163 research outputs found
Modeling the Anisotropic Resolution and Noise Properties of Digital Breast Tomosynthesis
Digital breast tomosynthesis (DBT) is a 3D imaging modality in which a reconstruction of the breast is generated from various x-ray projections. Due to the newness of this technology, the development of an analytical model of image quality has been on-going. In this thesis, a more complete model is developed by addressing the limitations found in the previous linear systems (LS) model [Zhao, Med. Phys. 2008, 35(12): 5219-32].
A central assumption of the LS model is that the angle of x-ray incidence is approximately normal to the detector in each projection. To model the effect of oblique x-ray incidence, this thesis generalizes Swank\u27s calculations of the transfer functions of x-ray fluorescent screens to arbitrary incident angles. In the LS model, it is also assumed that the pixelation in the reconstruction grid is the same as the detector; hence, the highest frequency that can be resolved is the detector alias frequency. This thesis considers reconstruction grids with smaller pixelation to investigate super-resolution, or visibility of higher frequencies. A sine plate is introduced as a conceptual test object to analyze super-resolution. By orienting the long axis of the sine plate at various angles, the feasibility of oblique reconstruction planes is also investigated. This formulation differs from the LS model in which reconstruction planes are parallel to the breast support.
It is shown that the transfer functions for arbitrary angles of x-ray incidence can be modeled in closed form. The high frequency modulation transfer function (MTF) and detective quantum efficiency (DQE) are degraded due to oblique x-ray incidence. In addition, using the sine plate, it is demonstrated that a reconstruction can resolve frequencies exceeding the detector alias frequency. Experimental images of bar patterns verified the existence of super-resolution. Anecdotal clinical examples showed that super-resolution improves the visibility of microcalcifications. The feasibility of oblique reconstructions was established theoretically with the sine plate and was validated experimentally with bar patterns.
This thesis develops a more complete model of image quality in DBT by addressing the limitations of the LS model. In future studies, this model can be used as a tool for optimizing DBT
Comparison of different image reconstruction algorithms for Digital Breast Tomosynthesis and assessment of their potential to reduce radiation dose
Tese de mestrado, Engenharia FĂsica, 2022, Universidade de Lisboa, Faculdade de CiĂȘnciasDigital Breast Tomosynthesis is a three-dimensional medical imaging technique that allows the
view of sectional parts of the breast. Obtaining multiple slices of the breast constitutes an advantage
in contrast to conventional mammography examination in view of the increased potential in breast
cancer detectability. Conventional mammography, despite being a screening success, has undesirable
specificity, sensitivity, and high recall rates owing to the overlapping of tissues. Although this new
technique promises better diagnostic results, the acquisition methods and image reconstruction
algorithms are still under research.
Several articles suggest the use of analytic algorithms. However, more recent articles highlight the
iterative algorithmâs potential for increasing image quality when compared to the former. The scope
of this dissertation was to test the hypothesis of achieving higher quality images using iterative
algorithms acquired with lower doses than those using analytic algorithms.
In a first stage, the open-source Tomographic Iterative GPU-based Reconstruction (TIGRE)
Toolbox for fast and accurate 3D x-ray image reconstruction was used to reconstruct the images
acquired using an acrylic phantom. The algorithms used from the toolbox were the Feldkamp, Davis,
and Kress, the Simultaneous Algebraic Reconstruction Technique, and the Maximum Likelihood
Expectation Maximization algorithm.
In a second and final state, the possibility of further reducing the radiation dose using image
postprocessing tools was evaluated. A Total Variation Minimization filter was applied to the images
reconstructed with the TIGRE toolbox algorithm that provided the best image quality. These were then
compared to the images of the commercial unit used for the image acquisitions.
With the use of image quality parameters, it was found that the Maximum Likelihood Expectation
Maximization algorithm performance was the best of the three for lower radiation doses, especially
with the filter. In sum, the result showed the potential of the algorithm in obtaining images with quality
for low doses
Image quality comparison between a phase-contrast synchrotron radiation breast CT and a clinical breast CT: a phantom based study
In this study we compared the image quality of a synchrotron radiation (SR) breast computed tomography (BCT) system with a clinical BCT in terms of contrast-to-noise ratio (CNR), signal-to-noise ratio (SNR), noise power spectrum (NPS), spatial resolution and detail visibility. A breast phantom consisting of several slabs of breast-adipose equivalent material with different embedded targets (i.e., masses, fibers and calcifications) was used. Phantom images were acquired using a dedicated BCT system installed at the Radboud University Medical Center (Nijmegen, The Netherlands) and the SR BCT system at the SYRMEP beamline of Elettra SR facility (Trieste, Italy) based on a photon-counting detector. Images with the SR setup were acquired mimicking the clinical BCT conditions (i.e., energy of 30 keV and radiation dose of 6.5 mGy). Images were reconstructed with an isotropic cubic voxel of 273 ”m for the clinical BCT, while for the SR setup two phase-retrieval (PhR) kernels (referred to as âsmoothâ and âsharpâ) were alternatively applied to each projection before tomographic reconstruction, with voxel size of 57 Ă 57 Ă 50 ”m3. The CNR for the clinical BCT system can be up to 2-times higher than SR system, while the SNR can be 3-times lower than SR system, when the smooth PhR is used. The peak frequency of the NPS for the SR BCT is 2 to 4-times higher (0.9 mmâ1 and 1.4 mmâ1 with smooth and sharp PhR, respectively) than the clinical BCT (0.4 mmâ1). The spatial resolution (MTF10%) was estimated to be 1.3 lp/mm for the clinical BCT, and 5.0 lp/mm and 6.7 lp/mm for the SR BCT with the smooth and sharp PhR, respectively. The smallest fiber visible in the SR BCT has a diameter of 0.15 mm, while for the clinical BCT is 0.41 mm. Calcification clusters with diameter of 0.13 mm are visible in the SR BCT, while the smallest diameter for the clinical BCT is 0.29 mm. As expected, the image quality of the SR BCT outperforms the clinical BCT system, providing images with higher spatial resolution and SNR, and with finer granularity. Nevertheless, this study assesses the image quality gap quantitatively, giving indications on the benefits associated with SR BCT and providing a benchmarking basis for its clinical implementation. In addition, SR-based studies can provide a gold-standard in terms of achievable image quality, constituting an upper-limit to the potential clinical development of a given technique
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