Abstract: In magnetic resonance imaging (MRI), the powerful magnetic fields can interfere with, damage, cause premature failure in, and attract certain non-MR safe instruments. Electromagnetic ally sensitive components are eliminated in favor of MR safe components, such as ceramic piezoelectric components and bi-metallic components. Instruments that previously had to be kept a safe distance away from the main magnet (12), e.g., beyond the 5 Gauss line, while a patient was being scanned are now allowed near the patient without fear of damage to the instrument (40) or danger to the patient and medical staff or the MRI device (10).

Abstract: Methods and computer-readable mediums are provided for obtaining an optimally gated medical image. For example, in one embodiment, a method is provided that acquires medical images in list mode. The method also acquires a respiration correlated signal S(t). Thereafter, a final upper strain threshold value and a final lower strain threshold value pair that has a narrowest interval are selected. The medical images are synchronized with the respiration correlated signal S(t). The synchronized images and signal are used to create an optimally gated medical image. In various embodiments, the disclosed optimal gating can be utilized in PET systems and in other embodiments the disclosed optimal gating can be utilized in SPECT systems. In yet other embodiments, the optimally gated images can be matched to MRI systems and in still other embodiments, the optimally gated images can be matched to CT systems.

Abstract: Embodiments of a system and method for detecting a leading stroke risk indicator using low-cost, non-contact visual computing methods are generally described herein. In some embodiments, a video camera is arranged to capture a video of a face of a subject to be evaluated for having a stroke risk indicator. A memory is provided for storing data. A processor is coupled to the memory and is arranged to analyze processed image data associated with the video of the face of the subject captured by the video camera. The processor is further arranged to determine whether the processed image data exhibits a leading indicator for carotid artery stenosis.

Abstract: Medical devices utilizing shock waves with spark gap electrodes that include fluid holes into the respective electrode cores.

Abstract: The present invention includes an apparatus having an elongated probe with proximal and distal ends and a sensor coupled to the elongated probe and configured to generate signals used for determining location and orientation coordinates of the elongated probe. The apparatus further includes a processor operatively connected to the sensor, and being configured to measure a cumulative angle of rotation that is applied by an operator to the proximal end of the probe while the operator manipulates the proximal end so as to move the distal end within a body of a patient. The apparatus also includes an output device operatively connected to the processor, and configured to present an indication of the cumulative angle of rotation to the operator.

Abstract: What is disclosed is a video system and method that accounts for differences in imaging characteristics of differing video systems used to acquire video of respective regions of interest of a subject being monitored for a desired physiological function. In one embodiment, video is captured using N video imaging devices, where N?2, of respective regions of interest of a subject being monitored for a desired physiological function (i.e., a respiratory or cardiac function). Each video imaging device is different but has complimentary imaging characteristics. A reliability factor f is determined for each of the devices in a manner more fully disclosed herein. A time-series signal is generated from each of the videos. Each time-series signal is weighted by each respective reliability factor and combined to obtain a composite signal. A physiological signal can be then extracted from the composite signal. The processed physiological signal corresponds to the desired physiological function.

Abstract: A visualization apparatus for the vein according to the present disclosure includes a near-infrared ray irradiating unit for irradiating near-infrared rays below the skin of a target area, an infrared camera unit for photographing the target area, an image processing unit for receiving and processing image information of a portion below the skin of the target area, photographed by the infrared camera unit, and providing the processed image information to a display device, and a display device located near the target area to display the image information provided from the image processing unit.

Abstract: A shock wave applicator includes a reflector and a movable shockwave-generating electrode disposed in the reflector at a first focal point. The reflector is at least a portion of an ellipsoidal shape having a long and small axis with the first focal point and a second focal point on the long axis, and the reflector terminates at an edge defining a membrane-covered aperture on a plane intersecting the small axis and coincident with the second focal point.

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

Abstract: Provided is a medical system including a first capsule type medical device, and a second capsule type medical device. The first and second capsule type medical devices operate in cooperation with each other in a body.

Abstract: An MRI system is provided that includes a physiological sensor used for gating the MRI system and an MRI control terminal wirelessly connected to the sensor. The physiological sensor is used to monitor a physiological parameter of a user, such as pressure pulse, and communicate data regarding the monitored physiological parameter to the MRI control terminal. The MRI control terminal processes the data received from the physiological sensor and determines whether a triggering condition on the data is met. When it is determined that the triggering condition is met, the MRI control terminal initiates the acquisition of a data set. The acquisition of the data set involves initiating a pre-programmed pulse sequence and acquiring RF signals emitted from the patient's tissue as a result of the execution of the pre-programmed pulse sequence.

