Clutter reduction for ultrasound images and associated devices, systems, and methods

What is claimed is: 1. An ultrasound imaging system, comprising: an array of acoustic elements configured to transmit acoustic energy into an anatomy and receive echoes corresponding to the transmitted acoustic energy; and a processor in communication with the array and configured to: activate the array to perform a scan sequence to obtain a plurality of signals; generate an image based on the plurality of signals; arrange the plurality of signals into a first right subaperture, a second right subaperture, a first left subaperture, and a second left subaperture; use the first right subaperture with a first apodization function and the second right subaperture with a second apodization function to generate a dual apodization with cross-correlation (DAX)-suppressed right subaperture; use the first left subaperture with a third apodization function and the second left subaperture with a fourth apodization function to generate a dual apodization with cross-correlation (DAX)-suppressed left subaperture; identify off-axis signals from the plurality of signals by comparing the DAX-suppressed right subaperture and the DAX-suppressed left subaperture; generate a clutter reduction mask based on the identified off-axis signals; apply the clutter reduction mask to the image to generate a masked image; and output the masked image to a display in communication with the processor. 2. The ultrasound imaging system of claim 1 , wherein the scan sequence comprises a plurality of transmit-receive pairs associated with the acoustic elements of the array, wherein the plurality of signals corresponds to the plurality of transmit-receive pairs, wherein the first right subaperture comprises a first portion of the transmit-receive pairs and the second right subaperture comprises a second portion of the transmit-receive pairs, wherein the first portion of the transmit-receive pairs and the second portion of the transmit-receive pairs are interleaving, wherein the first left subaperture comprises a third portion of the transmit-receive pairs and the second left subaperture comprises a fourth portion of the transmit-receive pairs, wherein the third portion of the transmit-receive pairs and the fourth portion of the transmit-receive pairs are interleaving. 3. The ultrasound imaging system of claim 1 , wherein the processor is configured to generate a noise image layer based on a relationship that includes the DAX-suppressed right subaperture and the DAX-suppressed left subaperatures, wherein the noise image layer comprises an image layer formed of signals representative of noise in the image. 4. The ultrasound imaging system of claim 3 , wherein the processor is configured to generate the clutter reduction mask based in part on the noise image layer. 5. The ultrasound imaging system of claim 1 , wherein the processor is configured to generate a tissue image layer based on a relationship that includes the DAX-suppressed right subaperture and the DAX-suppressed left subaperatures, the image, and the clutter reduction mask, wherein the tissue image layer comprises an image layer formed of signals representative of tissue in the image. 6. The ultrasound imaging system of claim 5 , wherein the processor is configured to generate a lumen image layer based on the tissue image layer and the clutter reduction mask, wherein the lumen image layer comprises an image layer formed of signals representative of a body lumen in the image. 7. The ultrasound imaging system of claim 1 , where the first and second left subapertures and the first and second right subapertures are part of an aperture, and wherein the aperature comprises an axis. 8. The ultrasound imaging system of claim 7 , wherein the first and second left subapertures is spatially associated with the left side of the axis of the aperture and the first and second right subapertures is spatially associated with the right side of the axis of the aperture. 9. The ultrasound imaging system of claim 7 , wherein the aperture is associated with an angular portion of a circumference of the array. 10. The ultrasound imaging system of claim 7 , wherein the off-axis signals are generated from ultrasound energy reflected from objects that are away from the axis of the aperture. 11. The ultrasound imaging system of claim 7 , wherein the aperture is formed of a plurality of transmit-receive pairs of the scan sequence, wherein each of the plurality of transmit-receive pairs is associated with a transmit element of the aperture and a receive element of the aperture, wherein the right subaperture is formed of a first portion of the plurality of transmit-receive pairs representative of all of the transmit elements of the aperture and a portion of the receive elements of the aperture, and wherein the left subaperture is formed of a second portion of the plurality of transmit-receive pairs representative of a portion of the transmit elements of the aperture and all of the receive elements of the aperture. 12. The ultrasound imaging system of claim 1 , further comprising an intravascular ultrasound (IVUS) imaging catheter, and wherein the array of acoustic elements is positioned around a perimeter of the IVUS imaging catheter. 13. A method for ultrasound imaging, comprising: activating an array of acoustic elements to perform a scan sequence to obtain a plurality of signals; generating, by a processor in communication with the array, an image based on the plurality of signals; arranging, by the processor, the plurality of signals into a first right subaperture, a second right subaperture, a first left subaperture, and a second left subaperture; using the first right subaperture with a first apodization function and the second right subaperture with a second apodization function to generate a dual apodization with cross-correlation (DAX)-suppressed right subaperture; using the first left subaperture with a third apodization function and the second left subaperture with a fourth apodization function to generate a dual apodization with cross-correlation (DAX)-suppressed left subaperture; identifying, by the processor, off-axis signals from the plurality of signals by comparing the DAX-suppressed right subaperture and the DAX-suppressed left subaperture; generating, by the processor, a clutter reduction mask based on the identified off-axis signals; applying, by the processor, the clutter reduction mask to the image to generate a masked image; and outputting the masked image to a display in communication with the processor. 14. The method of claim 13 , wherein activating the array to perform the scan sequence comprises activating a plurality of transmit-receive pairs associated with the acoustic elements of the array, wherein the plurality of signals corresponds to the plurality of transmit-receive pairs, wherein the first right subaperture comprises a first portion of the transmit-receive pairs and the second right subaperture comprises a second portion of the transmit-receive pairs, wherein the first portion of the transmit-receive pairs and the second portion of the transmit-receive pairs are interleaving, wherein the first left subaperture comprises a third portion of the transmit-receive pairs and a second left subaperture comprises a fourth portion of the transmit-receive pairs, wherein the third portion of the transmit-receive pairs and the fourth portion of the transmit-receive pairs are interleaving. 15. The method of claim 13 , further comprising generating a noise image layer based on a relationship that includes the DAX-suppressed right subaperture and the DAX-su