Scatter radiation in digital tomosynthesis of the breast

Authors

  • Sechopoulos Ioannis,

    1. Department of Radiology and Winship Cancer Institute, Emory University School of Medicine, 1701 Uppergate Drive, Suite 5018, Atlanta, Georgia 30322 and Wallace H. Coulter Department of Biomedical Engineering, Georgia Institute of Technology, 313 Ferst Drive, Atlanta, Georgia 30332
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  • Suryanarayanan Sankararaman,

    1. Department of Radiology and Winship Cancer Institute, Emory University School of Medicine, 1701 Uppergate Drive, Suite 5018, Atlanta, Georgia 30322
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  • Vedantham Srinivasan,

    1. Department of Radiology and Winship Cancer Institute, Emory University School of Medicine, 1701 Uppergate Drive, Suite 5018, Atlanta, Georgia 30322
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  • D'Orsi Carl J.,

    1. Department of Radiology and Winship Cancer Institute, Emory University School of Medicine, 1701 Uppergate Drive, Suite 5018, Atlanta, Georgia 30322
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  • Karellas Andrew

    1. Department of Radiology and Winship Cancer Institute, Emory University School of Medicine, 1701 Uppergate Drive, Suite 5018, Atlanta, Georgia 30322 and Wallace H. Coulter Department of Biomedical Engineering, Georgia Institute of Technology, 313 Ferst Drive, Atlanta, Georgia 30332
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    • a)

      Author to whom correspondence should be addressed. Electronic mail: akarell@emory.edu

Errata

This article is corrected by:

  1. Errata: Erratum: “Scatter radiation in digital tomosynthesis of the breast” [Med. Phys., – (2007)] Volume 34, Issue 9, 3697, Article first published online: 27 August 2007

Abstract

Digital tomosynthesis of the breast is being investigated as one possible solution to the problem of tissue superposition present in planar mammography. This imaging technique presents various advantages that would make it a feasible replacement for planar mammography, among them similar, if not lower, radiation glandular dose to the breast; implementation on conventional digital mammography technology via relatively simple modifications; and fast acquisition time. One significant problem that tomosynthesis of the breast must overcome, however, is the reduction of x-ray scatter inclusion in the projection images. In tomosynthesis, due to the projection geometry and radiation dose considerations, the use of an antiscatter grid presents several challenges. Therefore, the use of postacquisition software-based scatter reduction algorithms seems well justified, requiring a comprehensive evaluation of x-ray scatter content in the tomosynthesis projections. This study aims to gain insight into the behavior of x-ray scatter in tomosynthesis by characterizing the scatter point spread functions (PSFs) and the scatter to primary ratio (SPR) maps found in tomosynthesis of the breast. This characterization was performed using Monte Carlo simulations, based on the Geant4 toolkit, that simulate the conditions present in a digital tomosynthesis system, including the simulation of the compressed breast in both the cranio-caudal (CC) and the medio-lateral oblique (MLO) views. The variation of the scatter PSF with varying tomosynthesis projection angle, as well as the effects of varying breast glandular fraction and x-ray spectrum, was analyzed. The behavior of the SPR for different projection angle, breast size, thickness, glandular fraction, and x-ray spectrum was also analyzed, and computer fit equations for the magnitude of the SPR at the center of mass for both the CC and the MLO views were found. Within mammographic energies, the x-ray spectrum was found to have no appreciable effect on the scatter PSF and on the SPR. Glandular fraction and compressed breast size were found to have a small effect, while compressed breast thickness and projection angle, as expected, introduced large variations in both the scatter PSF and SPR. The presence of the breast support plate and the detector cover plate in the simulations introduced important effects on the SPR, which are also relevant to the scatter content in planar mammography.

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