Abstract: Active MRI compatible interventional devices, such as catheters, include at least one RF antenna so that they are visible under MRI analysis. However, metallic structures within intravascular devices may heat up significantly during interventional MRI procedures due to eddy current formation over the conductive transmission lines. The electrical field coupling that occurs between interventional devices and RF signals depend on the position and orientation of interventional device within the bore and the insertion length of the interventional device. The system detects an induced current signal during RF transmission phase and selectively adjusts the impedance value associated with the interventional device by using a varactor and integrated circuit components in such a manner that the currents induced in the interventional device are below a threshold current level, thereby controlling current levels and heating in the interventional device.

Abstract: The present invention generally relates to forward imaging devices for imaging the inside of a vessel and associated methods. The invention can involve an elongated body configured to fit within the vessel of a lumen and at least one imaging sensor located on the elongated body configured to image an object in a forward direction.

Abstract: In a methods for elastography in a defined region of an examined person, a radio-frequency pulse is radiated to manipulate a transverse magnetization in the defined region and at least one additional radio-frequency pulse with a spatial selectivity of the amplitude is radiated to generate shear waves in the defined region. A magnetic resonance signal from the defined region is detected and a determination of a value describing the tissue elasticity in the defined region is made based on the magnetic resonance signal.

Abstract: Methods, systems and computer readable storage medium for retrieving mental images of faces from the human brain. An exemplary embodiment includes a method for retrieving mental images of faces from a human brain, the method including generating an image on a screen, measuring brain activity data from a brain scanner, varying characteristics of the image on the screen, detecting changes in the brain activity data measured from the brain scanner, and generating a final image on the screen, the final image being related to a subjectively described mental image.

Abstract: A nuclear medicine diagnostic apparatus includes a support unit for supporting an inspection object from front, an opening for receiving a breast of the inspection object supported by the support unit, a detector ring opposed to the inspection object across a supporting surface of the support unit for detecting radiation generated from the breast, a chest mat provided around the opening formed in the support unit for supporting the chest of the inspection object, and an outer mat provided outward of the chest mat for supporting the inspection object. The chest mat is formed of a material having a greater sagging rate than the outer mat.

Abstract: A method is disclosed for performing a combined magnetic resonance/positron emission tomography scan of an examination object in an MR/PET system. An embodiment of the method entails acquiring first magnetic resonance data using a first readout gradient field. The first readout gradient field is chosen such that, at a location of the field of view of the magnetic resonance system, a distortion caused by a nonlinearity of the first readout gradient field and a distortion caused by a B0 field inhomogeneity substantially cancel each other out. First magnetic resonance images for planning the combined magnetic resonance/positron emission tomography session and determining an attenuation correction map for a positron emission tomography scan are determined on the basis of the first magnetic resonance data. Positron emission data and second magnetic resonance data are acquired using a second readout gradient field.

Abstract: The present invention relates to methods for differentiating a blood vessel from a nonvascular tissue during a minimally invasive surgery using a device. A device may be any penetration sensor device, such as a dilator sensor device, a hollow needle sensor device, or a trocar sensor device, which penetrates the skin and subcutaneous layers to reach a target location inside the body. The penetration sensor device includes a sensor probe which can make optical measurements to determine various parameters of the tissue at the tip of the sensor probe. These parameters may include an optical signal level returned from tissue contacting the tip of the sensor probe, an oxygen saturation level of the tissue, a total hemoglobin concentration, a blood flow, and a pulse. Based on these parameters, the presence or absence of a blood vessel at the tip of the penetration sensor device can be determined while the device travels towards the target location for surgery.

Abstract: A processor-controlled, energy-based therapy apparatus includes a device configured to provide therapeutic energy to a patient and a processor that controls the output of the device. The output of the device is based on output profiles programmed into the processor. The output profiles include a therapeutic energy output profile and a ramp-up energy profile. The therapeutic energy output profile includes a desired target energy level and a therapeutic duration for controlling the output of the device during a therapeutic period. The ramp-up energy output profile includes an initial treatment energy level and a ramp-up duration for controlling the output of the device during a ramp-up period. The energy output specified by the ramp-up energy output profile incrementally increases over the ramp-up duration as a function of the desired target energy level and the ramp-up duration.

Abstract: Method for influencing and/or detecting magnetic particles in a field of view. Selection coils/magnets generate a magnetic selection field and drive coils generate a magnetic drive field for moving a field-free point along a predetermined trajectory through the field of view, changing the magnetization of the magnetic material locally. The drive field comprises a time-dependent oscillating drive field current per drive field coil having one or more individual oscillating frequencies and one or more individual current amplitudes and being generated by a corresponding drive field voltage generated by a superposition of a number of drive field voltage components including a drive field voltage component per drive field coil, wherein a drive field voltage component corresponding to a drive field coil comprises one or more sub-components, each having an individual voltage amplitude and having the same individual oscillating frequency as the respective drive field current of said particular drive field coil.