Abstract: The volume of fluid flow within a vessel (VE) is measured by an ultrasound system. Ultrasound waves backscattered from the fluid within the vessel generate data from which velocity values representing components of velocity (Vx and Vy) of the fluid flow in the scan plane (IP) are calculated. Grayscale data is correlated and the rate of decorrelation (D) of the data is calculated. The volume flow of the fluid (F) is estimated in response to the velocity signals and the rate of decorrelation (D).

Abstract: A Picture Archiving and Communications System (PACS) having multi-level image data processing is provided. The system includes imaging a patient with an imaging modality to generate raw digital image data and then sending the raw image data to an acquisition workstation. The acquisition workstation then performs a first level of image data processing to form partially processed raw image data with regard to a predetermined subset of the set of control parameters to form a partially processed image. The subset of control parameters may comprise frequency control parameters or contrast control parameters, for example. The partially processed image may then be sent to an external connection, stored in a database in the PACS, or sent to a display workstation for a second level of image data processing to complete the image processing and display the image.

Abstract: An ultrasound system operating on a personal computer architecture comprising multiple processors controlled to operate in parallel to share ultrasound operations of the system. The multiple processors are controlled by software to share the operations associated with system setup, system control, scanning, data acquisition, beamforming, user interface service, signal processing, and scan conversion. The ultrasound system utilizes management software which divides operations associated with each function (such as signal processing and scan conversion) into parallel sub-operations or tasks. Each task is assigned by the operating system to a CPU. Any of the CPUs may be capable of performing any of the tasks. The CPUs operate in parallel to carry out the assigned tasks. Once all of the CPUs have completed the assigned tasks, the system may serially advance to the next ultrasound function.

Abstract: A method for processing images in a Picture Archiving and Communications System (PACS) is provided. The method includes imaging a patient with an imaging modality to generate raw digital image data and then sending the raw image data to an acquisition workstation. The acquisition workstation then partially processes the raw image data with regard to a predetermined subset of the set of control parameters to form a partially processed image. The subset of control parameters may comprise frequency control parameters or contrast control parameters, for example. The partially processed image may then be sent to an external connection, stored in a database in the PACS, or sent to a display workstation for complete processing and display. A partially processed image that has been stored in a database in the PACS may be retrieved and sent to a display workstation for complete processing and display.

Abstract: A magnetic resonance (MR) imaging system equipped with real-time imaging capability and methods of interactively prescribing geometry to excitation profiles of structure of interest, are disclosed herein. The MR imaging system includes a graphical user interface for displaying and receiving prescription commands, a display screen for displaying MR images and the graphical user interface, and an input device for inputting prescription commands. The MR imaging system allows an operator to prescribe the boundary geometry of a subsequent imaging volume and to rapidly view the prescribed boundary imaging sections prior to committing to the subsequent imaging volume acquisition. The MR imaging system also allows the operator to retrieve boundary geometry of a previously prescribed imaging volume and to rapidly view the imaging sections corresponding to the retrieved boundary geometry prior to initiating the image volume acquisition.

Abstract: An ultrasound system and method for calculation and display of tissue deformation parameters, such as tissue Doppler and strain rate imaging, are disclosed. An ultrasound acquisition technique that allows a high frame rate in tissue velocity imaging or strain rate imaging is employed. With this acquisition technique the same ultrasound pulses are used for the tissue image and the Doppler based image. The number of beams used in Doppler subframes are increased to allow tissue visualization based only on Doppler subframes. A sliding window technique is used for processing.

Abstract: A mount (50) is adapted to be move along a table (20) without disturbing a patient (P) lying on a pad (130) on the table. The mount includes lips (52 and 72) which are joined by a cross member (90) which passes under the table (20).

Abstract: An electronic video camera apparatus is provided for focusing light rays from object plane proximate image intensifier of a medical x-ray imaging system onto an image plane proximate a light sensor. The electronic video camera includes a lens system located between the object and image planes to focus light rays from the object plane onto the image plane. The light rays at the object plane are representative of a patient image. An optical filter is located between the object and image planes and partially blocks light rays passing there through. The optical filter includes at least first and second filter regions having different opacity. The first and second filter regions are alignable with the lens system at different times to block differing first and second amounts of light rays, respectively, associated with differing first and second x-ray amounts transmitted at different times.

Abstract: A patient table, which is movable in at least one of a vertical direction and a tiltable direction. The patient table comprises: a base; a patient support surface; a support mechanism connected to the base and the support mechanism moving the patient support surface in at least one of a vertical direction and a tiltable direction; and a telescopic cover enclosing the support mechanism, the telescopic cover expanding and constructing with movement of the support mechanism.

Abstract: In order to reduce bias associated with conventional ECG analysis, the present invention provides a method and apparatus to improve diagnosis of acute cardiac syndromes (ACS), such as acute myocardial infarction and acute cardiac ischemia (unstable angina), in specified groups of patients using ECG signals and automatic detection analysis. Specific criteria are developed and utilized based on a prespecified group selection for the particular patient. After identifying group membership for the particular patient, ECG data are acquired from a patient experiencing ACS symptoms. Known criteria typically used for assessing ACS are then modified for the particular group membership. Such criteria significantly reduce the bias found in a baseline group for which the known criteria were established.

