Abstract: According to some embodiments of the invention, an ultrasound imaging system having real-time tracking and image registration includes a fiducial-marker system comprising an ultrasound transmitter structured to provide a localized ultrasound pulse at an optically observable localized spot on a body of interest.

Abstract: A system and method is provided for solving the AX=XB calibration problem. A calibration method is presented to determine the unknown X in the AX=XB calibration problem. Sensor data is filtered, such that data without the desired screw theory invariants are discarded. The correspondence between A and B is then computed, either through a probabilistic Batch method that treats the data streams as probability density functions, or by formulating the data streams as a time-evolving differential equation which allows for online calibration of the device. Also, a calibration phantom and software is also provided. The phantom is an extension of known Z-fiducial phantoms, in which the Z-fiducials are oriented based on consideration of imaging physics. An additional phantom is designed that does not utilize rods within the phantom to perform the calibration.

Abstract: A system for thermal treatment or ablation of tissue includes an ultrasonic thermal ablation probe, an ultrasonic three-dimensional imaging probe that captures an image from radio frequency image data obtained before the radio frequency image data is processed, a control system for multi-axis control of the imaging probe's position, and an ultrasonic feedback mechanism that measures ultrasound echo strain to estimate heat-induced structural changes of an area surrounding the ultrasonic thermal ablation probe, from the image. The ultrasonic thermal ablation probe is either an interstitial ablator inserted into tissue, a natural cavity or a vessel to emit high intensity ultrasound energy to deposit thermal dose, or an external applicator that emits a directional high intensity ultrasound energy to deposit thermal dose via surface contact with tissue. The control system adjusts power levels of the ultrasonic thermal ablation probe based on the estimated heat-induced structural changes.

Abstract: A virtual rigid body optical tracking system includes a virtual rigid body generator for projecting a virtual rigid body, wherein the virtual rigid body forms a pattern of light on a surface. The virtual rigid body optical tracking system includes an optical detection system for detecting the pattern of light, and a data processing system in communication with the optical detection system. The data processing system is configured to determine a position of the virtual rigid body generator based on the detected pattern of light.

Abstract: A synthetic aperture ultrasound system includes an ultrasound probe, and an ultrasound signal processor configured to communicate with the ultrasound probe to receive phase and amplitude information from a plurality of ultrasonic echo signals from a corresponding plurality of ultrasound pulses. The synthetic aperture ultrasound system also includes a positioning system configured to communicate with the ultrasound signal processor to provide probe position information. The positioning system is configured to determine a first position and a second position of the ultrasound probe relative to a region of interest. The ultrasound signal processor is further configured to coherently sum, utilizing the probe position information, at least one of the plurality of ultrasonic echo signals from the first position with at least one of the plurality of ultrasonic echo signals from the second position to provide a synthetic aperture that is larger than a physical aperture of the ultrasound probe.

Abstract: An interventional system with real-time ablation thermal dose monitoring includes an interventional tool, an ultrasound transmitter at least one of attached to or integral with the interventional tool, an ultrasound receiver configured to receive ultrasound signals from the ultrasound transmitter after at least one of transmission through or reflection from a region of tissue while under an ablation procedure and to provide detection signals, and a signal processing system configured to communicate with the ultrasound receiver to receive the detection signals and to calculate, based on the detections signals, a thermal dose delivered to the region of tissue in real time during the ablation procedure.

Abstract: According to some embodiments of the invention, a robot-assisted ultrasound system includes a first ultrasound probe, a robot comprising a manipulator arm having a tool end, and a second ultrasound probe attached to the tool end of the manipulator arm. The robot-assisted ultrasound system further includes a robot control system configured to control at least one of a position or a pose of the second ultrasound probe based on a contemporaneous position and pose of the first ultrasound probe, and an ultrasound processing and display system configured to communicate with at least one of the first and second ultrasound probes to receive and display an ultrasound image based on the first and second ultrasound probes acting in conjunction with each other.

Abstract: Three dimensional heat-induced echo-strain imaging is a potentially useful tool for monitoring the formation of thermal lesions during ablative therapy. Heat-induced echo-strain, known as thermal strain, is due to the changes in the speed of propagating ultrasound signals and to tissue expansion during heat deposition. This paper presents a complete system for targeting and intraoperative monitoring of thermal ablation by high intensity focused acoustic applicators. A special software interface has been developed to enable motor motion control of 3D mechanical probes and rapid acquisition of 3D-RF data (ultrasound raw data after the beam-forming unit). Ex-vivo phantom and tissue studies were performed in a controlled laboratory environment. While B-mode ultrasound does not clearly identify the development of either necrotic lesions or the deposited thermal dose, the proposed 3D echo-strain imaging can visualize these changes, demonstrating agreement with temperature sensor readings and gross-pathology.

