Determining material stiffness using multiple aperture ultrasound

What is claimed is: 1. A method of determining a stiffness of a tissue with ultrasound, the method comprising the steps of: forming a baseline image of a region of interest with a ping-based ultrasound imaging system; transmitting an ultrasonic pulse with a shear-wave-initiating transducer, the ultrasonic pulse being configured to induce a propagating shear wave in the region of interest; imaging the region of interest with the ping-based ultrasound imaging system to capture a first image frame and a second image frame of the propagating shear wave as it moves through the region of interest, wherein capturing the first frame comprises: transmitting a first unfocused ultrasound ping from a first transmitter transducer element of the ping-based ultrasound imaging system; forming a first image layer using echoes of only the first ultrasound ping received by elements of a first receive aperture of the ping-based ultrasound imaging system with an electronic controller of the ping-based ultrasound imaging system; forming a second image layer using echoes of only the first ultrasound ping received by elements of a second receive aperture of the ping-based ultrasound imaging system with the electronic controller; combining the first image layer and the second image layer with the electronic controller to form the first frame; wherein capturing the second frame comprises: transmitting a second unfocused ultrasound ping from the first transmitter transducer element of the ping-based ultrasound imaging system; forming a third image layer using echoes of only the second ultrasound ping received by elements of the first receive aperture of the ping-based ultrasound imaging system with the electronic controller; forming a fourth image layer using echoes of only the second ultrasound ping received by elements of the second receive aperture of the ping-based ultrasound imaging system with the electronic controller; combining the third image layer and the fourth image layer with the electronic controller to form the second frame; subtracting the baseline image from the first image frame with the electronic controller of the ping-based ultrasound imaging system to obtain a first difference frame; subtracting the baseline image from the second image frame with the electronic controller to obtain a second difference frame; determining a position of the propagating shear wave in the first and second difference frames with the electronic controller; and calculating a first propagation speed of the propagating shear wave in the region of interest from the positions in the first and second difference frames with the electronic controller. 2. The method of claim 1 , further comprising calculating a tissue stiffness of the region of interest from the propagation speed. 3. The method of claim 1 , wherein the transmitting step comprises transmitting an ultrasonic pulse with a first ultrasound transducer array, and wherein the imaging step comprises imaging the region of interest with a second ultrasound transducer array. 4. The method of claim 1 , wherein the forming step comprises transmitting a first circular waveform from a first transmit aperture and receiving echoes on a first receive aperture. 5. The method of claim 4 , wherein the imaging step comprises transmitting second and third circular waveforms from the first transmit aperture and receiving echoes of the second and third circular waveforms with the first receive aperture. 6. The method of claim 5 , wherein the first transmit aperture and the first receive aperture do not include overlapping transducer elements. 7. The method of claim 1 , wherein the frame rate is between 1,000 and 75,000 fps. 8. The method of claim 1 , further comprising identifying the propagating shear wave as a speckle pattern moving through the region of interest. 9. The method of claim 1 , further comprising displaying a contemporaneous image of the region of interest, including a line indicating a direction of transmission of the ultrasonic pulse configured to induce a propagating shear wave. 10. The method of claim 8 , wherein the first difference frame and the second difference frame each contain substantially only noise and the speckle pattern representing the shear wave. 11. The method of claim 8 , further comprising approximating a center line of the speckle pattern. 12. The method of claim 1 , further comprising determining that a first segment of the shear wave is propagating faster than adjacent segments of the shear wave, and calculating a first segment propagation speed of the first segment. 13. The method of claim 1 , further comprising: imaging the region of interest with the ping-based ultrasound imaging system to capture a third image frame of the propagating shear wave as it moves through the region of interest; subtracting the baseline image from the third image frame with the electronic controller to obtain a third difference frame; determining a position of the propagating shear wave in the third difference frame with the electronic controller; calculating a second propagation speed of the propagating shear wave in the region of interest from the positions in the first and third difference frames; calculating a third propagation speed of the propagating shear wave in the region of interest from the positions in the second and third difference frames; and calculating an average propagation speed from the first propagation speed, the second propagation speed and the third propagation speed. 14. The method of claim 1 , wherein each of the baseline image and the first image frame comprises a plurality of pixel values, and wherein subtracting the baseline image from the first image frame comprises subtracting each pixel value of the baseline image from each corresponding pixel value of the first image frame. 15. The method of claim 1 , wherein imaging the region of interest with the ping-based ultrasound imaging system further comprises transmitting unfocused omni-directional pings into the region of interest from at least one transmit aperture and receiving echoes of the unfocused omni-directional pings with at least one receive aperture separate from the transmit aperture. 16. The method of claim 1 , wherein the shear wave propagates at a speed of between about 1 meter per second and about 10 meters per second. 17. The method of claim 1 , wherein forming the baseline image of the region of interest comprises the steps of: transmitting a first unfocused ultrasound ping from a first transmitter transducer element; forming a first baseline image layer with an electronic controller using echoes of the first ultrasound ping received by elements of a first receive aperture; forming a second baseline image layer with the electronic controller using echoes of the first ultrasound ping received by elements of a second receive aperture; transmitting a second unfocused ultrasound ping from a second transmitter transducer element different than the first transmitter element; forming a third baseline image layer with the electronic controller using echoes of the second ultrasound ping received by elements of the first receive aperture; forming a fourth baseline image layer with the electronic controller using echoes of the second ultrasound ping received by elements of the second receive aperture; and combining the first baseline image layer, the second baseline image layer, the third baseline image layer, and the fourth baseline image layer with the electronic controller to form the baseline image.