Abstract: A method includes, while an operator of an elongated probe, having proximal and distal ends, manipulates the proximal end so as to move the distal end within a body of a patient, automatically measuring a cumulative angle of rotation that is applied by the operator to the proximal end. An indication of the cumulative angle of rotation is presented to the operator.

Abstract: A magnetic resonance imaging (MRI) system includes at least one controller configured to first acquire at least MRI locator image data for different portions of patient anatomy at each of different imaging stations for a defined multi-station locator sequence. An operator may interface with a respectively corresponding displayed locator image for each imaging station to set diagnostic scan sequence parameters for subsequent diagnostic MRI scans of corresponding portions of patient anatomy. Diagnostic MRI scan data is automatically acquired at each of the imaging stations in a multi-station diagnostic scan sequence that, if desired, can be seamlessly continued without operator interruption once begun.

Abstract: A dosimeter measures radiation dosage to a subject during a magnetic resonance imaging guided radiation therapy session. The dosimeter includes an outer surface configured to receive a surface of the subject, and discrete cells. Each of the discrete cells is filled with a magnetic resonance radiation dosimeter.

Abstract: Techniques for temperature measurement and correction in long-term MR thermometry utilize a known temperature distribution in an MR imaging area as a baseline for absolute temperature measurement. Phase shifts that arise from magnetic field drifts are detected in one or more portions of the MR imaging area, facilitating correction of temperature measurements in an area of interest.

Abstract: The invention relates to methods and systems to optically analyze samples such as tissue based on speckle patterns of microscopic motion, such as Brownian motion.

Abstract: Ultrasound data is simulated using magnetic resonance (MR) elastography. MR elastography provides tissue characteristic information, such as elastic modulus, velocity, or stiffness. This tissue characteristic information indicates a density or viscosity of the tissue, allowing simulation of ultrasound data with MR acquired data. The same MR imaging system may be used to acquire the MR elastography and pre-operative anatomy information. The actual ultrasound information may be registered with simulated ultrasound information for registration of the actual ultrasound information with the MR anatomy information.

Abstract: In a method and apparatus to acquire a measurement data set of a breathing examination subject by magnetic resonance, the measurement data set is acquired in multiple shots each composed of a number of k-space trajectories (views), with the number Nv of views per shot being selected. The number of shots is determined in order to completely fill k-space to be scanned. The views of the shots are associated with sectors in k-space, with approximately the same number of views in each sector, and with all views in a sector have a similar distance from the k-space center. A respective view of each sector is associated with a respective one of the shots, corresponding to the orientation of the respective shot. The views that are associated with the same sector and different shots respectively assume the same time position within the shot.

Abstract: An ultrasonic system useful for providing imaging, therapy and temperature monitoring generally comprises an acoustic transducer assembly configured to enable the ultrasound system to perform the imaging, therapy and temperature monitoring functions. The acoustic transducer assembly comprises a single transducer that is operatively connected to an imaging subsystem, a therapy subsystem and a temperature monitoring subsystem. The ultrasound system may also include a display for imaging and temperature monitoring functions. Additionally, the acoustic transducer assembly can be configured to provide three-dimensional imaging, temperature monitoring or therapeutic heating through the use of adaptive algorithms and/or rotational or translational movement. Moreover, a plurality of the exemplary single transducers can be provided to facilitate enhanced treatment capabilities.

Abstract: A method of triggering an imaging process includes obtaining breathing signals, analyzing the breathing signals to identify a non-periodicity in a subject's breathing, and generating a signal to cause an imaging process to begin in response to the identified non-periodicity. A computer product having a set of instructions stored in a non-transitory medium, wherein an execution of the instructions causes a method to be performed, the method includes obtaining breathing signals, analyzing the breathing signals to identify a non-periodicity in a subject's breathing, and generating a signal to cause an imaging process to begin in response to the identified non-periodicity. A system for triggering an imaging process includes a processor that is configured for obtaining breathing signals, analyzing the breathing signals to identify a non-periodicity in a subject's breathing, and generating a signal to cause an imaging process to begin in response to the identified non-periodicity.

Abstract: A method for assisting a physician track a surgical device in a body organ of a subject during a procedure includes fluoroscopic based registration, and tracking. An initial registration step includes receiving a 3D image data of a subject in a first body position, receiving a real time fluoroscopy image data, and estimating a deformation model or field to match points in the real time fluoro image with a corresponding point in the 3D model. A tracking step includes computing the 3D location of the surgical device based on a reference mark present on the surgical device, and displaying the surgical device and the 3D model of the body organ in a fused arrangement.

Abstract: A multimodal fiducial marker (10) for registration of data is disclosed. The multimodal fiducial marker (10) generally comprises a first portion (12) made from at least one radiopaque material and a second portion (14) made from a porous material capable of absorbing at least one radioactive material. The second portion (14) at least partially surrounds the first portion (12).

