Abstract: An ultrasound device having a transducer propagating and receiving sound signals to/from a blood vessel of a person being examined for caisson's disease where the blood vessel is at above normal surface atmospheric pressure and a controller determining onset of the caisson's disease by analyzing the received sound signals from the transducer to determine presence of naturally occurring bubbles in the blood vessel during decompression of the blood vessel.

Abstract: A system and method for fundamental real-time imaging of the non-linear response of tissue perfused with a contrast agent are disclosed. An image with increased sensitivity to non-linear responses can be achieved by detecting the ultrasound response at the fundamental frequency from tissue perfused with a contrast agent and excited by multiple excitation levels. The responses detected from the multiple excitation levels may be gain corrected in an amount corresponding to the difference in magnitude of the excitation levels, then mathematically combined. The mathematical manipulation serves to remove linear responses to the fundamental excitation from the detected image. An ultrasonic contrast agent and tissue imaging system can be implemented with a transducer, first and second transmitters, a receiver, a control system, a processing system and a display.

Abstract: Systems and methods for enhanced color-flow imaging of contrast-agent perfused blood vessels and other tissues within a patient's body are disclosed. The method generally comprises, introducing one or more contrast agents into the body, power-modulating transmit pulses into the body, receiving echoes from the body, processing the received echoes to reduce tissue-generated echoes and echoes from stationary contrast agent, using a color-flow processor to generate a color-encoded display responsive to contrast-agent motion. The method may be implemented by a system with a an excitation-signal source, a transducer, an ultrasound-processing system having multiple image processors including a color-flow processor, as well as, a clutter filter, and an arbiter, and a display-processing system.

Abstract: Systems and methods for enhanced color-flow imaging of contrast-agent perfused blood vessels and other tissues within a patient's body are disclosed. The method generally comprises, introducing one or more contrast agents into the body, power-modulating transmit pulses into the body, receiving echoes from the body, processing the received echoes to reduce tissue-generated echoes and echoes from stationary contrast agent, using a color-flow processor to generate a color-encoded display responsive to contrast-agent motion. The method may be implemented by a system with a an excitation-signal source, a transducer, an ultrasound-processing system having multiple image processors including a color-flow processor, as well as, a clutter filter, and an arbiter, and a display-processing system.

Abstract: An apparatus and method of imaging contrast agents within a patient's body. The apparatus includes an imaging system transmitting at multiple frequencies to elicit a response from the contrast agent at corresponding multiple frequencies, forms images corresponding to each frequency, and the combines the formed images.

Abstract: A system and method for synchronized persistence with ultrasonic harmonic imaging of both tissue and tissue perfused with a contrast agent are disclosed. The ultrasonic harmonic imaging system comprises a frame memory, a frame processor, a persistence actuator, and a persistence controller. In a preferred embodiment, the persistence actuator disables persistence filtering in response to contrast agent destructive ultrasonic transmissions. A method for observing an ultrasonic response of a contrast agent may be performed by: introducing a contrast agent into tissue targeted for imaging; insonifying the tissue with a first ultrasound transmit signal suited to observe the contrast agent and the tissue; modifying a transmit signal parameter to destroy a substantial portion of the contrast agent; disabling persistence filtering while the modified transmit signal is actuated; and enabling persistence filtering while observing the re-perfusion of the tissue.

Abstract: Ultrasonic imaging to receive a signal from contrast agent microbubbles in arterioles of a myocardium, without being masked by a signal from microbubbles in capillaries of the myocardium. For example, high power ultrasonic energy is emitted to destroy microbubbles in the arterioles and capillaries. A time delay passes from the destruction. The time delay is sufficiently long to allow the arterioles to refill with microbubbles and sufficiently short so that the capillaries do not completely refill with microbubbles. Ultrasonic imaging is then performed to receive a signal between harmonics from the microbubbles refilled in the arterioles. Various other destructive and non-destructive imaging techniques are disclosed.

Abstract: The present invention relates to a] A device for producing an image of a body part into which a contrasting agent has been introduced, the device including an image detecting device modifying the contrasting agent to provide a modified image, and a processor acquiring and processing the modified image so as to create an image which represents a rate of flow of blood or other fluid in the body part. The device may be an ultrasound imaging device or may be a magnetic resonance imaging device.

Abstract: A system and method for fundamental real-time imaging of the non-linear response of tissue perfused with a contrast agent are disclosed. An image with increased sensitivity to non-linear responses can be achieved by detecting the ultrasound response at the fundamental frequency from tissue perfused with a contrast agent and excited by multiple excitation levels. The responses detected from the multiple excitation levels may be gain corrected in an amount corresponding to the difference in magnitude of the excitation levels, then mathematically combined. The mathematical manipulation serves to remove linear responses to the fundamental excitation from the detected image. An ultrasonic contrast agent and tissue imaging system can be implemented with a transducer, first and second transmitters, a receiver, a control system, a processing system and a display.

Abstract: The method of the invention controls an ultrasound system to image a microbubble contrast agent in a region of fluid flow and/or a region of tissue that is perfused by blood or other fluid. A transducer transmits ultrasound acoustic signals having a fundamental frequency f and receives echoes resulting from interaction of the ultrasound signals with both tissue and the microbubble contrast agent. A transmitter controls the transducer to transmit ultrasound signals at a sufficient power level to destroy the microbubble contrast agent. A receiver processes the echoes and selectively extracts signal components that exhibit a noninteger multiple of the fundamental frequency f of the transmitted acoustic signal. The system then produces images, principally from signal components including those that exhibit the noninteger multiple of the fundamental frequency f.

