Patient-derived PixelPrint phantoms for evaluating clinical imaging performance of a deep learning CT reconstruction algorithm

Jessica Yunyun Im; Sandra Halliburton; Kai Mei; Amy E Perkins; Eddy Wong; Leonid Roshkovan; Olivia F Sandvold; Leening P Liu; Grace J Gang; Peter B Noël

doi:10.1088/1361-6560/ad3dba

Patient-derived PixelPrint phantoms for evaluating clinical imaging performance of a deep learning CT reconstruction algorithm

Phys Med Biol. 2024 Apr 11. doi: 10.1088/1361-6560/ad3dba. Online ahead of print.

Authors

Affiliations

¹ Department of Radiology, University of Pennsylvania, 3400 Spruce St., Philadelphia, Pennsylvania, 19104-6243, UNITED STATES.
² Philips Healthcare US, 100 Park Ave, Cleveland, Ohio, 01810, UNITED STATES.
³ Philips Healthcare US, 100 Park Ave, Orange Village, Ohio, 44122, UNITED STATES.
⁴ Department of Radiology, University of Pennsylvania, 3400 Spruce St., Philadelphia, 19104-6243, UNITED STATES.
⁵ Department of Radiology, University of Pennsylvania, 3400 Spruce St., Philadelphia, Pennsylvania, 19104, UNITED STATES.

PMID: 38604190
DOI: 10.1088/1361-6560/ad3dba

Abstract

ObjectiveDeep learning reconstruction (DLR) algorithms exhibit object-dependent resolution and noise performance. Thus, traditional geometric CT phantoms cannot fully capture the clinical imaging performance of DLR. This study uses a patient-derived 3D-printed PixelPrint lung phantom to evaluate a commercial DLR algorithm across a wide range of radiation dose levels.MethodThe lung phantom used in this study is based on a patient chest CT scan containing ground glass opacities and was fabricated using PixelPrint 3D-printing technology. The phantom was placed inside two different size extension rings to mimic a small- and medium-sized patient and was scanned on a conventional CT scanner at exposures between 0.5 and 20 mGy. Each scan was reconstructed using filtered back projection (FBP), iterative reconstruction, and DLR at five levels of denoising. Image noise, contrast to noise ratio (CNR), root mean squared error (RMSE), structural similarity index (SSIM), and multi-scale SSIM (MS SSIM) were calculated for each image.ResultsDLR demonstrated superior performance compared to FBP and iterative reconstruction for all measured metrics in both phantom sizes, with better performance for more aggressive denoising levels. DLR was estimated to reduce dose by 25-83% in the small phantom and by 50-83% in the medium phantom without decreasing image quality for any of the metrics measured in this study. These dose reduction estimates are more conservative compared to the estimates obtained when only considering noise and CNR. ConclusionDLR has the capability of producing diagnostic image quality at up to 83% lower radiation dose, which can improve the clinical utility and viability of lower dose CT scans. Furthermore, the PixelPrint phantom used in this study offers an improved testing environment with more realistic tissue structures compared to traditional CT phantoms, allowing for structure-based image quality evaluation beyond noise and contrast-based assessments.

Keywords: 3D-printed phantom; 3D-printing; CT imaging phantoms; Deep learning reconstruction; Dose reduction; Image quality assessment.

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