Abstract: A system and associated method provide tissue perfusion monitoring in a patient. A laser Doppler unit is provided including a coherent laser light source and a photodetector. A processor is configured to receive a signal from the photodetector and determine a tissue perfusion measurement from a Doppler-shifted component of the photodetector signal. A wireless communication circuit transmits the tissue perfusion measurement. A power source provides power to the laser Doppler unit, the processor and the communication circuit. A wireless housing encloses the laser Doppler unit, the processor, the power source and the communication circuit.

Abstract: There is provided an information processing apparatus including an eardrum recognition unit configured to recognize a position of an eardrum based on image information regarding the eardrum, a temperature measurement unit configured to acquire a temperature within an external ear canal including the eardrum, and a temperature processing unit configured to determine a temperature of the eardrum based on a recognition result of the eardrum recognition unit and a measured temperature of the temperature measurement unit.

Abstract: For generating a three-dimensional magnetic resonance image of a respirating examination subject, the respiration of the examination subject is divided into a number of predefined clusters. Based on a measured respiratory position of the examination subject, one of these clusters is selected. The scanned k-space range is divided into a number of data acquisition shots which, by means of a particular k-space trajectory, each fill a number of k-space lines. The different shots are acquired for the different clusters until all shots of the measurement data set are assigned together to at least two adjacent clusters. The magnetic resonance image is reconstructed from those shots that are assigned to at least two adjacent clusters.

Abstract: Systems and methods for generating MRI images of the lungs and/or airways of a subject using a medical grade gas mixture comprises between about 20-79% inert perfluorinated gas and oxygen gas. The images are generated using acquired 19F magnetic resonance image (MRI) signal data associated with the perfluorinated gas and oxygen mixture.

Abstract: This document discusses, among other things, brain stimulation models, systems, devices, and methods, such as for deep brain stimulation (DBS) or other electrical stimulation. In an example, a target volume of activation (VOA) can be received, a test VOA can be simulated, and at least one of a target electrode location or parameter can be provide using a relationship between the target VOA and the test VOA.

Abstract: A system and method for identifying the location of a medical device within a patient's body may be used to localize the fossa ovalis for trans-septal procedures. The systems and methods measure light reflected by tissues encountered by an optical array. An optical array detects characteristic wavelengths of tissues that are different distances from the optical array. The reflectance of different wavelengths of light at different distances from an optical array may be used to identify the types of tissue encountered, including oxygenated blood in the left atrium as detected from the right atrium through the fossa ovalis.

Abstract: Medical devices with novel spark gap electrode designs, able to control manually or automatically the electrodes gap are provided. These devices are used to generate a shock wave created by the rapid expansion and collapse of a plasma bubble that is formed between two spark gap electrodes placed in a special liquid medium, when a high differential voltage (kV) is applied to the electrodes. The resulting shock wave impacts a reflector to direct the energy into the body of an animal or a human toward the desired treatment location. This electro-hydraulic principle to create acoustic shock waves as a method of treatment is in use in the medical (lithotripsy, orthopedic use, wound treatment, burns, post-operative treatment, pain treatment, diagnosis, skin and organ transplantation supporting devices, arteriosclerosis treatment), cosmetic (treatment of scars and cellulite) and veterinary (treatment of musculoskeletal disorders) fields.

Abstract: A SPECT diagnostic method of performing myocardial perfusion imaging on a patient by administering a rest radiotracer to the patient while the patient is at rest; then when the rest radiotracer is fixed in a heart of the patient, scanning the heart to obtain rest heart pumping ability information; scanning the heart of the patient to obtain a rest perfusion image; administering a stressing agent to the patient to place the patient's heart under stress; scanning the heart of the patient to obtain stress heart pumping ability information; then administering a stress radiotracer while the heart of the patient is under stress; then when the stress radiotracer is fixed in the heart, scanning the heart to obtain a stress perfusion image.

Abstract: An ECU-prep scan is used to set an optimum time phase in both systole and diastole of the heart. At each of the different time phases, an imaging scan is started to acquire a plurality of sets of echo data. An artery/vein visually separated blood flow image is produced from the echo data. The imaging scan uses a half-Fourier technique, for example. This provides high-quality blood flow images with shorter scan time, without injecting a contrast medium. Additionally, with a readout gradient pulse applied substantially parallel with a direction of slowly flowing blood, a scan is performed in synchronism with an optimally determined cardiac time phase. The readout gradient pulse has a dephasing pulse for enhancing differences in a flow void effect depending on blood flow velocities. This enables slow-speed flows, such as blood flows in the inferior limb, to be depicted without fail.