Methods and apparatus for ultrasound strain imaging

摘要

A system and method for improved ultrasound strain imaging includes using data from a tracking system to enhance the quality of ultrasound strain image and to reduce the dependency of image quality of the user's expertise. The tracking information is synchronized with the RF frames and interpolated to find the transformation corresponding to each frame. The RF frames with their transformations are incorporated into calculation of ultrasound strain images. The tracking system may be an optical tracker, electromagnetic tracker, accelerometer, or a structured light system. The structured light system may also be used for probe calibration, by calibrating the surface of the probe pre-operatively. In addition, a relative Young's Modulus may be calculated using tracking information that is independent from the distribution of input force.

主权项

1. A system for providing ultrasonic strain imaging, comprising:
an ultrasound probe for acquiring a sequence of RF frames during palpations of a target area; a structured light system including a projector configured to project a structured light pattern and at least two cameras configured to acquire images; a processor having a non-transitory computer readable medium encoded with a program configuring the processor to: control the projector to project a structured light pattern onto a surface of the target area, control the at least two cameras to acquire a first set of images of the structured light pattern on the surface of the target area, control the at least two cameras to acquire a second set of images of the structured light pattern on the surface of the target area and the ultrasound probe located in the target area, reconstruct the surface of the target area using the first set of images, determine a position and orientation of the ultrasound probe within the target area based on the second set of images, during the palpations of the target area at each said RF frame in said sequence of RF frames, track and monitor positions and orientations of the ultrasound probe and tissue deformation based on the determined position and orientation of the ultrasound probe and the reconstructed surface of the target area respectively, synchronize each of said monitored positions and orientations of the ultrasound probe or the target area to a respective RF frame in said sequence of RF frames, compute an energy value for each RF frame with respect to all other RF frames in said sequence of RF frames using an energy function, wherein the energy function uses said monitored positions and orientations from said sequence of RF frames, remove RF frames beneath a threshold energy value from said sequence of RF frames; automatically select multiple pairs of RF frames from said sequence of RF frames by minimizing a cost function which evaluates relative motion of any two image frames based upon the monitored positions and orientations, calculate strain values for each of said selected multiple pairs of RF frames, construct a finite element model based upon the first set of images, second set of images, and strain values, and generate a final strain image using the finite element model to solve for Young's Modulus; and a display for displaying the final strain image.