Display Field-Of-View Agnostic Robust CT Kernel Synthesis Using Model-Based Deep Learning

• URL: http://arxiv.org/abs/2502.14920v1
• Date: Wed, 19 Feb 2025 15:29:47 GMT
• Title: Display Field-Of-View Agnostic Robust CT Kernel Synthesis Using Model-Based Deep Learning
• Authors: Hemant Kumar Aggarwal, Antony Jerald, Phaneendra K. Yalavarthy, Rajesh Langoju, Bipul Das,
• Abstract summary: Different kernels influence spatial resolution, image noise, and contrast in various ways.<n>The Display Field-of-View (DFOV) adds complexity to kernel synthesis.<n>This work introduces an efficient, DFOV-agnostic solution for image-based kernel synthesis using model-based deep learning.
• Score: 5.577914196716853
• License: http://creativecommons.org/licenses/by-nc-nd/4.0/
• Abstract: In X-ray computed tomography (CT) imaging, the choice of reconstruction kernel is crucial as it significantly impacts the quality of clinical images. Different kernels influence spatial resolution, image noise, and contrast in various ways. Clinical applications involving lung imaging often require images reconstructed with both soft and sharp kernels. The reconstruction of images with different kernels requires raw sinogram data and storing images for all kernels increases processing time and storage requirements. The Display Field-of-View (DFOV) adds complexity to kernel synthesis, as data acquired at different DFOVs exhibit varying levels of sharpness and details. This work introduces an efficient, DFOV-agnostic solution for image-based kernel synthesis using model-based deep learning. The proposed method explicitly integrates CT kernel and DFOV characteristics into the forward model. Experimental results on clinical data, along with quantitative analysis of the estimated modulation transfer function using wire phantom data, clearly demonstrate the utility of the proposed method in real-time. Additionally, a comparative study with a direct learning network, that lacks forward model information, shows that the proposed method is more robust to DFOV variations.

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