Effect of x-ray energy on the radiological image quality in propagation-based phase-contrast computed tomography of the breast.
Sarina WanBenedicta D ArhatariYakov I NesteretsSheridan C MayoDarren A ThompsonJane FoxBeena KumarZdenka ProdanovicDaniel HausermannAnton MaksimenkoChristopher HallMatthew R DimmockKonstantin M PavlovDarren LockieMary RickardZiba GadomkarAlaleh AminzadehElham VafaAndrew PeeleHarry M QuineySarah LewisTimur E GureyevPatrick C BrennanSeyedamir Tavakoli TabaPublished in: Journal of medical imaging (Bellingham, Wash.) (2021)
Purpose: Breast cancer is the most common cancer in women in developing and developed countries and is responsible for 15% of women's cancer deaths worldwide. Conventional absorption-based breast imaging techniques lack sufficient contrast for comprehensive diagnosis. Propagation-based phase-contrast computed tomography (PB-CT) is a developing technique that exploits a more contrast-sensitive property of x-rays: x-ray refraction. X-ray absorption, refraction, and contrast-to-noise in the corresponding images depend on the x-ray energy used, for the same/fixed radiation dose. The aim of this paper is to explore the relationship between x-ray energy and radiological image quality in PB-CT imaging. Approach: Thirty-nine mastectomy samples were scanned at the imaging and medical beamline at the Australian Synchrotron. Samples were scanned at various x-ray energies of 26, 28, 30, 32, 34, and 60 keV using a Hamamatsu Flat Panel detector at the same object-to-detector distance of 6 m and mean glandular dose of 4 mGy. A total of 132 image sets were produced for analysis. Seven observers rated PB-CT images against absorption-based CT (AB-CT) images of the same samples on a five-point scale. A visual grading characteristics (VGC) study was used to determine the difference in image quality. Results: PB-CT images produced at 28, 30, 32, and 34 keV x-ray energies demonstrated statistically significant higher image quality than reference AB-CT images. The optimum x-ray energy, 30 keV, displayed the largest area under the curve ( AUC VGC ) of 0.754 ( p = 0.009 ). This was followed by 32 keV ( AUC VGC = 0.731 , p ≤ 0.001 ), 34 keV ( AUC VGC = 0.723 , p ≤ 0.001 ), and 28 keV ( AUC VGC = 0.654 , p = 0.015 ). Conclusions: An optimum energy range (around 30 keV) in the PB-CT technique allows for higher image quality at a dose comparable to conventional mammographic techniques. This results in improved radiological image quality compared with conventional techniques, which may ultimately lead to higher diagnostic efficacy and a reduction in breast cancer mortalities.
Keyphrases
- dual energy
- image quality
- computed tomography
- contrast enhanced
- deep learning
- positron emission tomography
- magnetic resonance
- heavy metals
- convolutional neural network
- magnetic resonance imaging
- high resolution
- optical coherence tomography
- risk assessment
- metabolic syndrome
- pregnant women
- machine learning
- polycystic ovary syndrome
- mass spectrometry
- density functional theory
- breast cancer risk
- childhood cancer
- air pollution
- skeletal muscle
- data analysis
- aqueous solution