Low-dose, high-resolution CT of infant-sized lungs via propagation-based phase contrast

Abstract

Many lung diseases and abnormalities require detailed visualisation of the lungs for accurate diagnosis and treatment. High-resolution computed tomography (CT) is the gold-standard technique for non-invasive lung disease detection, but it presents a risk to the patient through the relatively high ionising radiation dose required. Utilising the X-ray phase information may allow improvements in image resolution at equal or lower radiation levels than current clinical imaging. Propagation-based phase-contrast imaging requires minimal adaption of existing medical systems, and is well suited to lung imaging due to the strong phase gradients introduced by the lung-air material interface. Herein, propagation-based phase contrast CT is demonstrated for large animals, namely lambs, as a model for paediatric patients, using monochromatic radiation and a photon-counting detector at the Imaging and Medical Beamline of the Australian Synchrotron. Image quality, normalised against radiation dose, was optimised as a function of the beam energy and propagation distance, with the optimal conditions used to test the available image quality at very low radiation dose. Noise-limited spatial resolution was measured using Fourier ring correlation, and dosimetry was performed through Monte Carlo simulation calibrated against air kerma. The resulting CT images demonstrate superior resolution to existing high-resolution CT systems, pushing dose to the quantum limit to comply with current Australian guidelines for infant chest CT exposure (<2.5 mSv effective dose). Constituent raw projections are shown to have significant proportions of pixels with zero photon counts that would create severe information loss in conventional CT, which was prevented through phase retrieval.