Author:
Wang Xiang,He Jichun,Liu Yi,Zhang Pengcheng,Cheng Weiting,Wang Bin,Gui Zhiguo
Abstract
Abstract
Sparse-view CT is an effective method to reduce X-ray
radiation dose in clinical CT imaging. However, sparse view image
reconstruction is still challenging due to highly undersampled
data. To this end, we propose a new deep learning-based
reconstruction model of CT images, called DIDR-Net. Unlike existing
methods, DIDR-Net employs a dual network structure, including an
iterative reconstruction sub-network and a detail recovery
sub-network. The iterative reconstruction sub-network expands the
FISTA (Fast Iterative Soft Thresholding Algorithm) into a deep
network, utilizing learnable nonlinear sparse transform and
shrinkage thresholding to improve reconstruction performance. To
avoid loss of image details while removing artifacts, we design a
detail recovery sub-network. Specifically, this sub-network captures
the local details and global information of the initial image
through local and global branches, and adaptively fuses the results
of these two branches through a fusion module. DIDR-Net generates
both the initial reconstruction map and the detail feature map in a
parallel manner, and finally fuses the two sides to reconstruct a
high-quality CT image. Experimental results on the AAPM public
dataset show that DIDR-Net exhibits better performance in both
streak artifact removal and detail structure preservation compared
to other advanced reconstruction algorithms.
Subject
Mathematical Physics,Instrumentation