Abstract
The exposure of normal tissues to high radiation during cone-beam CT (CBCT) imaging increases the risk of cancer and genetic defects. Statistical iterative algorithms with the total variation (TV) penalty have been widely used for low dose CBCT reconstruction, with state-of-the-art performance in suppressing noise and preserving edges. However, TV is a first-order penalty and sometimes leads to the so-called staircase effect, particularly over regions with smooth intensity transition in the reconstruction images. A second-order penalty known as the Hessian penalty was recently used to replace TV to suppress the staircase effect in CBCT reconstruction at the cost of slightly blurring object edges. In this study, we proposed a new penalty, the TV-H, which combines TV and Hessian penalties for CBCT reconstruction in a structure-adaptive way. The TV-H penalty automatically differentiates the edges, gradual transition and uniform local regions within an image using the voxel gradient, and adaptively weights TV and Hessian according to the local image structures in the reconstruction process. Our proposed penalty retains the benefits of TV, including noise suppression and edge preservation. It also maintains the structures in regions with gradual intensity transition more successfully. A majorization-minimization (MM) approach was designed to optimize the objective energy function constructed with the TV-H penalty. The MM approach employed a quadratic upper bound of the original objective function, and the original optimization problem was changed to a series of quadratic optimization problems, which could be efficiently solved using the Gauss-Seidel update strategy. We tested the reconstruction algorithm on two simulated digital phantoms and two physical phantoms. Our experiments indicated that the TV-H penalty visually and quantitatively outperformed both TV and Hessian penalties.
Highlights
On-board cone-beam computed tomography (CBCT) is extensively used in clinical imageguided radiation therapy [1]
Our results indicated that the total variation (TV)-H penalty outperformed the TV penalty in suppressing the staircase effect, and overcame the drawbacks of the Hessian penalty, without blurring object edges
We examined the adaptive parameter α defined in Eq (5) along the yellow line in the anthropomorphic head phantom for TV-H in the penalized weighted leastsquares (PWLS) reconstruction process (Fig. 11)
Summary
On-board cone-beam computed tomography (CBCT) is extensively used in clinical imageguided radiation therapy [1]. The radiation dose may be reduced by lowering the mAs levels during the CBCT acquisition process. This strategy decreases the number of x-ray photons detected by the scanner. The conventional FDK method will produce reconstructed CBCT images with increased noise from the projections acquired with lower mAs levels [4]. Several algorithms have been proposed to improve the quality of CBCT imaging from lower mAs level projections [5]. The penalized weighted leastsquares (PWLS) iterative algorithm with TV (PWLS-TV) has demonstrated its advantage in suppressing noises and preserving edges, showing state-of-the-art performance in CBCT reconstruction [11, 12]
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