Abstract: A two-dimensional array transducer probe is used to image regions of the body that are acoustically obstructed from conventional view by objects such as the lungs or ribs. The probe is located against the body at an acoustic window which provides acceptable ultrasonic transmissivity between the transducer array and the body. While maintaining the probe at its acoustic window, an image plane location is manipulated by adjusting the beam steering directions. The image plane can be tilted in the elevation direction, moved laterally, and/or rotated about a center axis to position the image plane so that the obstructed anatomy is effectively imaged for diagnosis.

Abstract: An electromagnetic sensor capable of maintaining its accuracy through temperature cycling is provided. The sensor element material of an electromagnetic sensor is covered by an encapsulant having substantially similar thermal expansion values as the sensor element material. By matching the thermal expansion values of the components, changes in component orientation may be minimized during temperature cycling thus reducing the need for recalibration of the sensor assembly. In one embodiment the encapsulant is doped with a ceramic material or glass microspheres to achieve a thermal expansion coefficient similar to the thermal expansion coefficient of the copper sensor element material.

Abstract: An ultrasonic probe for detecting ultrasonic waves in a two-dimensional manner without necessity of electric-wiring works to a large number of very fine elements and without increasing of crosstalk and electric impedance. The ultrasonic probe is equipped with an ultrasonic transmitting function and can be provided in low cost. The ultrasonic probe includes an ultrasonic detecting element having a reception plane capable of receiving ultrasonic waves, for modulating light on the basis of ultrasonic waves applied to respective positions of the reception plane, and at least one ultrasonic transmitting element for transmitting ultrasonic waves.

Abstract: Systems and methods for obtaining images of body organs or other tissue for each of their multiple characterizing aspects, and for classifying different tissue types within the images according to their characterizing aspects, are disclosed herein. The tissue may be irradiated with an ultrasonic signal, and an interaction signal received in return. Sinogram data may be constructed from the received interaction signal, and multiple characterizing data extracted therefrom. The multiple characterizing data representing multiple characterizing aspects may then be matched to tissue type within a database containing information correlating characterizing multi-aspect data with tissue type. Images of the tissue may then be presented with identifiers associating tissue portions with their matched tissue types.

Abstract: An ultrasound imaging system including an electromagnetically protected ultrasound TEE probe, a display for displaying ultrasound images, a housing including a transducer connector including at least one connection and a computer for processing electrical signals representative of received ultrasound echoes. The TEE probe includes a probe housing including an imaging sensor, an outer acoustic lens, a cable interconnect and an internal metal shield which surrounds the sensor and cable interconnect, and a cable including electrical conductors and electromagnetic cable shielding, the electrical conductors electrically connected to the cable interconnect at a first end, and the electrical conductors and the cable shielding are electrically connected to a transducer connector at a second end.

Abstract: Apparatuses and methods for measuring a velocity component of tissue and blood flow within a human body may generate sample data by transmitting ultrasound signals to and sampling echo signals reflected from the human body, generate frequency distribution data containing the velocity component of tissue and blood flow, extract the frequency distribution data corresponding to the velocity component of tissue flow from the frequency distribution data, and display the extracted frequency distribution data. The apparatuses and methods may also input the frequency distribution data containing the velocity component of tissue and blood flow, eliminate a direct-current component of the frequency distribution data, extract the velocity component of blood flow from the frequency distribution data, determine a maximum value of the extracted velocity component of blood flow, decide a gain level, and multiply the frequency distribution data by the decided gain level.

Abstract: An ultrasound imaging guidewire, that is inserted into a patient's body. The guidewire has a static central core and an imaging guidewire body comprising an acoustical scanning device. The acoustical scanning device can be rotated to obtain 360 degree acoustical images of a site of interest in the patients body. Furthermore, the imaging guidewire includes a connector that permits the imaging guidewire body to be disengaged from the static central core tip so that the imaging guidewire body can be axially translated to obtain multi-position imaging. The imaging guidewire body is axially translated without losing the original guidewire positioning because the static central core maintains its position in the patient's body.

Abstract: A medical examination and/or treatment system has an X-ray image exposure system with a radiation source, a radiation receiver as well as a control and processing device that controls them, a catheter system with a catheter with at least one element in the catheter tip that generates a magnetic field and a device for generating an external magnetic field for guiding the movement of the catheter introduced into a patient by interaction with the magnetic field generated by the element at the catheter tip, as well as an ultrasound image exposure system having a device integrated in the catheter tip for generating and for receiving ultrasound and having a control and processing device that controls this device.

Abstract: A system and method for the in situ discrimination of healthy and diseased tissue. A fiberoptic based probe is employed to direct ultraviolet illumination onto a tissue specimen and to collect the fluorescent response radiation. The response radiation is observed at three selected wavelengths, one of which corresponds to an isosbestic point. In one example, the isosbestic point occurs at about 431 nm. The intensities of the observed signals are normalized using the 431 nm intensity. A score is determined using the ratios in a discriminant analysis. The tissue under examination is resected or not, based on the diagnosis of disease or health, according to the outcome of the discriminant analysis.

