Abstract
In this note we present the first proof-of-concept results on the potential effectiveness of the edge-illumination x-ray phase contrast method (in its ‘coded-aperture’ based lab implementation) combined with tomosynthesis. We believe that, albeit admittedly preliminary (e.g. we only present phantom work), these results deserve early publication in a note primarily for four reasons. First, we fully modelled the imaging acquisition method, and validated the simulation directly with experimental results. This shows that the implementation of the method in the new geometry is understood, and thus that it will be possible to use the model to simulate more complex scenarios in the future. Secondly, we show that a strong phase contrast signal is preserved in the reconstructed tomosynthesis slices: this was a concern, as the high spatial frequency nature of the signal makes it sensitive to any filtration-related procedure. Third, we show that, despite the non-optimized nature of the imaging prototype used, we can perform a full angular scan at acceptable dose levels and with exposure times not excessively distant from what is required by clinical practice. Finally, we discuss how the proposed phase contrast method, unlike other approaches apart from free-space propagation (which however requires a smaller focal spot, thus reducing the flux and increasing exposure times), can be easily implemented in a tomosynthesis geometry suitable for clinical use. In summary, we find that these technical results indicate a high potential for the combination of the two methods. Combining slice separation with detail enhancement provided by phase effects would substantially increase the detectability of small lesions and/or calcifications, which we aim to demonstrate in the next steps of this study.
Highlights
This note presents preliminary results on the possible combination of two important developments in medical x-ray imaging, namely x-ray phase contrast imaging (XPCi) (Lewis 2004, Bravin et al 2013) and digital tomosynthesis (DTS) (Dobbins and Godfrey 2003, Park et al 2007).Following its introduction either at synchrotrons (Snigirev et al 1995, Ingal and Beliaevskaya 1995) or with microfocal sources (Davis et al 1995, Wilkins et al 1996), XPCi has progressed significantly over recent years
In this note we present the first proof-of-concept results on the potential effectiveness of the edge-illumination x-ray phase contrast method combined with tomosynthesis
We fully modelled the imaging acquisition method, and validated the simulation directly with experimental results. This shows that the implementation of the method in the new geometry is understood, and that it will be possible to use the model to simulate more complex scenarios in the future
Summary
This note presents preliminary results on the possible combination of two important developments in medical x-ray imaging, namely x-ray phase contrast imaging (XPCi) (Lewis 2004, Bravin et al 2013) and digital tomosynthesis (DTS) (Dobbins and Godfrey 2003, Park et al 2007).Following its introduction either at synchrotrons (Snigirev et al 1995, Ingal and Beliaevskaya 1995) or with microfocal sources (Davis et al 1995, Wilkins et al 1996), XPCi has progressed significantly over recent years. Methods have emerged that enable its implementation with conventional, non-microfocal laboratory sources, such as Talbot–Lau interferometry (Pfeiffer et al 2006) and edge-illumination/coded-aperture approaches (Olivo et al 2001, Olivo and Speller 2007a). These methods have the potential to enable the transfer of XPCi into clinical practice. With regards to a tomosynthesis implementation, this set-up simplification is essential as it enables acquiring the various projections by ‘tracking’ the source angular position with a lateral displacement of the pre-sample mask (see below)
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