In vivo stability of supramolecular host-guest complexes monitored by dual-isotope multiplexing in a pre-targeting model of experimental liver radioembolization

Introduction: Cyclodextrin (CD)-based supramolecular interactions have been proposed as nanocarriers for drug delivery. We previously explored the use of these supramolecular interactions to perform targeted hepatic radioembolization. In a two-step procedure the appropriate location of the diagnostic pre-targeting vector can first be confirmed, after which the therapeutic vector will be targeted through multivalent host-guest interactions. Such a procedure would prevent therapeutic errors that come from a mismatch between diagnostic and therapeutic procedures. In the current study we explored the use of dual-isotope imaging to assess the in vivo stability of the formed complex and individual components. Methods: Dual-isotope imaging of the host and guest vectors was performed after labeling of the pre-targeted guest vector, being adamantane (Ad) functionalized macro-aggregated albumin (MAA) particles, with technetium-99m (Tc-99m-MAA-Ad). The host vector, Cy5(0.5)CD(9)PIBMA(39), was labeled with indium-111 (In-111-Cy5(0.5)CD(9)PIBMA(39)). The in situ stability of both the individual vectors and the resulting [MAA-Ad-In-111-Cy5(0.5)CD(9)PIBMA(39)] complexes was studied over 44 h at 37 degrees C in a serum protein-containing buffer. In vivo, the host vector In-111-Cy5(0.5)CD(9)PIBMA(39) was administered two hours after local deposition of Tc-99m-MAA-Ad in mice. Dual-isotope SPECT imaging and quantitative biodistribution studies were performed between 2 and 44 h post intravenous host vector administration. Results: The individual vectors portrayed < 5% dissociation of the radioisotope over the course of 20 h. Dissociation of [MAA-Ad-In-111-Cy5(0.5)CD(9)PIBMA(39)] complexes remained within a 10-20% range after incubation in serum. In vivo dual-isotope SPECT imaging of host-guest interactions revealed co-localization of the tracer components. Quantitative assessment of the biodistribution revealed that the hepatic accumulation of the host vector nearly doubled between 2 h and 44 h post-injection (from 14.9 +/- 6.1% ID/g to 26.2 +/- 2.1% ID/g). Conclusions: Assessment of intra-hepatic host-guest complexation was successfully achieved using dual isotope multiplexing, underlining the complex stability that was found in situ (up to 44 h in serum). Overall, the results obtained in this study highlight the potential of supramolecular chemistry as a versatile platform that could advance the field of nanomedicine.