Monte Carlo dosimetry for 125I and 60Co in eye plaque therapy

Abstract

Monte Carlo calculations of radiation dosimetry using morse code are performed for ¹²⁵I and ⁶⁰Co point sources in a cylindrical head phantom that simulates the geometry of eye plaque therapy for choroidal melanoma. We obtain the dose variation in the eye at submillimeter intervals over distances as close as 1 mm and up to 2.5 cm from the source. The calculations for ¹²⁵I are performed for the phantom media of water, protein, and a homogenized protein–water mixture simulating the composition of the eye. Relative dose functions for ¹²⁵I for these phantom media are fitted to second‐degree polynomials. Agreement is found with published results. The relative dose function for ⁶⁰Co at eye position in the water head phantom is fitted to a third‐degree polynomial and compared with that for ⁶⁰Co at the center of a large water sphere. A boundary effect due to the head phantom–air interface on the dose distribution for ⁶⁰Co is demonstrated. The dose falloff with distance is faster for the eye geometry compared with the bulk geometry. We also show that the relative dose distributions within the tumor are comparable for ¹²⁵I and ⁶⁰Co by comparing their relative dose functions. This result is consistent with the success of clinical trials of large melanoma treatments with ¹²⁵I plaques.