Predicting Image Properties in Penalized-Likehood Reconstructions of Flat-Panel CBCT.

PURPOSE: Model-based iterative reconstruction (MBIR) algorithms such as penalized-likelihood (PL) methods exhibit data-dependent and shift-variant properties. Image quality predictors have been derived to prospectively estimate local noise and spatial resolution, facilitating both system hardware design and tuning of reconstruction methods. However, current MBIR image quality predictors rely on idealized system models, ignoring physical blurring effects and noise correlations found in real systems. In this work, we develop and validate a new set of predictors using a physical system model specific to at-panel cone-beam CT (FP-CBCT).

METHODS: Physical models appropriate for integration with MBIR analysis are developed and parameterized to represent non-idealities in FP projection data including focal-spot blur, scintillator blur, detector aperture effect, and noise correlations. Flat-panel-specific predictors for local spatial resolution and local noise properties in PL reconstructions are developed based on these realistic physical models. Estimation accuracy of conventional (idealized) and FP-specific predictors are investigated and validated against experimental CBCT measurements using specialized phantoms.

RESULTS: Validation studies show that at-panel-specific predictors can accurately estimate the local spatial resolution and noise properties, while conventional predictors show significant devia-tions in the magnitude and scale of the spatial resolution and local noise. The proposed predictors show accurate estimations over a range of imaging conditions including varying x-ray technique and regularization strength. The conventional spatial resolution prediction is sharper than ground truth. Using conventional spatial resolution predictor, the full width at half maximum (FWHM) of local point spread function (PSF) is underestimated by 0.2 mm. This mismatch is mostly elim-inated in FP-specific prediction. The general shape and amplitude of local noise power spectrum (NPS) FP-specific predictions are consistent with measurement, while the conventional predictions underestimated the noise level by 70%.

CONCLUSION: The proposed image quality predictors permit accurate estimation of local spatial res-olution and noise properties for PL reconstruction, accounting for dependencies on the system geom-etry, x-ray technique, and patient-specific anatomy in real FP-CBCT. Such tools enable prospective analysis of image quality for a range of goals including novel system and acquisition design, adaptive and task-driven imaging, and tuning of MBIR for robust and reliable behavior. This article is protected by copyright. All rights reserved.