Abstract: Determining location and orientation of a hand-held surgical tool is provided. One embodiment captures image data that includes images of a first detectable target on the hand-held surgical tool and a second detectable target on a patient. Location and orientation or the first detectable target in a 3D space is determined based on the image data. Current location and orientation of the hand-held surgical tool in the 3D space determined based on the determined location and orientation of the first detectable target and based on retrieved model data representing the hand-held surgical tool. Location of the second detectable target in the 3D space is determined based on the image data. Then, a location of the patient's tissue in the 3D space relative to the location and orientation of the hand-held surgical tool is determined based on the determined location of the patient's second detectable target.

Abstract: A system and method for performing ultrasound scans is provided. One embodiment of the ultrasonagraphic system acquires sonogram information from a series of ultrasonic scans of a human subject. The series of ultrasound scans are taken over a portion of interest on the human subject which has their underlying bone structure or other ultrasound discernable organ that is under examination. The data from the series of scans are synthesized into a single data file that corresponds to a three-dimensional (3D) image and/or 3D model of the underlying bone structure or organ of the examined human subject.

Abstract: A system and method for performing ultrasound scans is provided. One embodiment of the ultrasonagraphic system acquires sonogram information from a series of ultrasonic scans of a human subject. The series of ultrasound scans are taken over a portion of interest on the human subject which has their underlying bone structure or other ultrasound discernable organ that is under examination. The data from the series of scans are synthesized into a single data file that corresponds to a three-dimensional (3D) image and/or 3D model of the underlying bone structure or organ of the examined human subject.

Abstract: A system and method for performing ultrasound scans is provided. One embodiment of the ultrasonagraphic system acquires sonogram information from a series of ultrasonic scans of a human subject. The series of ultrasound scans are taken over a portion of interest on the human subject which has their underlying bone structure or other ultrasound discernable organ that is under examination. The data from the series of scans are synthesized into a single data file that corresponds to a three-dimensional (3D) image and/or 3D model of the underlying bone structure or organ of the examined human subject.

Abstract: A system and method for performing ultrasound scans is provided. One embodiment of the ultrasonagraphic system acquires sonogram information from a series of ultrasonic scans of a human subject. The series of ultrasound scans are taken over a portion of interest on the human subject which has their underlying bone structure or other ultrasound discernable organ that is under examination. The data from the series of scans are synthesized into a single data file that corresponds to a three-dimensional (3D) image and/or 3D model of the underlying bone structure or organ of the examined human subject.

Abstract: A method for correlating a 2D ultrasonagraphic image of a patient's spine with a relative location along the spine may include storing a generic 3D model of a spine in a database of an ultrasonagraphic system, recording a patient-specific spine contour line via an ultrasound probe, resizing the length of the generic 3D model according to the patient-specific contour line, distorting the shape of the generic 3D model according to the patient-specific spine contour line to create a patient-specific 3D model of the patient's spine, capturing a first ultrasound image of the patient's spine via the ultrasound probe and concurrently determining a 3D location of the ultrasound probe. The method may include correlating the 3D location of the ultrasound probe with a corresponding location on the patient-specific 3D model. A rendering of the patient-specific 3D model may be displayed, including an indication of the relative location of the ultrasound probe.

Abstract: Methods for assessing spinal health and treatment effectiveness for spinal conditions in a patient via use of an ultrasonagraphic system are shown and described. The ultrasonagraphic system includes optical targets, a transducer probe, an optical tracker unit, an image processing system, a 3D ultrasound processor, and a display. The methods include attaching optical targets to the patient's body; detecting locations of the optical targets on the patient; detecting a location of the transducer probe; moving the transducer probe over at least a portion of the patient's body to collect spinal image data; generating 3D image data; sending 3D image data to the image processing system; processing 3D image data; displaying a real-time 3D image of the one or more vertebrae on the display to allow a healthcare provider to assess spinal health and treatment effectiveness based on the displayed real-time 3D image.

Abstract: A method for correlating a 2D ultrasonagraphic image of a patient's spine with a relative location along the spine may include storing a generic 3D model of a spine in a database of an ultrasonagraphic system, recording a patient-specific spine contour line via an ultrasound probe, resizing the length of the generic 3D model according to the patient-specific contour line, distorting the shape of the generic 3D model according to the patient-specific spine contour line to create a patient-specific 3D model of the patient's spine, capturing a first ultrasound image of the patient's spine via the ultrasound probe and concurrently determining a 3D location of the ultrasound probe. The method may include correlating the 3D location of the ultrasound probe with a corresponding location on the patient-specific 3D model. A rendering of the patient-specific 3D model may be displayed, including an indication of the relative location of the ultrasound probe.

Abstract: Methods for assessing spinal health and treatment effectiveness for spinal conditions in a patient via use of an ultrasonagraphic system are shown and described. The ultrasonagraphic system includes optical targets, a transducer probe, an optical tracker unit, an image processing system, a 3D ultrasound processor, and a display. The methods include attaching optical targets to the patient's body; detecting locations of the optical targets on the patient; detecting a location of the transducer probe; moving the transducer probe over at least a portion of the patient's body to collect spinal image data; generating 3D image data; sending 3D image data to the image processing system; processing 3D image data; displaying a real-time 3D image of the one or more vertebrae on the display to allow a healthcare provider to assess spinal health and treatment effectiveness based on the displayed real-time 3D image.

Abstract: The present disclosure is directed to an ultrasonographic imaging system for examining and treating spinal conditions. In some examples, the system includes an ultrasound transducer probe configured to captured an ultrasound image, an ultrasound processor configured to receive data from the ultrasound transducer probe, a video capture card configured to receive the digital image from the ultrasound processor, an image processing system configured to process the digital image, the image processing system further including an image restoration module, an algorithm module, and a visualization module, a plurality of optical targets and a display device.