In Vitro Dissolution of Respirable Aerosols of Industrial Uranium and Plutonium Mixed-oxide Nuclear Fuels

Abstract

Dissolution characteristics of mixed-oxide nuclear fuels are important considerations for prediction of biological behavior of inhaled particles. Four representative industrial mixed-oxide powders were obtained from fuel fabrication enclosures. Studies of the dissolution of Pu, Am and U from aerosol particles of these materials in a serum simulant solution and in 0.1M HCl showed: (1) dissolution occurred at a rapid rate initially and slowed at longer times, (2) greater percentages of U dissolved than Pu or Am: with the dissolution rates of U and Pu generally reflecting the physical nature of the UO₂-PuO₂ matrix, (3) the temperature history of industrial mixed-oxides could not be reliably related to Pu dissolution except for a 3–5% increase when incorporated into a solid solution by sintering at 1750°C, and (4) dissolution in the serum simulant agreed with the in vivo UO₂ dissolution rate and suggested the dominant role of mechanical processes in PuO₂ clearance from the lung. The rapid initial dissolution rate was shown to be related, in part, to an altered surface layer. The advantages and uses of in vitro solubility data for estimation of biological behavior of inhaled industrial mixed oxides, such as assessing the use of chelation therapy and interpretation of urinary excretion data, are discussed. It was concluded that in vitro solubility tests were useful, simple and easily applied to individual materials potentially inhaled by humans.