The in vivo behavior of copper-64-labeled azamacrocyclic complexes.

The use of copper radioisotopes in imaging and therapy applications has created a greater need for bifunctional chelates (BFCs) for complexing copper radioisotopes to biomolecules. It has been demonstrated that the charge and lipophilicity of the Cu-BFC complex has a significant effect on the in vivo behavior of the radiolabeled Cu-BFC-biomolecule conjugate. To evaluate the effects of charge, stability, and macrocyclic backbone size on the biological behavior of 64Cu complexes, a series of macrocyclic 64Cu complexes have been prepared, and the biodistributions of these agents were evaluated in normal Sprague-Dawley rats. Two macrocyclic backbones, dodecane and tetradecane, were evaluated; cyclen, DOTA, and DO2A were dodecane backbone derivatives, and cyclam, TETA, and et-cyclam were tetradecane backbone derivatives. The biodistributions of the 64Cu-labeled complexes correlated with differences in the size of the macrocycle backbone and the formal charge of the complex. All compounds showed uptake and clearance through the liver and kidneys; however, the positively charged 64Cu complexes showed significantly higher uptake in both of these organs than did the negatively charged or neutral complexes. 64Cu-TETA, a negatively charged complex with the tetradecane backbone, had the most efficient clearance by 24 hours' postinjection. These data suggest that negatively charged complexes may have more favorable clearance properties when used as BFCs.

New hydroxybenzyl and hydroxypyridylmethyl substituted triazacyclononane ligands for use with gallium(III) and indium(III).

The 67Ga(III) and/or 111In(III) complexes of four new hexadentate ligands have been prepared and evaluated in vitro and in vivo. These substituted triazacyclononane ligands bind the metal ion through three tertiary ring nitrogens and three oxygens from pendant phenolic or hydroxypyridyl arms. The hydroxypyridyl moieties increase the aqueous solubility of the metal complexes while retaining a lipophilic character. As indicated by their large positive partition coefficients, the phenolic ligands proved to be significantly more lipophilic than the hydroxypyridyl ligands. Biodistribution in Sprague-Dawley rats indicated that the more lipophilic phenolic complexes cleared the body primarily through the liver, while the less lipophilic hydroxypyridyl complexes cleared rapidly, primarily through the kidney. To differentiate the clearance characteristics of these radiolabeled compounds, radiochemical purity of selected complexes in vivo was measured. The complexes were evaluated for overall charge in vitro and in vivo, in plasma samples. In addition, plasma and urine were analyzed for possible metabolites. With one exception, each complex was unmetabolized in vivo. All complexes and metabolites formed were neutral in vitro and in vivo. Extended stability in serum of selected radiometal complexes has been measured. Each complex measured was stable to exchange with transferrin, up to 72 h, as expected from the large stability constants of the complexes. The clearance characteristics of the hydroxypyridyl and phenolic ligands, however, were markedly different. The rapid hepatic clearance of the phenolic ligands indicates potential as bifunctional chelates for Ga(III) or In(III).