Abstract: The present invention relates to an apparatus for treating a living body or tissue with shock waves originating from at least two sources to a focal area on or within said living body or tissue. The apparatus is particularly for treating an illness or fragmenting stones or concretions. The sources of shock waves are at different angles from one another. An objective of the invention is to induce a localized effective shock wave treatment area and at the same time to minimize or abolish the unwanted tissue damage effects outside the treatment area.

Abstract: An apparatus for measuring parameters preparatory to a stent replacement of an aneurytic blood vessel in a patient (26) includes a computed tomography (CT) scanner (10) that acquires image data (28) corresponding to multiple two-dimensional image slices. A reconstruction processor (32) reconstructs a three-dimensional image representation (34) from the image data (28). A tracking processor (40) produces a tracked vessel (92) including at least a centerline (80) and selected vessel boundaries (86). A user interface (44) displays a rendering (242) of the image representation to an associated user (42), measures selected vascular parameters corresponding to the stent parameters (276), and graphically superimposes the measured parameters on the rendering of the image representation (270, 272).

Abstract: A composition for ultrasonic imaging is described having a microbubble population of controlled fragility. The microbubbles comprise an outer shell and a hollow core. The ratio of shell thickness to microbubble diameter is substantially similar across the population of microbubbles. A method of using such composition for imaging a fluid filled cavity, vessel or tissue is described.

Abstract: Apparatus for mapping a surface of a cavity within a body of a subject includes an elongate probe, having a longitudinal axis and including a distal portion adapted for insertion into the cavity. A primary acoustic transducer on the distal portion of the probe is adapted to emit acoustic waves while the probe is in the cavity. A plurality of secondary acoustic transducers, distributed along the longitudinal axis over the distal portion of the probe, are adapted to receive the acoustic waves after reflection of the waves from the surface of the cavity and to generate, responsive to the received waves, electrical signals indicative of times of flight of the waves.

Abstract: In a method for the operation of a magnetic resonance apparatus having a gradient system and a radio-frequency system that, among other things, are utilized for location coding of magnetic resonance signals, magnetic resonance signals from at least parts of a region of an examination subject to be imaged are acquired in a time sequence, and a deformation of the region to be imaged occurring during the time sequence is identified and the location coding is adapted according to the identified deformation.

Abstract: The present invention relates to a method for determining the position of at least one object in a navigation system of co-ordinates, wherein: reference points and/or markers (4) are connected in a defined positional relationship to the object; the position of the object is detected in relation to a detection system of co-ordinates; the position of the reference points (4) is detected in relation to the detection system of co-ordinates; the position of the reference points is detected in relation to a navigation system of co-ordinates; and the position of the object is determined in the navigation system of co-ordinates, from the position of the at least one reference point (4) in the detection system of co-ordinates; as well as to a device for determining the position of an object in a navigation system of co-ordinates.

Abstract: The present invention provides an ultrasonic diagnostic apparatus. The ultrasonic diagnostic apparatus comprises an ultrasonic probe (1) for transmitting ultrasonic pulses into a living body and receiving ultrasonic reflected waves from the living body, a phase-detecting section (5) for detecting each phase of the ultrasonic reflected waves, and a phase-difference detecting section (6) for determining a phase difference in the repetition period of the ultrasonic transmitting/receiving operation according to the detected phase signals.

Abstract: An ultrasonic diagnostic apparatus by which an image having superior space resolution is obtained. The apparatus includes: first means for transmitting an ultrasonic wave, which is continued for at least two cycles, to an object to be inspected, and for detecting an echo signal which is produced by reflection of the transmitted ultrasonic wave from tissue of the object to be inspected to thereby obtain a detection signal; second means for delaying the detection signal by such a time duration corresponding to one cycle of the transmitted ultrasonic wave to thereby obtain a delayed detection signal; and third means for obtaining image information related to the tissue of the object to be inspected based upon a difference between the detection signal and the delayed detection signal.

Abstract: An ultrasonic operation system includes a handpiece having an ultrasonic transducer, which treats a living tissue using ultrasonic oscillations. The system includes a driving signal oscillator for producing a driving signal for driving the ultrasonic transducer and supplying the driving signal to the handpiece; a sweep circuit for sweeping a frequency of the driving signal; a data transfer circuit for transferring start frequency data to the sweep circuit to start sweeping the frequency of the driving signal; a detection circuit for detecting a resonance frequency of the handpiece based on the driving signal of which the frequency has been swept by the sweep circuit; and a chase lock loop (PLL) circuit for locking the frequency of an output current onto the resonance frequency; and, a switch for switching between the PLL circuit and the sweep circuit according to a detection result from the detection circuit.

Abstract: An ultrasonic diagnostic apparatus includes one transmitting coil arranged in the longitudinal direction of an endoscope inserting portion in an ultrasonic endoscope, and another transmitting coil for detecting the position and the direction, which detects the position and the direction of a tomographic plane when forming a tomogram at a distal end portion of an inserting portion by an ultrasonic vibrator. A coil energizing signal is applied to both the transmitting coils so as to generate a magnetic field. The magnetic field is detected by receiving coils. A position and direction calculating circuit detects positional data of the one transmitting coil and positional and directional data of the other transmitting coil. The calculated data is transmitted to an auxiliary-image forming circuit which forms an image of an inserting shape and an auxiliary image indicating the position and the direction of the tomographic plane.

