Program Information
Quantitative Evaluation of Spectral Detector CT Using Virtual Monochromatic Images: Initial Results
X Duan1*, G Arbique2 , J Guild3 , A Dhanantwari4 , Y Yagil5 , J Anderson6 , (1) UT Southwestern Medical Center, Dallas, TX, (2) UT Southwestern Medical Ctr at Dallas, Dallas, TX, (3) UT Southwestern Medical Center, Dallas, TX, (4) Philips Healthcare, Highland Heights, Ohio, (5) Philips Medical Systems, Haifa, ,(6) UT Southwestern Medical Ctr at Dallas, Dallas, TX
Presentations
TU-EF-204-12 (Tuesday, July 14, 2015) 1:45 PM - 3:45 PM Room: 204
Purpose
To evaluate the image quality and spectral information of a spectral detector CT (SDCT) scanner using virtual monochromatic (VM) energy images.
Methods
The SDCT scanner (Philips Healthcare) was equipped with a dual-layer detector and spectral iterative reconstruction (IR), which generates conventional 80-140 kV polychromatic energy (PE) CT images using both detector layers, PE images from the low-energy (upper) and high-energy (lower) detector layers and VM images. A solid water phantom with iodine (2.0-20.0 mg I/ml) and calcium (50.0-600.0 mg Ca/ml) rod inserts was used to evaluate effective energy estimate (EEE) and iodine contrast to noise ratio (CNR). The EEE corresponding to an insert CT number in a PE image was calculated from a CT number fit to the VM image set. Since PE image is prone to beam-hardening artifact EEE may underestimate the actual energy separation from two layers of the detector. A 30-cm-diameter water phantom was used to evaluate noise power spectrum (NPS). The phantoms were scanned at 120 and 140 kV with the same CTDIvol.
Results
The CT number difference for contrast inserts in VM images (50-150 keV) was 1.3±6% between 120 and 140 kV scans. The difference of EEE calculated from low- and high-energy detector images was 11.5 and 16.7 keV for 120 and 140 kV scans, respectively. The differences calculated from 140 and 100 kV conventional PE images were 12.8, and 20.1 keV from 140 and 80 kV conventional PE images. The iodine CNR increased monotonically with decreased keV. Compared to conventional PE images, the peak of NPS curves from VM images were shifted to lower frequency.
Conclusion
The EEE results indicates that SDCT at 120 and 140 kV may have energy separation comparable to 100/140 kV and 80/140 kV dual-kV imaging. The effects of IR on CNR and NPS require further investigation for SDCT.
Funding Support, Disclosures, and Conflict of Interest: Author YY and AD are Philips Healthcare employees.
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