Share Email Print
cover

Journal of Medical Imaging

Spectral response model for a multibin photon-counting spectral computed tomography detector and its applications
Author(s): Xuejin Liu; Mats Persson; Hans Bornefalk; Staffan Karlsson; Cheng Xu; Mats Danielsson; Ben Huber
Format Member Price Non-Member Price
PDF $20.00 $25.00
cover GOOD NEWS! Your organization subscribes to the SPIE Digital Library. You may be able to download this paper for free. Check Access

Paper Abstract

Variations among detector channels in computed tomography can lead to ring artifacts in the reconstructed images and biased estimates in projection-based material decomposition. Typically, the ring artifacts are corrected by compensation methods based on flat fielding, where transmission measurements are required for a number of material-thickness combinations. Phantoms used in these methods can be rather complex and require an extensive number of transmission measurements. Moreover, material decomposition needs knowledge of the individual response of each detector channel to account for the detector inhomogeneities. For this purpose, we have developed a spectral response model that binwise predicts the response of a multibin photon-counting detector individually for each detector channel. The spectral response model is performed in two steps. The first step employs a forward model to predict the expected numbers of photon counts, taking into account parameters such as the incident x-ray spectrum, absorption efficiency, and energy response of the detector. The second step utilizes a limited number of transmission measurements with a set of flat slabs of two absorber materials to fine-tune the model predictions, resulting in a good correspondence with the physical measurements. To verify the response model, we apply the model in two cases. First, the model is used in combination with a compensation method which requires an extensive number of transmission measurements to determine the necessary parameters. Our spectral response model successfully replaces these measurements by simulations, saving a significant amount of measurement time. Second, the spectral response model is used as the basis of the maximum likelihood approach for projection-based material decomposition. The reconstructed basis images show a good separation between the calcium-like material and the contrast agents, iodine and gadolinium. The contrast agent concentrations are reconstructed with more than 94% accuracy.

Paper Details

Date Published: 11 September 2015
PDF: 11 pages
J. Med. Img. 2(3) 033502 doi: 10.1117/1.JMI.2.3.033502
Published in: Journal of Medical Imaging Volume 2, Issue 3
Show Author Affiliations
Xuejin Liu, KTH Royal Institute of Technology (Sweden)
Mats Persson, KTH Royal Institute of Technology (Sweden)
Hans Bornefalk, KTH Royal Institute of Technology (Sweden)
Staffan Karlsson, KTH Royal Institute of Technology (Sweden)
Cheng Xu, KTH Royal Institute of Technology (Sweden)
Mats Danielsson, KTH Royal Institute of Technology (Sweden)
Ben Huber, KTH Royal Institute of Technology (Sweden)


© SPIE. Terms of Use
Back to Top