Systems and methods for tissue tracking with radiation therapy beams

The invention claimed is: 1. A radiation therapy system comprising: a radiation source configured to emit a radiation therapy beam; a collimator positioned to attenuate at least a periphery of the radiation therapy beam; a radiation fiducial configured to be coupled to a patient; a first radiation detector having a first plurality of sensing elements each configured to sense radiation that interacts with the respective sensing element; a second radiation detector having a second plurality of sensing elements each configured to sense radiation that interacts with the respective sensing element, wherein the second radiation detector is arranged more distally from the radiation source than the first radiation detector to receive the radiation therapy beam after the first radiation detector; a computing device in communication with the radiation source, the first radiation detector, and the second radiation detector, the computing device being configured to: receive first imaging data from the first radiation detector; receive second imaging data from the second radiation detector; and track a position of the imaging fiducial within or outside the attenuated periphery of the radiation therapy beam using the first imaging data and the second imaging data. 2. The radiation therapy system of claim 1 , wherein the first radiation detector has a first gain, and the second radiation detector has a second gain, and wherein the second gain of the second radiation detector is greater than the first gain of the first radiation detector. 3. The radiation therapy system of claim 2 , wherein the first radiation detector includes a gadolinium oxysulfide (GOS) detector, and wherein the second radiation detector includes a layer of a LKH-5 scintillating glass. 4. The radiation therapy system of claim 1 , wherein the computing device is configured to: generate a first image using the first imaging data; generate a second image using the second imaging data; and combine the first image and the second image by weighting the second image over the first image when the fiducial is within the periphery of the radiation therapy beam. 5. The radiation therapy system of claim 4 , wherein the computing device is configured to: segment a portion of the second image that corresponds to an envelope of the periphery of the radiation therapy beam; and locate the imaging fiducial in a remaining portion of the second image that does not include the envelope of the periphery of the radiation therapy beam, to determine that the fiducial is within the periphery of the radiation therapy beam. 6. The radiation therapy system of claim 5 , wherein the computing device is further configured to process the remaining portion of the second image by filtering the remaining portion of the second image using a median filter having a width and a length, and wherein a ratio of the length to the width of the median filter is approximately 40. 7. The radiation therapy system of claim 5 , wherein the remaining portion of the second image surrounds and encapsulates the envelope of the periphery of the radiation therapy beam to define a circular void. 8. The radiation therapy system of claim 5 , wherein at least one of: the region defined by the portion of the second image that corresponds to the envelope is a predefined region, the size and shape of the predefined region being based on the properties of the radiation beam and a distance the radiation beam traverses along a path from the collimator and to the first radiation detector; or the computing device is configured to determine a boundary of the envelope of the periphery of the radiation therapy beam from the first image, the boundary of the envelope of the periphery being used to define the portion of the second image that is to be segmented. 9. The radiation therapy system of claim 4 , wherein, to combine the first image and the second image, the computing device is configured to: subtract the second image from the first image to generate a subtracted second image; and locate the imaging fiducial in the subtracted second image. 10. The radiation therapy system of claim 1 , wherein the first plurality of sensing elements defines a first sensing area of the first radiation detector, wherein the second plurality of sensing elements defines a second sensing area of the second radiation detector, and wherein the first sensing area is substantially aligned with the second sensing area so that the first sensing area substantially overlaps with the second sensing area. 11. The radiation therapy system of claim 10 , wherein at least one of: the first sensing area is substantially similar to the second sensing area; the size of each of the first plurality of sensing elements is substantially similar to the size of each of the second plurality of sensing elements, or the number of the first plurality of sensing elements is substantially similar to the number of the second plurality of sensing elements. 12. The radiation therapy system of claim 1 , further comprising: a third radiation detector having a third plurality of sensing elements each configured to sense radiation that interacts with the respective sensing element; and a fourth radiation detector having a fourth plurality of sensing elements each configured to sense radiation that interacts with the respective sensing element; and wherein the second radiation detector is situated more proximate to the radiation source than the third radiation detector, and the third radiation detector is situated more proximate to the radiation source than the fourth radiation detector, and wherein the computing device is configured to: receive third imaging data from the third radiation detector; receive fourth imaging data from the fourth radiation detector; generate a first image from the first imaging data; generate a second image by combining at least two of the second imaging data, the third imaging data, or the fourth imaging data; and locate the imaging fiducial in the second image to track the position of the imaging fiducial. 13. The radiation therapy system of claim 12 , wherein generating the second image includes the computing device being configured to: combine the second imaging data, the third imaging data, and the fourth imaging data together to generate combined imaging data; and generate the second image using the combined imaging data, and wherein the computing device is configured to: at least one of segment a portion of the second image that corresponds to a region within the attenuated periphery of the radiation therapy beam, or subtract the second image from the first image to generate a subtracted second image; and locate the imaging fiducial in the remaining portion of the second image, or the subtracted second image. 14. The radiation therapy system of claim 12 , wherein gains of the second, third, and fourth detectors are substantially similar, and wherein a gain of the second detector is greater than a gain of the first detector. 15. The radiation therapy system of claim 1 , wherein the first imaging data is first three-dimensional (3D) imaging data, and wherein the second imaging data is second 3D imaging data. 16. A method for performing a radiation therapy treatment comprising: delivering a radiation therapy beam from a radiation source to a patient having a fiducial marker positioned on the patient during a radiation therapy treatment; receiving the radiation therapy beam after passing through the patient using a first radiation detector tuned to acquire first ima