The capture and safe storage of radiological iodine (I-129) from nuclear fuel reprocessing is of concern due to its long half-life and potential mobility in the environment. The development of durable waste forms in which to store captured iodine requires materials that are both compatible with the iodine capture phases and durable to repository environments. To that end, Sandia is developing a low-temperature sintering Bi-Si-Zn oxide glass composite material (GCM) waste form and herein presents results of durability testing. Furthermore, durability studies were extended to both the occluded iodine capture material Ag-Zeolite (Mordenite, MOR) as well as the GCM, synthesized with compositional variations including: amount of Ag flake added, AgI-MOR particle size in the GCM, and mass loading of I within the AgI-MOR. Product consistency test (PCT-B), chemical durability (MCC-1) tests, and single-pass flow-through (SPFT) tests, were performed on both the individual components of the GCM and the completed GCMs. Durability tests indicate low GCM dissolution rates (<10(-3)g/m(2)d) across wide variable ranges including: pH, AgI-MOR loading, I loading, and AgI-MOR particle size. Results indicate that the Bi-Si-Zn oxide glass matrix sharply limits the release of iodine from the otherwise relatively fast degrading AgI-MOR getter material. Furthermore, the formation of an amorphous AgI phase during sintering of the GCM results in the limitation of iodine release during waste form degradation. Durability of GCM and release rates approximate those of established nuclear waste glasses, or analogues such as basaltic glass. This suggests that the Bi-Si-Zn GCM is a viable candidate as a repository iodine waste form.