Abstract: The invention comprises a system and method for handling a patient in a tomographic imaging system using a plurality of imaging devices. The imaging devices each have a bore through which a patient is translated during scanning. One or more patient support structures extend from the front of the tomographic imaging system, where the patient is initially placed, through the bores of the system. The patient is translated through the bores of the system and along the patient support structures by an actuator.

Abstract: A method and apparatus is disclosed in which a two-tiered approach is taken to first grade a patient to identify the presence of any suspected stenosis, and then a second step is used to acquire more detailed information to grade the stenosis. The invention includes performing a screening study by acquiring a first MR image having a low resolution to scan a suspected stenosis region. After analyzing the first MR image to identify a suspected stenosis within the suspected stenosis region, a more detailed study is performed by acquiring a second MR image having a higher resolution than the first MR image to scan the identified suspected stenosis. If no lesions, or stenotic vessels, are identified after the first MR image, the second MR image need not be obtained.

Abstract: A three-dimensional (3D) ultrasound imaging system performs receive-focusing at voxels corresponding to pixels of a display device. The system comprises a display device; transducers for transmitting ultrasound signals toward the object and receiving echo signals from a voxel corresponding to a pixel on the display device, wherein the voxel is on a scanning region of the object; an RF volume memory for storing signals from the transducers; a signal processor for processing the stored signals to obtain 3D data sets with respect to the voxel; and an image former for forming the 3D image.

Abstract: The present invention relates generally to systems and methods for assessing blood flow in blood vessels, for assessing vascular health, for conducting clinical trials, for screening therapeutic interventions for adverse effects, and for assessing the effects of risk factors, therapies and substances, including therapeutic substances, on blood vessels, especially cerebral blood vessels, all achieved by measuring various parameters of blood flow in one or more vessels and analyzing the results in a defined matter. The relevant parameters of blood flow include mean flow velocity, systolic acceleration, and pulsatility index. By measuring and analyzing these parameters, one can ascertain the vascular health of a particular vessel, multiple vessels and an individual. Such measurements can also determine whether a substance has an effect, either deleterious or advantageous, on vascular health. In one of many embodiments, the present invention further provides an expert system for achieving the above.

Abstract: An ultrasound image is obtained by subjecting an object containing an ultrasound contrast enhancement agent to a first imaging pulse burst and then to a second release pulse and then to a second imaging pulse to obtain two images and then comparing the two images to obtain an enhanced image.

Abstract: Echogenic medical devices, methods of fabrication and methods of use are disclosed. The device can be adapted to be inserted into a patient. The echogenic construction can be incorporated into the device at the time of fabrication providing acoustic impedance different from that of the surrounding biological tissue or fluid. The medical device is designed for use with an ultrasound imaging system to provide real-time location of the insertion and guidance at the time the device is implanted in a patient, such as in brachytherapy. Following placement of the device the position can be evaluated over time to insure the device remains in proper aligmnent and functional. Furthermore, the device is designed to incorporate a spacer element at one or both ends to provide separation between radioactive elements.

Abstract: Ultrasonic imaging method and apparatus improved to provide image data at a high frame rate and achieve a better resolution. The ultrasonic imaging apparatus includes a transmission side signal processing unit for providing drive signals; an ultrasonic probe for transmitting ultrasonic beams and detecting echoes of the transmitted ultrasonic beams to obtain detection signals; a reception side signal processing unit for amplifying the detection signals and obtaining image data on the measurement target; and a control unit for controlling the transmission side signal processing unit to transmit ultrasonic beams simultaneously in a plurality of directions and controlling the reception side signal processing unit to process the detection signals and form a plurality of receiving focal points with respect to each of the transmitted ultrasonic beams.

Abstract: Apparatus for mapping a surface of a cavity within a body of a subject includes an elongate probe, having a longitudinal axis and including a distal portion adapted for insertion into the cavity. A plurality of acoustic transducers are distributed along the longitudinal axis over the distal portion of the probe, which transducers are adapted to be actuated individually to emit acoustic waves while the probe is in the cavity, and are further adapted to receive the acoustic waves after reflection of the waves from the surface of the cavity and to generate, responsive to the received waves, electrical signals indicative of times of flight of the waves.

Abstract: The control panel of an ultrasound system can be moved laterally from one side of the ultrasound system to the other, enabling an operator to more comfortably operate the ultrasound system while scanning a patient located to the side of the ultrasound system. The control panel locks in its central home position and can be moved linearly to either side of the home position. Detents serve to retain the control panel at different lateral locations. Preferably the control panel can swivel independently of its lateral articulation.

Abstract: A system and method for individually varying the orientation of scan lines in at least two dimensions in an ultrasound scan are disclosed. In one embodiment, the invention includes a system for generating a three-dimensional ultrasound volume scan, comprising a transducer probe having elements arranged in a plurality of dimensions and a system controller capable of generating a scan line apparently emanating from a location other than the geographic center of the transducer probe.