2 research outputs found
Bisphosphonate-Anchored PEGylation and Radiolabeling of Superparamagnetic Iron Oxide: Long-Circulating Nanoparticles for <i>in Vivo</i> Multimodal (T1 MRI-SPECT) Imaging
The efficient delivery of nanomaterials to specific targets for <i>in vivo</i> biomedical imaging is hindered by rapid sequestration by the reticuloendothelial system (RES) and consequent short circulation times. To overcome these two problems, we have prepared a new stealth PEG polymer conjugate containing a terminal 1,1-bisphosphonate (BP) group for strong and stable binding to the surface of ultrasmall-superparamagnetic oxide nanomaterials (USPIOs). This polymer, PEG(5)-BP, can be used to exchange the hydrophobic surfactants commonly used in the synthesis of USPIOs very efficiently and at room temperature using a simple method in 1 h. The resulting nanoparticles, PEG(5)-BP-USPIOs are stable in water or saline for at least 7 months and display a near-zero Ī¶-potential at neutral pH. The longitudinal (<i>r</i><sub>1</sub>) and transverse (<i>r</i><sub>2</sub>) relaxivities were measured at a clinically relevant magnetic field (3 T), revealing a high <i>r</i><sub>1</sub> of 9.5 mM<sup>ā1</sup> s<sup>ā1</sup> and low <i>r</i><sub>2</sub>/<i>r</i><sub>1</sub> ratio of 2.97, making these USPIOs attractive as T1-weighted MRI contrast agents at high magnetic fields. The strong T1-effect was demonstrated <i>in vivo</i>, revealing that PEG(5)-BP-USPIOs remain in the bloodstream and enhance its signal 6-fold, allowing the visualization of blood vessels and vascular organs with high spatial definition. Furthermore, the optimal relaxivity properties allow us to inject a dose 4 times lower than with other USPIOs. PEG(5)-BP-USPIOs can also be labeled using a radiolabeled-BP for visualization with single photon emission computed tomography (SPECT), and thus affording dual-modality contrast. The SPECT studies confirmed low RES uptake and long blood circulation times (<i>t</i><sub>1/2</sub> = 2.97 h). These results demonstrate the potential of PEG(5)-BP-USPIOs for the development of targeted multimodal imaging agents for molecular imaging
Exploiting the Metal-Chelating Properties of the Drug Cargo for <i>In Vivo</i> Positron Emission Tomography Imaging of Liposomal Nanomedicines
The
clinical value of current and future nanomedicines can be improved
by introducing patient selection strategies based on noninvasive sensitive
whole-body imaging techniques such as positron emission tomography
(PET). Thus, a broad method to radiolabel and track preformed nanomedicines
such as liposomal drugs with PET radionuclides will have a wide impact
in nanomedicine. Here, we introduce a simple and efficient PET radiolabeling
method that exploits the metal-chelating properties of certain drugs
(<i>e.g.</i>, bisphosphonates such as alendronate and anthracyclines
such as doxorubicin) and widely used ionophores to achieve excellent
radiolabeling yields, purities, and stabilities with <sup>89</sup>Zr, <sup>52</sup>Mn, and <sup>64</sup>Cu, and without the requirement
of modification of the nanomedicine components. In a model of metastatic
breast cancer, we demonstrate that this technique allows quantification
of the biodistribution of a radiolabeled stealth liposomal nanomedicine
containing alendronate that shows high uptake in primary tumors and
metastatic organs. The versatility, efficiency, simplicity, and GMP
compatibility of this method may enable submicrodosing imaging studies
of liposomal nanomedicines containing chelating drugs in humans and
may have clinical impact by facilitating the introduction of image-guided
therapeutic strategies in current and future nanomedicine clinical
studies