Abstract: A computed tomography system includes an x-ray source, an x-ray detector aligned with the x-ray source, a processor coupled to the x-ray detector, and a display for displaying reconstructed images. The processor is programmed to perform at least one of: generating a partially reconstructed image for display on the display; dynamically reformatting images for display on the display; communicating the partially reconstructed image, the reformatted images, or data associated with the system to a remote facility.

Abstract: A method for displaying a region of interest graphic on an imaging system includes: (a) establishing a communication connection over a network between the imaging system and a remote facility; (b) displaying an image frame, the image frame having a reference point; (c) displaying a region of interest graphic on the image frame at a depth determined relative to the reference point, the region of interest graphic having a bottom width, a top width, a height, and an angle between a projection of a first edge line and a projection of a second edge line; (d) changing the depth of the region of interest; and (e) changing the top width and the angle of the region of interest graphic as a function of the change in depth, while maintaining the height and the bottom width of the region of interest graphic substantially unchanged. At least one of steps (b) through (e) is done remotely over the communication connection.

Abstract: A system for performing image-based diagnosis of a machine includes a database containing a plurality of historical images taken from a plurality of machines, a diagnostic unit configured to diagnose a new artifact image from the machine and to communicate historical and non-historical images or data associated with the system to a remote facility. The plurality of historical images include a plurality of ideal images generated from the plurality of machines using all possible machine settings and a plurality of artifact images generated from the plurality of machines, each of the artifact images having known faults associated therewith and a corresponding corrective action for repairing the faults. The diagnostic unit includes a diagnostic image processor and a diagnostic fault isolator.

Abstract: An ultrasound color flow imaging system is programmed to optimize display images on a display monitor (18) by automatically adjusting a threshold. B-mode data corresponding to valid color data is subjected to statistical analysis including mean and standard deviation (S3). The threshold is computed according to mean plus k (standard deviation), where k preferably is based on a linear regression equation.

Abstract: A preferred embodiment of the present invention provides a method and apparatus for optimized dual energy image acquisition. The system comprises a dual energy medical imaging system, a detector, a user interface, an image segmentation module, a characterization module, and a control module. The method comprises obtaining an image from a first exposure of a patient and segmenting the image into an anatomy of interest. The method further comprises characterizing the segmented anatomy in terms of a set of patient parameters and optimizing a second exposure of the segmented anatomy based upon said anatomy and the characterization of the anatomy. A resulting anatomy image is obtained from analysis of the first and second exposures.

Abstract: An internal imaging probe including an expandable scanhead for improving the positioning of an imaging element mounted on the scanhead. The imaging probe is introduced into the esophagus of a patient via the patient's mouth. Once, the imaging probe is introduced, the imaging probe is positioned to a point where an internal structure of the patient is within the direction of view of an imaging element, such as a transducer, located on the scanhead. Once positioned, the scanhead is expanded either by inflation, or via a moving extensor located within the scanhead. The scanhead is then expanded until the imaging element, such as a transducer, achieves close and uniform contact with the esophageal wall of the patient thereby providing accurate imaging of the internal structure. Further, expanding the scanhead while the scanhead is within the esophagus of the patient minimizes the risks of damage to the esophageal wall that are associated with prior art probes.

Abstract: A method for prescribing geometry of an imaging volume of a structure of interest positioned in a magnetic resonance (MR) imaging system.

Abstract: A system employs a tracker and a set of substantially non-shadowing point markers, arranged in a fixed pattern or set in a fluoroscope calibration fixture that is imaged in each shot. The fixture is preferably affixed to the image detector of the fluoroscope, and tracking elements secured with respect to the fixture and at least one of a tool and the patient, provide respective position data irrespective of movement. A marker detection module identifies markers imaged in each shot, and a processor applies the known marker positions to model the projection geometry, e.g., camera axis and focus, for the shot and, together with the tracked tool position, form a corrected tool navigation image. In one embodiment an inverting distortion correction converts the tracked or actual location of the tool and displays the tool on the fluoroscopic image to guide the surgeon in tool navigation.

Abstract: An x-ray system (10) include a digital detector (400) that defines two regions: a first region (404) suitable for generating data useful for creating a patient x-ray image and a second region (406) less suitable for generating such data than the first region. A source (20) transmits x-rays through a phantom (420) located between the source and the second region (406) so that the detector (400) generates test data in the second region. A processor (302) measures at least one parameter in response to the test data and stores a value of the parameter at one point of time. The processor compares the first value with a second value of the one parameter generated at a later second point in time. The processor also generates a result signal representing the results of the comparison.

Abstract: A method for converting a digital image to an analog-simulative film-like digital image includes (a.) obtaining digital image input values for a number of pixels, each pixel having a digital image input value X, wherein the range of input values for all pixels defines the input dynamic range; (b.) for each pixel, determining an analog-simulative film-like output value Y = ∑ i = 1 M ⁢   ⁢ A i ⁢   ⁢ X Pi + Bi wherein Ai, pi, and Bi are real numbers, and M is an integer value greater than or equal to 1; and (c.) communicating the analog-simulative film-like digital image or data associated therewith to a remote facility over a network.