Abstract: A method and apparatus for enabling a biopsy needle to be observed in a three-dimensional ultrasound diagnostic system using an interventional ultrasound system. The apparatus comprises an ultrasound transducer, a three-dimensional image-forming section, a section for extracting a target object, a location-calculating section, a display section, and a controller. The method comprises the steps of acquiring a two-dimensional ultrasound image of a subject; generating a three-dimensional volume image based on the two-dimensional ultrasound image; segmenting a target image, which corresponds to a target object within the subject, from the three-dimensional volume image; displaying a guide line of the biopsy guide on the segmented target image; extracting the segmented target image; acquiring information on a location of the biopsy needle by reference to the segmented target image; calculating an error based on the information; and displaying a guiding status of the biopsy needle based on the calculated error.

Abstract: An ultrasonic apparatus and method are described in which a volumetric region of the body is imaged by biplane images. One biplane image has a fixed planar orientation to the transducer, and the plane of the other biplane image can be varied in relation to the fixed reference image. In a preferred embodiment one image can be rotated relative to the other, and can be tilted relative to the other. An image orientation icon is shown on the display screen together with the two biplane images depicting the relative orientation of the two planar images.

Abstract: An apparatus and method for guiding a needle in conjunction with a biopsy using a medical imaging device, where a non-reusable needle guide, which is relatively inexpensive which grasps the sheathed bracket firm, and holds the same in a set position based upon a bullet-nose lock.

Abstract: An ultrasonic diagnostic imaging system is described in which two planes of a volumetric region which are in different elevation planes are scanned in real time. In one embodiment the two planes are scanned in the sector format with a common apex, causing corresponding depths of the two images to be separated by the same distance in elevation. In another embodiment one image plane has a fixed orientation with respect to the imaging probe and the location of the other image plane can be adjusted by the user.

Abstract: A plurality of planes are scanned in real time to provide a display of images in the scanned planes in real time. The displayed images are accompanied by an orientation icon which depicts the relative inclination of the displayed planes. The icon includes a perspective view of the outline of one of the images as seen from the scanning transducer, with the aspect ratio of the outline varying to provide a visual depiction of the instantaneous inclination of the image planes. The icon may also include a numerical indication of the relative inclination and an indication of the left-right orientation of the images relative to the scanning transducer.

Abstract: A puncturing needle guide includes a plate-like body whose width diminishes gradually from one end thereof to the other end thereof; a plurality of holes which are formed in an end surface of the puncturing needle guide at one end thereof and through which a puncturing needle can be passed; a single hole which is formed in an end surface of the puncturing needle guide at the other end thereof and through which the puncturing needle can be passed; a hollow that is formed inside the plate-like body and that allows the plurality of holes and the single hole to communicate with one another; and an attachment which is formed along an edge of the plate-like body in a width direction thereof and by which the plate-like body is attached to an ultrasonic probe.

Abstract: A therapeutic agent is incorporated into microbubbles of a contrast agent, and the microbubbles containing the therapeutic agent are delivered to a region of interest in a patient. An ultrasound image of the region of interest is generated by an ultrasound imaging system, and ultrasound energy for destroying the microbubbles of the contrast agent is transmitted to the region of interest. Parameter data that is representative of activation of the therapeutic agent in the region of interest is acquired, and a parameter display is generated. One or more parameters of the ultrasound energy applied to the region of interest for activating the therapeutic agent may be adjusted, either manually based on the parameter display or automatically based on acquired parameter data. In one embodiment, the parameter display is indicative of a parameter associated with the ultrasound energy transmitted to the region of interest.

Abstract: Planar waves are transmitted to a target object with an angle of wave propagation corresponding to a center position of a receive subaperture. The echo signals reflected from the target object are received by the receive subaperture, stored in a receive pattern memory and dynamic-focused. The dynamic-focused signals are then combined to form at least one beam pattern to produce an ultrasound image.

Abstract: A customized surgical fixture (400) is formed by scanning a body to form a three-dimensional image of the body, and then identifying in the image a target (310) in the body, and mounting points or structures (330) on the body. A model, such as a computer solid model, of the fixture (400) is specified in accordance with the locations of the target (310) and mounting structures (330) or points. The fixture (400) is formed in accordance with the model of the fixture (400), for example using a rapid prototyping and tooling machine. When attached to the body, the fixture (400) can be used to guide a surgical instrument (610) into the body, for example, by using a mechanical guide (600) attached to the fixture (400) or using a remote sensing device (1300) that tracks the relative position of the customized fixture (400) and the surgical instrument.

Abstract: An apparatus and method for obtaining data for diagnosing the condition of a living body without harming living tissue using an ultrahigh frequency (UHF) signal includes a signal transmitter, a signal receiver, and a signal processor. Signal transmitter generates a UHF signal and radiates the UHF signal at a first of two acupuncture points of a living body. The signal receiver receives a UHF signal emitted from a second acupuncture point, detects and outputs the magnitude of the received UHF signal.

Abstract: An apparatus and method for detecting the highest velocity of fluid flow with in a volume having multiple sources of fluid flow with different velocities. There are multiple pairs of receiving transducers arranged about a region wherein each transducer in a pair is positioned on the same axis with respect to the region. A transmitting transducer is positioned at the region to provide an output frequency signal, which frequency signal is transmitted to the fluid flow area volume. This causes Doppler shifted frequency signals to be reflected, with the Doppler shift being a function of the fluid flow velocity. Each of the receiving transducers receive the Doppler shifted signals. Signal processing means are responsive to the Doppler shifted signals and the original transmitted output frequency signal to process those signals to provide a velocity signal for each pair of transducers. One then selects the maximum velocity signal obtained from the pair.