Intrinsically radiolabeled nanoparticles: an emerging paradigm.

Although chelator-based radiolabeling techniques have been used for decades, concerns about the complexity of coordination chemistry, possible altering of pharmacokinetics of carriers, and potential detachment of radioisotopes during imaging have driven the need for developing a simple yet better technique for future radiolabeling. Here, the emerging concept of intrinsically radiolabeled nanoparticles, which could be synthesized using methods such as hot-plus-cold precursors, specific trapping, cation exchange, and proton beam activation, is introduced. Representative examples of using these multifunctional nanoparticles for multimodality molecular imaging are highlighted together with current challenges and future research directions. Although still in the early stages, design and synthesis of intrinsically radiolabeled nanoparticles has shown attractive potential to offer easier, faster, and more specific radiolabeling possibilities for the next generation of molecular imaging.

[1]  Qian Liu,et al.  Multifunctional rare-earth self-assembled nanosystem for tri-modal upconversion luminescence /fluorescence /positron emission tomography imaging. , 2011, Biomaterials.

[2]  Zhen Cheng,et al.  Harnessing the Power of Radionuclides for Optical Imaging: Cerenkov Luminescence Imaging , 2011, The Journal of Nuclear Medicine.

[3]  Hao Hong,et al.  Chelator-free synthesis of a dual-modality PET/MRI agent. , 2013, Angewandte Chemie.

[4]  Dong Liang,et al.  A chelator-free multifunctional [64Cu]CuS nanoparticle platform for simultaneous micro-PET/CT imaging and photothermal ablation therapy. , 2010, Journal of the American Chemical Society.

[5]  Xiaoyuan Chen,et al.  Molecular imaging in cancer treatment , 2011, European Journal of Nuclear Medicine and Molecular Imaging.

[6]  N. Menguy,et al.  EXAFS and HRTEM evidence for As(III)-containing surface precipitates on nanocrystalline magnetite: implications for As sequestration. , 2009, Langmuir : the ACS journal of surfaces and colloids.

[7]  Sanjiv S Gambhir,et al.  PET of vascular endothelial growth factor receptor expression. , 2006, Journal of nuclear medicine : official publication, Society of Nuclear Medicine.

[8]  Yun Sun,et al.  Fluorine-18-labeled Gd3+/Yb3+/Er3+ co-doped NaYF4 nanophosphors for multimodality PET/MR/UCL imaging. , 2011, Biomaterials.

[9]  Yadong Yin,et al.  Cation Exchange Reactions in Ionic Nanocrystals , 2004, Science.

[10]  Feng Chen,et al.  Synthesis and biomedical applications of copper sulfide nanoparticles: from sensors to theranostics. , 2014, Small.

[11]  Karen L Wooley,et al.  Copper-64-alloyed gold nanoparticles for cancer imaging: improved radiolabel stability and diagnostic accuracy. , 2014, Angewandte Chemie.

[12]  Chulhong Kim,et al.  Porphysome nanovesicles generated by porphyrin bilayers for use as multimodal biophotonic contrast agents. , 2011, Nature Materials.

[13]  Multiply-twinned intermetallic AuCu pentagonal nanorods. , 2014, Chemical communications.

[14]  Kai Liu,et al.  Rapid size-controlled synthesis of dextran-coated, 64Cu-doped iron oxide nanoparticles. , 2012, ACS nano.

[15]  Younan Xia,et al.  Radioluminescent gold nanocages with controlled radioactivity for real-time in vivo imaging. , 2013, Nano letters.

[16]  Yong Ding,et al.  Self-Illuminating 64Cu-Doped CdSe/ZnS Nanocrystals for in Vivo Tumor Imaging , 2014, Journal of the American Chemical Society.

[17]  Weijun Niu,et al.  Comparative in vivo stability of copper-64-labeled cross-bridged and conventional tetraazamacrocyclic complexes. , 2004, Journal of medicinal chemistry.

[18]  W. Cai,et al.  Tumor vasculature targeting: a generally applicable approach for functionalized nanomaterials. , 2014, Small.

