Contrast agent dose reduction in computed tomography with deep learning using a conditional generative adversarial network.

Abstract

To reduce the dose of intravenous iodine-based contrast media (ICM) in CT through virtual contrast-enhanced images using generative adversarial networks. Dual-energy CTs in the arterial phase of 85 patients were randomly split into an 80/20 train/test collective. Four different generative adversarial networks (GANs) based on image pairs, which comprised one image with virtually reduced ICM and the original full ICM CT slice, were trained, testing two input formats (2D and 2.5D) and two reduced ICM dose levels (-50% and -80%). The amount of intravenous ICM was reduced by creating virtual non-contrast series using dual-energy and adding the corresponding percentage of the iodine map. The evaluation was based on different scores (L1 loss, SSIM, PSNR, FID), which evaluate the image quality and similarity. Additionally, a visual Turing test (VTT) with three radiologists was used to assess the similarity and pathological consistency. The -80% models reach an SSIM of > 98%, PSNR of > 48, L1 of between 7.5 and 8, and an FID of between 1.6 and 1.7. In comparison, the -50% models reach a SSIM of > 99%, PSNR of > 51, L1 of between 6.0 and 6.1, and an FID between 0.8 and 0.95. For the crucial question of pathological consistency, only the 50% ICM reduction networks achieved 100% consistency, which is required for clinical use. The required amount of ICM for CT can be reduced by 50% while maintaining image quality and diagnostic accuracy using GANs. Further phantom studies and animal experiments are required to confirm these initial results.

• The amount of contrast media required for CT can be reduced by 50% using generative adversarial networks.

• Not only the image quality but especially the pathological consistency must be evaluated to assess safety.

• A too pronounced contrast media reduction could influence the pathological consistency in our collective at 80%.

Click the Cite button above to demo the feature to enablevisitors to import publication metadata into their reference management software.
Johannes Haubold
Johannes Haubold
Medical Lead

My research interests include virtual sequencing, non-invasive tumor decoding and clinical AI integration.

René Hosch
René Hosch
Team Lead

My research interests include distributed Computer Vision, Generative Adversarial Networks and Image-to-Image translation.

Felix Nensa
Felix Nensa
Lead

My research interests include medical digitalization, computer vision and radiology.