Effect of metal reconstruction plates on cobalt-60 dose distribution: a predictive formula and clinical implications

Abstract

Purpose: We sought to create a predictive formula for the dose perturbations caused by head and neck reconstruction plates in the delivery of postoperative radiotherapy with 60Co beams.Materials and Methods: The dose perturbation effects of Vitallium and Titanium reconstruction plates and flat metal plates of aluminum (13Al), stainless steel (26Fe), tin (50Sn) and lead (82Pb) irradiated with a 60Co beam were measured in polystyrene phantoms using a film dosimetry system. We then used these results to create formulas to predict the effect of a metal reconstruction plate dependent upon its effective atomic number.Results: Percentage dose increases secondary to back scattering were 10% at 1 mm in front of the Vitallium plate and 40% at the plate while the percentage dose decrease was 29% at the plate and 10% 1 mm behind the plate. For the Titanium plate, the percentage dose increase was 5% at 1 mm in front the plate and 25% at the plate while the percentage dose decrease was 20% at the plate and 5% 1 mm behind the plate. For flat plates the percentage dose increases and decreases, respectively, at the plate surfaces were: 13Al (8%, 6%), 26Fe (35%, 16%), 50Sn (60%, 24%), and 82Pb (85%, 13%). A second order polynomial predicting the back scatter and shadowing effects was created, Y = a + bZ + cZ2, where Z is the effective atomic number of the plate while a, b, and c are the following constants: for back scatter a = 0.854 ± 0.082, b = 0.0212 ± 0.0044, c = −0.00011 ± 0.00004 and for shadowing a = 1.108 ± 0.021, b = −0.0141 ± 0.0011, c = 0.00014 ± 0.00001.Conclusions: It is possible to predict the effect of a metal reconstruction plate upon the delivered postoperative radiotherapy dose. The dose perturbations around the plate only exist for a few millimeters, but this is substantially greater than the thickness of a normal tissue or tumor cell. Perhaps a coating of a low effective atomic number, biologically inert, substance might allow for greater dose homogeneity and decrease the risks of plate failure or tumor recurrence.