Abstract: Systems and methods for ultrasound imaging using an inertial reference unit are disclosed. In one embodiment, an ultrasound imaging system includes an ultrasound unit configured to ultrasonically scan at least one plane within a region of interest in a subject and generate imaging information from the scan. An inertial reference unit is provided that detects relative positions of the ultrasound unit as the ultrasound unit scans a plurality of plane. A processing unit is configured to receive the imaging information and the corresponding detected position and is operable to generate images of the region of interest.

Abstract: An ultrasound system and method to measure an organ wall weight and mass. When the organ is a bladder, a bladder weight (UEBW) is determined using three-dimensional ultrasound imaging that is acquired using a hand-held or machine controlled ultrasound transceiver. The infravesical region of the bladder is delineated on this 3D data set to enable the calculation of urine volume and the bladder surface area. The outer anterior wall of the bladder is delineated to enable the calculation of the bladder wall thickness (BWT). The UEBW is calculated as a product of the bladder surface area, the bladder wall thickness, and the bladder wall specific gravity.

Abstract: Ultrasound imaging systems and methods are disclosed. In one embodiment, an ultrasongraphy method includes creating a database that is representative of a tissue, a fluid, or a cavity of a body, and transmitting ultrasound pulses into a region-of-interest in a patient. Echoes are received from the region of interest, and based upon the received echoes, compiling an ultrasonic pattern of the region-of-interest is compiled. The pattern is processed by comparing the region-of-interest patterns to the pattern information stored in the database. A composition within the region-of-interest of the patient is then determined.

Abstract: A transducer device including a housing that encloses a three-layer piezoelectric crystal assembly in contact with a backing block to produce more finely resolved electric and acoustic pulses. The three-layer assembly includes a piezoelectric crystal flanked by a front and back matching layer with a backing block in contact with the back matching layer. In concert with the backing block, the front and back matching layers cooperatively interact to produce more highly resolved acoustic and electrical pulses than by transducers equipped with two-layer crystal assemblies.

Abstract: An ultrasound transceiver scans an organ and processes the echogenic signals to produce three-dimensional, two-dimensional, and one-dimensional information of the organ. The 3-D, 2-D, and 1-D information is utilized to determine the thickness, surface area, volume, and mass of the organ wall.

Abstract: A data collection device obtains three-dimensional ultrasound scan information of a portion of the abdominal aorta. A plurality of transducer elements are arranged to provide overlapping coverage. The data collection device is first positioned over the aorta by an operator; a one-dimensional scan with a Doppler sound generator operating on the blood flow is used to verify proper initial positioning of the device. Three-dimensional scan information is then obtained and converted from plane coordinates into spherical coordinates such that the resulting converted scan line planes are perpendicular to the aorta. The information in each converted scan line plane is then processed to determine the boundaries of the aorta, from which diameter information is then calculated. Diameter measurements over a given region of the aorta can be used to determine and monitor an aneurysm in the aorta.

Abstract: An ultrasound transceiver scans a bladder in a three dimensional array to measure the thickness and surface area of the bladder to determine bladder mass. The bladder wall thickness and masses may be determined for anterior, posterior, and lateral locations of the bladder.

Abstract: A data collection device obtains three-dimensional ultrasound scan information of a portion of the abdominal aorta. A plurality of transducer elements are arranged to provide overlapping coverage. The data collection device is first positioned over the aorta by an operator; a one-dimensional scan with a Doppler sound generator operating on the blood flow is used to verify proper initial positioning of the device. Three-dimensional scan information is then obtained and converted from plane coordinates into spherical coordinates such that the resulting converted scan line planes are perpendicular to the aorta. The information in each converted scan line plane is then processed to determine the boundaries of the aorta, from which diameter information is then calculated. Diameter measurements over a given region of the aorta can be used to determine and monitor an aneurysm in the aorta.