Abstract: An apparatus and method of imaging contrast agents within a patient's body. The apparatus includes an imaging system transmitting at multiple frequencies to elicit a response from the contrast agent at corresponding multiple frequencies, forms images corresponding to each frequency, and the combines the formed images.

Abstract: An ultrasound imaging system comprising an ultrasound transducer, an ultrasound imaging device incompatible with the transducer and a transducer adapter including an adapter-transducer connector to connect to a transducer connector of the ultrasound transducer, a system connector to connect to an ultrasound connector of the ultrasound imaging device, and an interface to provide compatible electrical information signals to/from the ultrasound transducer from/to the ultrasound imaging device via the connectors.

Abstract: A system and method for fundamental real-time imaging of the non-linear response of tissue perfused with a contrast agent are disclosed. An image with increased sensitivity to non-linear responses can be achieved by detecting the ultrasound response at the fundamental frequency from tissue perfused with a contrast agent and excited by multiple excitation levels. The responses detected from the multiple excitation levels may be gain corrected in an amount corresponding to the difference in magnitude of the excitation levels, then mathematically combined. The mathematical manipulation serves to remove linear responses to the fumdamental excitation from the detected image. An ultrasonic contrast agent and tissue imaging system can be implemented with a transducer, first and second transmitters, a receiver, a control system, a processing system and a display.

Abstract: A portable ultrasound diagnostic device dynamically collecting diagnostic data from a patient and, once the portable ultrasound diagnostic device determines that collecting the diagnostic data is complete, the portable ultrasound diagnostic device transmits the diagnostic data using a communication channel to a person at another location to analyze the diagnostic data.

Abstract: The present disclosure relates to a method for imaging contrast agents within a patient's body. The method generally comprises, receiving echoed signals from the body, processing the received data to correct for motion effects, processing the received data to suppress tissue response, and imaging the contrast agents.

Abstract: A method for processing ultrasound signal samples obtains enhanced images of a body structure through use of both harmonic and fundamental image processing. The method includes the steps of first obtaining a first plurality of signal samples from sensed backscatter signals that fall within a range of frequencies about a fundamental frequency of the transmitted ultrasound signal. Next, a second plurality of signal samples are obtained from backscatter signals that fall within a range of frequencies about a harmonic of a transmitted ultrasound signal. Control values are then derived from at least one of the first plurality of signal samples or the second plurality of signal samples. Those control values are then utilized to control the processing of the other of the signal samples to derive an improved ultrasound image. In a preferred embodiment, the control values are derived from the signal samples which result from sensed harmonic backscatter signals.

Abstract: An ultrasound system with a transducer that transmits ultrasound signals based on a plurality of parameters in response to a control device that, upon activation in a first imaging mode, adjusts at least one of the parameters to cause the transducer to output a modified waveform based on the first imaging mode, for example, to output a signal adapted to disrupt contrast agent while in a lower power imaging mode or to output a signal adapted for continuous low power viewing when in a triggered mode. Subsequently, the control device readjusts the parameters so as to cause the transducer to output a waveform adapted to the first imaging mode.

Abstract: The method of the invention controls an ultrasound system to identify a boundary between a tissue region and a blood-filled region that lies within an ROI. The method initially administers a contrast agent to the region of interest and then transmits first and second ultrasound beams at a different power levels into the ROI. Signal returns from the first and second beams are processed to derive first and second digital values, respectively. It has been determined that, under certain circumstances, a phase change of echo returns occurs at the boundary between tissue and blood-containing contrast agent. Detection of the phase change enables precise identification of the boundary, based upon the time segment in which the phase change is detected. Accordingly, time segment values of the first and second stored digital values are then phase-compared to enable determination of a boundary location between the tissue region and the blood-filled region by detection of the phase change.

Abstract: The method of the invention controls an ultrasound system to image a microbubble contrast agent in a region of fluid flow. A transducer is caused to transmit ultrasound signals and to receive echoes resulting from interaction of the ultrasound signals with both tissue and microbubbles. A transmitter enables the transducer to transmit the ultrasound signals at a plurality of power levels. A receiver selectively extracts signal components from the echo signals that fall within a determined bandwidth, and is controlled to alter the determined bandwidth (or the center frequency thereof) in accordance with which of the power levels is transmitted.

Abstract: The method of the invention controls an ultrasound system to identify a boundary between a tissue region and a blood-filled region that lies within an ROI. The method initially administers a contrast agent to the region of interest and then transmits first and second ultrasound beams at a different power levels into the ROI. Signal returns from the first and second beams are processed to derive first and second digital values, respectively. It has been determined that, under certain circumstances, a phase change of echo returns occurs at the boundary between tissue and blood-containing contrast agent. Detection of the phase change enables precise identification of the boundary, based upon the time segment in which the phase change is detected. Accordingly, time segment values of the first and second stored digital values are then phase-compared to enable determination of a boundary location between the tissue region and the blood-filled region by detection of the phase change.