Abstract: An intraoperative registration and tracking system includes an optical source configured to illuminate tissue intraoperatively with electromagnetic radiation at a substantially localized spot so as to provide a photoacoustic source at the substantially localize spot, an optical imaging system configured to form an optical image of at least a portion of the tissue and to detect and determine a position of the substantially localized spot in the optical image, an ultrasound imaging system configured to form an ultrasound image of at least a portion of the tissue and to detect and determine a position of the substantially localized spot in the ultrasound image, and a registration system configured to determine a coordinate transformation that registers the optical image with the ultrasound image based at least partially on a correspondence of the spot in the optical image with the spot in the ultrasound image.

Abstract: A method of processing ultrasound data includes receiving ultrasound data for a first ultrasound image, the first ultrasound image being represented as a first set of discrete pixels corresponding to positions of a region of interest; receiving ultrasound data for a second ultrasound image, the second ultrasound image being represented as a second set of discrete pixels corresponding to positions of the region of interest; generating a displacement map by minimizing a cost function using a dynamic programming procedure that identifies each of the first set of discrete pixels with a corresponding one of the second set of discrete pixels; refining the displacement map to obtain intermediate displacement values corresponding to positions between the discrete pixels based on minimizing a local approximation to the cost function; and calculating a physical property of the region of interest based on the displacement map.

Abstract: A closed-loop ultrasound system includes an ultrasound receiver, an ultrasound transmitter at least one of integral with or at a predetermined position relative to the ultrasound receiver, and a trigger circuit configured to receive detection signals from the ultrasound receiver and to provide trigger signals to the ultrasound transmitter in response to received detection signals. The ultrasound transmitter is configured to transmit ultrasound energy in response to the trigger signals.

Abstract: An augmentation device for an imaging system has a bracket structured to be attachable to an imaging component, and a projector attached to the bracket. The projector is arranged and configured to project an image onto a surface in conjunction with imaging by the imaging system. A system for image-guided surgery has an imaging system, and a projector configured to project an image or pattern onto a region of interest during imaging by the imaging system. A capsule imaging device has an imaging system, and a local sensor system. The local sensor system pro-vides information to reconstruct positions of the capsule endoscope free from external monitoring equipment.

Abstract: A method of processing ultrasound data includes receiving ultrasound data for a first ultrasound image, the first ultrasound image being represented as a first set of discrete pixels corresponding to positions of a region of interest; receiving ultrasound data for a second ultrasound image, the second ultrasound image being represented as a second set of discrete pixels corresponding to positions of the region of interest; generating a displacement map by minimizing a cost function using a dynamic programming procedure that identifies each of the first set of discrete pixels with a corresponding one of the second set of discrete pixels; refining the displacement map to obtain intermediate displacement values corresponding to positions between the discrete pixels based on minimizing a local approximation to the cost function; and calculating a physical property of the region of interest based on the displacement map.

Abstract: A robotic 5D ultrasound system and method, for use in a computer integrated surgical system, wherein 3D ultrasonic image data is integrated over time with strain (i.e., elasticity) image data. By integrating the ultrasound image data and the strain image data, the present invention is capable of accurately identifying a target tissue in surrounding tissue; segmenting, monitoring and tracking the target tissue during the surgical procedure; and facilitating proper planning and execution of the surgical procedure, even where the surgical environment is noisy and the target tissue is isoechoic.

Abstract: A robotic 5D ultrasound system and method, for use in a computer integrated surgical system, wherein 3D ultrasonic image data is integrated over time with strain (i.e., elasticity) image data. By integrating the ultrasound image data and the strain image data, the present invention is capable of accurately identifying a target tissue in surrounding tissue; segmenting, monitoring and tracking the target tissue during the surgical procedure; and facilitating proper planning and execution of the surgical procedure, even where the surgical environment is noisy and the target tissue is isoechoic.

Abstract: Disclosed is a system and method for intra-operatively spatially calibrating an ultrasound probe. The method includes determining the relative changes in ultrasound images of a phantom, or high-contrast feature points within a target volume, for three different ultrasound positions. Spatially calibrating the ultrasound probe includes measuring the change in position and orientation of the probe and computing a calibration matrix based on the measured changes in probe position and orientation and the estimated changes in position and orientation of the phantom.

Abstract: Disclosed is a system and method for intra-operatively spatially calibrating an ultrasound probe. The method includes determining the relative changes in ultrasound images of a phantom, or high-contrast feature points within a target volume, for three different ultrasound positions. Spatially calibrating the ultrasound probe includes measuring the change in position and orientation of the probe and computing a calibration matrix based on the measured changes in probe position and orientation and the estimated changes in position and orientation of the phantom.