Computed tomography (CT) scans is an extremely important diagnostic tool with ~80 million scans per year with over half of those scans using exogenous contrast agents to enhance visualization of various lesions and to provide functional information. Spectral CT uses data acquisition with different spectral channels to separate individual materials and to provide concentration maps of particular contrast agents. Contrast agent develop- ment is an active research area with many new compounds under investigation including gold, bismuth, gado- linium, xenon, and lanthanide-based contrast agents. Imaging of multiple agents simultaneously in a single ac- quisition has distinct advantages for multiphasic studies and multisystem (e.g., angiography/respiratory or an- giography/gastrointestinal) studies. Similarly, even if agents are estimated individually, flexibility to provide op- timal spectra for those agents is desirable in terms of dose utilization and/or raising low concentration visibility limits. However, current spectral CT systems are limited in their ability to image multiple contrast agents either due to the limited number of spectral channels available (e.g., two in dual-energy systems) or due to their lim- ited flexibility in shaping the x-ray spectrum (e.g., using one, or in dual-source system two x-ray filters). We propose a novel and relatively simple hardware modification applicable to both current diagnostic CT as well preclinical spectral CT prototypes that can either enable or enhance material decomposition capabilities, respectively. The concept borrows from an idea used in color optical imaging where spectral information is en- coded spatially using tiled filters. For x-ray imaging, these filters can be comprised of materials with k-edges in the diagnostic range to effect specific spectral shapes. Data acquisitions using these filters will be sparse in each spectral channel. Ordinarily this would present a challenge for traditional reconstruction and material de- composition; however, model-based material decomposition (MBMD) and compressed sensing allow for direct estimation of material concentration from the projection measurements enabling this unique data acquisition. The proposed joint hardware and software research effort has the following specific aims.
Aim 1 : Characterize and design spectral-spatial filters. We will develop models for spectral-spatial filters to enable simulation, MBMD reconstruction, and optimized filter design.
Aim 2 : Construct spectral-spatial filters and implement sparse data acquisition in a CT test bench. We will develop methods for fabrication and integration of spec- tral-spatial filters into a CT test bench.
Aim 3 : Evaluate spectral-spatial filtered CT in physical material de- composition experiments. Performance of the novel spectral CT designs relative to current methodologies will be assessed including low-dose and low-concentration contrast limits. Successful completion of these aims will establish the feasibility of the spectral-spatial filtering approach as a modification to both standard diagnos- tic CT (enabling spectral imaging with a relatively simple modification) and to existing spectral CT prototype (providing additional spectral shaping capabilities for better dose utilization and lower concentration limits).

Public Health Relevance

Spectral CT is an emerging technology that is starting to find widespread clinical use due to its ability to decompose the patient volume into separate material images including estimates of exogenous contrast agents like iodine. Current spectral CT system are somewhat inflexible in their ability to change the number of spectral channels and the shape of the x-ray spectra incident on the patient, which limits the ability to separation multiple contrast agents simultaneously or individual without additional hardware changes. The proposed effort seeks to combine a new x-ray filtration approach, using a concept from color digital imaging where spectral information is encoded spatially, which will enable increased flexibility is spectral channel design and enable optimized imaging of multiple contrast agents with minor modifications to the CT scanner.

Agency
National Institute of Health (NIH)
Institute
National Institute of Biomedical Imaging and Bioengineering (NIBIB)
Type
Exploratory/Developmental Grants (R21)
Project #
1R21EB026849-01
Application #
9592315
Study Section
Biomedical Imaging Technology Study Section (BMIT)
Program Officer
Shabestari, Behrouz
Project Start
2018-08-01
Project End
2020-05-31
Budget Start
2018-08-01
Budget End
2019-05-31
Support Year
1
Fiscal Year
2018
Total Cost
Indirect Cost
Name
Johns Hopkins University
Department
Biomedical Engineering
Type
Schools of Medicine
DUNS #
001910777
City
Baltimore
State
MD
Country
United States
Zip Code
21205
Webster Stayman, J; Tilley 2nd, Steven (2018) Model-based Multi-material Decomposition using Spatial-Spectral CT Filters. Conf Proc Int Conf Image Form Xray Comput Tomogr 2018:102-105