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Development of Realistic Multi-Contrast Textured XCAT (MT-XCAT) Phantoms Using a Dual-Discriminator Conditional-Generative Adversarial Network (D-CGAN)

Y Chang1*, K Lafata2, P Segars3, F Yin4, L Ren5, (1) Duke University, Durham, NC, (2) Duke University, Durham, NC, (3) Duke Univ, Durham, NC, (4) Duke University, Durham, NC, (5) Duke University Medical Center, Cary, NC


(Sunday, 7/12/2020) 2:00 PM - 3:00 PM [Eastern Time (GMT-4)]

Room: Track 1

Develop a machine learning-based method to generate multi-contrast anatomical textures in the 4D extended cardiac-torso (XCAT) phantom for more realistic imaging simulations. As a pilot study, we synthesize CT and CBCT textures in the chest region.
For training purposes, major organs and gross tumor volumes in the chest region were segmented from real patient images and assigned to different HU values to generate organ maps, resembling XCAT produced images. A dual-discriminator conditional-generative adversarial network (D-CGAN) was developed to synthesize anatomical textures in the corresponding organ maps. The D-CGAN was uniquely designed with two discriminators, one trained for the body and the other for tumors. The network was trained separately using 62 CT and 63 CBCT images from lung SBRT patients to generate multi-contrast textured XCAT (MT-XCAT) for each modality. Various XCAT phantoms were input to the D-CGAN to generate textured phantoms. The phantoms were evaluated by comparing the intensity histograms and radiomic features with those from real patient images using Wilcoxon rank-sum test.

The visual examination demonstrated that the MT-XCAT phantoms presented similar general contrast and anatomical textures as CT and CBCT images. The mean HU values of the MT-XCAT-CT and MT-XCAT-CBCT were -140.35±336.48 and -185.72±350.32, compared with those of real CT (-149.79±346.37 ) and CBCT (-245.41±371.66). The majority of radiomic features from the MT-XCAT phantoms followed the same distribution as the real images according to the Wilcoxon rank-sum test, except for limited second-order features.

The study demonstrated the feasibility of generating realistic MT-XCAT phantoms using D-CGAN. The MT-XCAT phantoms can be further expanded to include other modalities (MRI, PET, ultrasound, etc.) under the same scheme. This crucial development greatly enhances the value of the phantom for various clinical applications, including testing and optimizing novel imaging techniques, validation of radiomics analysis methods, and virtual clinical trials.

Funding Support, Disclosures, and Conflict of Interest: This work was supported by the National Institutes of Health under Grant No. R01-CA184173 and R01-EB028324.


Phantoms, Texture Analysis


IM- Cone Beam CT: Phantoms - digital

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