[19]  Gang Zheng,et al.  Intrinsically copper-64-labeled organic nanoparticles as radiotracers. , 2012, Angewandte Chemie.

[20]  Shuang Liu Bifunctional coupling agents for radiolabeling of biomolecules and target-specific delivery of metallic radionuclides. , 2008, Advanced drug delivery reviews.

[21]  Jie Zheng,et al.  Near-infrared emitting radioactive gold nanoparticles with molecular pharmacokinetics. , 2012, Angewandte Chemie.

[22]  Qian Liu,et al.  18F-Labeled magnetic-upconversion nanophosphors via rare-Earth cation-assisted ligand assembly. , 2011, ACS nano.

[23]  Abass Alavi,et al.  Emerging role of radiolabeled nanoparticles as an effective diagnostic technique , 2012, EJNMMI Research.

[24]  Yun Sun,et al.  Fluorine-18 labeled rare-earth nanoparticles for positron emission tomography (PET) imaging of sentinel lymph node. , 2011, Biomaterials.

[25]  Jordi Llop,et al.  Biodistribution of different sized nanoparticles assessed by positron emission tomography: a general strategy for direct activation of metal oxide particles. , 2013, ACS nano.

[26]  Y. Liu,et al.  Hydrothermal synthesis of NaLuF4:153Sm,Yb,Tm nanoparticles and their application in dual-modality upconversion luminescence and SPECT bioimaging. , 2013, Biomaterials.

[27]  J. Kreuter,et al.  Distribution and elimination of poly(methyl-2-14C-methacrylate) nanoparticle radioactivity after injection in rats and mice. , 1979, Journal of pharmaceutical sciences.

[28]  M. Honer,et al.  Site-specific and stoichiometric modification of antibodies by bacterial transglutaminase. , 2010, Angewandte Chemie.

[29]  Weibo Cai,et al.  Multimodality Molecular Imaging of Tumor Angiogenesis , 2008, Journal of Nuclear Medicine.

[30]  Jordi Llop,et al.  Tracing nanoparticles in vivo: a new general synthesis of positron emitting metal oxide nanoparticles by proton beam activation. , 2012, The Analyst.

[31]  U. Haberkorn,et al.  Bifunctional chelators in the design and application of radiopharmaceuticals for oncological diseases. , 2012, Current medicinal chemistry.

[32]  Fan Zhang,et al.  Chimeric ferritin nanocages for multiple function loading and multimodal imaging. , 2011, Nano letters.

[33]  Mingyuan Gao,et al.  In situ 111In-doping for achieving biocompatible and non-leachable 111In-labeled Fe3O4 nanoparticles. , 2014, Chemical communications.

[34]  G. Denardo,et al.  Effect of the extent of chelate substitution on the immunoreactivity and biodistribution of 2IT-BAT-Lym-1 immunoconjugates. , 1995, Cancer research.

[35]  Heather M. Hennkens,et al.  Radiometals for combined imaging and therapy. , 2013, Chemical reviews.

[36]  Minghao Sun,et al.  Intrinsically radiolabeled multifunctional cerium oxide nanoparticles for in vivo studies. , 2013, Journal of materials chemistry. B.

[37]  Sanjiv Sam Gambhir,et al.  Positron emission tomography in diagnosis and management of invasive breast cancer: current status and future perspectives. , 2003, Clinical breast cancer.

[38]  Lin-wang Wang,et al.  Selective facet reactivity during cation exchange in cadmium sulfide nanorods. , 2009, Journal of the American Chemical Society.

[39]  M. Young,et al.  Targeting of cancer cells with ferrimagnetic ferritin cage nanoparticles. , 2006, Journal of the American Chemical Society.

[40]  Cunhai Dong,et al.  Cation exchange in lanthanide fluoride nanoparticles. , 2009, ACS nano.

[41]  Yun Sun,et al.  Core-shell lanthanide upconversion nanophosphors as four-modal probes for tumor angiogenesis imaging. , 2013, ACS nano.