Encapsulation of α-Particle-Emitting 225Ac3+ Ions Within Carbon Nanotubes.
Academic Article
Overview
abstract
UNLABELLED: (225)Ac(3+) is a generator of α-particle-emitting radionuclides with 4 net α-particle decays that can be used therapeutically. Targeting (225)Ac(3+) by use of ligands conjugated to traditional bifunctional chelates limits the amount of (225)Ac(3+) that can be delivered. Ultrashort, single-walled carbon nanotubes (US-tubes), previously demonstrated as sequestering agents of trivalent lanthanide ions and small molecules, also successfully incorporate (225)Ac(3+). METHODS: Aqueous loading of both (225)Ac(3+) ions and Gd(3+) ions via bath sonication was used to construct (225)Ac@gadonanotubes ((225)Ac@GNTs). The (225)Ac@GNTs were subsequently challenged with heat, time, and human serum. RESULTS: US-tubes internally loaded with both (225)Ac(3+) ions and Gd(3+) ions show 2 distinct populations of (225)Ac(3+) ions: one rapidly lost in human serum and one that remains bound to the US-tubes despite additional challenge with heat, time, and serum. The presence of the latter population depended on cosequestration of Gd(3+) and (225)Ac(3+) ions. CONCLUSION: US-tubes successfully sequester (225)Ac(3+) ions in the presence of Gd(3+) ions and retain them after a human serum challenge, rendering (225)Ac@GNTs candidates for radioimmunotherapy for delivery of (225)Ac(3+) ions at higher concentrations than is currently possible for traditional ligand carriers.
