Dynamic CBCT imaging using prior model-free spatiotemporal implicit neural representation (PMF-STINR)

Shao, Hua-Chieh; Mengke, Tielige; Pan, Tinsu; Zhang, You

doi:10.1088/1361-6560/ad46dc

Phys. Med. Biol.

2024

DOI: 10.1088/1361-6560/ad46dc

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Dynamic CBCT imaging using prior model-free spatiotemporal implicit neural representation (PMF-STINR)

Hua-Chieh Shao,

Tielige Mengke,

Tinsu Pan

et al.

Abstract: Objective: Dynamic cone-beam computed tomography (CBCT) can capture high-spatial-resolution, time-varying images for motion monitoring, patient setup, and adaptive planning of radiotherapy. However, dynamic CBCT reconstruction is an extremely ill-posed spatiotemporal inverse problem, as each CBCT volume in the dynamic sequence is only captured by one or a few X-ray projections, due to the slow gantry rotation speed and the fast anatomical motion (e.g., breathing). Approach: We developed a machine lear… Show more

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ρ-NeRF: Leveraging Attenuation Priors in Neural Radiance Field for 3D Computed Tomography Reconstruction

Zhou,

2024

Preprint

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This paper introduces \(\rho\)-NeRF, a self-supervised approach that sets a new standard in novel view synthesis (NVS) and computed tomography (CT) reconstruction by modeling a continuous volumetric radiance field enriched with physics-based attenuation priors. The \(\rho\)-NeRF represents a three-dimensional (3D) volume through a fully-connected neural network that takes a single continuous four-dimensional (4D) coordinate—spatial location \((x,y,z)\) and an initialized attenuation value \((\rho)\)—and outputs the attenuation coefficient at that position. By querying these 4D coordinates along X-ray paths, the classic forward projection technique is applied to integrate attenuation data across the 3D space. By matching and refining pre-initialized attenuation values derived from traditional reconstruction algorithms like Feldkamp-Davis-Kress algorithm (FDK) or conjugate gradient least squares (CGLS), the enriched schema delivers superior fidelity in both projection synthesis and image reconstruction, with negligible extra computational overhead. The paper details the optimization of \(\rho\)-NeRF for accurate NVS and high-quality CT reconstruction from a limited number of projections, setting a new standard for sparse-view CT applications.

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ρ-NeRF: Leveraging Attenuation Priors in Neural Radiance Field for 3D Computed Tomography Reconstruction

Zhou,

2024

Preprint

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Dynamic CBCT imaging using prior model-free spatiotemporal implicit neural representation (PMF-STINR)

Cited by 1 publication

References 71 publications

ρ-NeRF: Leveraging Attenuation Priors in Neural Radiance Field for 3D Computed Tomography Reconstruction

ρ-NeRF: Leveraging Attenuation Priors in Neural Radiance Field for 3D Computed Tomography Reconstruction

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