Glandular breast dose for monoenergetic and high-energy X-ray beams: MonteCarlo assessment

PURPOSE: To extend the utility of normalized glandular dose (D-gN) calculat ions to higher x-ray energies (up to 120 keV) and to provide the tools for investigators to calculate D-gN values for arbitrary mammographic and x-ray spectra. MATERIALS AND METHODS: Validated Monte Carte methods were used to assess D- gN values. One million x-ray photons (1-120 keV, in 1-keV increments)were i nput to a semicircular breast geometry of thicknesses from 2 to 12 cm and b reast compositions from 0% to 100% glandular. D-gN values for monoenergetic (1-120 keV) x-ray beams, polyenergetic (40-120 kV, tungsten anode) x-ray s pectra, and polyenergetic mammographic spectra were computed. Skin thicknes ses of 4-5 mm were used. RESULTS: The calculated D-gN Values were in agreement within approximately 1%-6% with previously published data, depending on breast composition. D-gN tables were constructed for a variety of x-ray tube anode-filter combinati ons, including molybdenum anode-molybdenum filter, molybdenum anode-rhodium filter, rhodium anode-rhodium filter, tungsten anode-rhodium filter; tungs ten anode-palladium filter, and tungsten anode-silver filter. D-gN values a lso were graphed for monoenergetic beams to 120 keV and for general diagnos tic x-ray beams to 120 kV. CONCLUSION: The tables and graphs may be useful for optimizing mammographic procedures. The higher energy data may be useful for investigations of the potential of dual-energy mammography or for calculation of dose in general diagnostic or computed tomographic procedures.