through-hole formed in the center of the bobbin, a SQUID printed circuit board (PCB) disposed one an upper side surface of the bobbin and including a SQUID sensor, and a signal line connection PCB inserted into an outer circumferential surface of the fixed block and adapted to transmit a signal detected in the SQUID sensor to an external circuit.

Abstract: Provided are an ultrasound probe and an operating method of the ultrasound probe which can select a power transmission channel and/or a wireless power transmission mode that are most appropriate in an environment in which power transmission channels exist. The operating method of the ultrasound probe includes operations of obtaining a plurality of pieces of information about power transmission channels; displaying a power transmission channel list, based on the plurality of pieces of information about the power transmission channels; selecting a power transmission channel from the power transmission channel list; and receiving wireless power that is transmitted via the selected power transmission channel.

Abstract: An object information acquiring apparatus according to the present invention includes: an acoustic wave detecting element which detects an acoustic wave propagating from an object and which outputs an acoustic signal; a reference element which receives an input of electrical noise corresponding to electrical noise input to the acoustic wave detecting element and which outputs a reference signal; a noise reducer which reduces a component derived from the electrical noise by subtracting the reference signal from the acoustic signal; and a processor which generates image data representing characteristic information of the object using the acoustic signal in which the component derived from the electrical noise has been reduced.

Abstract: A method and system are disclosed for a compact, inexpensive ultrasound system using an off-the-shelf personal digital assistant (PDA) device interfacing to a hand-held probe assembly through a standard digital interface. The hand-held probe assembly comprises a detachable transducer head attached to a beamforming module that performs digital beamforming. The PDA runs Windows applications and displays menus and images to a user. The PDA also runs ultrasound data processing software to support a plurality of imaging modes. An internal battery is provided in the PDA to power the system. The transducer head is detachable from the beamforming module.

Abstract: An electromagnetic tracking system including a patient support element and an electromagnetic field generator. The patient support element is superposed relative to the electromagnetic field generator, and the electromagnetic field generator is selectively moveable relative to the patient support element.

Abstract: An ultrasound imaging scanner includes an ultrasound input device (104), of a plurality of ultrasound input devices, that includes an array of transducer elements, which transmits an ultrasound signal and receives an echo signal produced in response thereto; and a multi-client ultrasound imaging data processing system (106) that includes processing resources which are shared by the plurality of ultrasound input devices, wherein the processing resources include a plurality of ultrasound signal processing units, each including a plurality of ultrasound signal processing blocks configured to processes echo signals, and wherein the multi-client ultrasound imaging data system temporarily allocates at least one ultrasound signal processing block to process the received echo signal of the ultrasound input device, generating an image indicative thereof.

Abstract: A catheter system includes an elongate flexible catheter and a support structure mounted on a proximal portion of the elongate flexible catheter. The support structure includes a first alignment feature configured to mate with a first sensor such that the first sensor is maintained parallel to a longitudinal axis of the support structure, and a second alignment feature configured to mate with a second sensor such that the second sensor is maintained parallel to the longitudinal axis of the support structure and such that the second sensor is fixed relative to the first sensor in at least one degree of freedom.