Purpose We and others have reported that Sarcophagine-based bifunctional chelators could be effectively used in the syntheses of (64)Cu radiopharmaceuticals. The resulted (64)Cu-Sarcophagine complexes demonstrated great in vivo stability. The goal of this study was to further derivatize Sarcophagine cage with amino and maleimide functional groups for conjugation with bioligands.Methods Starting from DiAmSar, three novel chelators (AnAnSar, BaMalSar, and Mal(2)Sar) with two functional groups have been synthesized. Among those, BaMalSar and Mal(2)Sar have been conjugated with cyclic peptide c(RGDyC) (denoted as RGD) and the resulted conjugates, BaMalSar-RGD and Mal(2)Sar-RGD(2) have been labeled with (64)Cu. The tumor targeting efficacy of (64)Cu-labeled RGD peptides were evaluated in a subcutaneous U87MG glioblastoma xenograft model.Results The conjugates, BaMalSar-RGD and Mal(2)Sar-RGD(2) could be labeled with (64)CuCl(2) in 10 min with high purity (>98%) and high radiochemical yield (>90%). Both (64)Cu-BaMalSar-RGD and (64)Cu-Mal(2)Sar-RGD(2) exhibited high tumor uptake and tumor-to-normal tissue ratios.Conclusion Three novel chelators with two functional groups have been developed based on Sarcophagine cage. The platform developed in this study could have broad applications in the design and synthesis of( 64)Cu-radiopharmaceuticals.
Keywords: 64Cu; Integrin αvβ3; RGD; Sarcophagine; microPET.