Self-assembling supramolecular dendrimer nanosystem for PET imaging of tumors

Significance Nanotechnology-based imaging is expected to bring breakthroughs in cancer diagnosis by improving imaging sensitivity and specificity while reducing toxicity. Here, we developed an innovative nanosystem for positron emission tomography (PET) imaging based on a self-assembling amphiphilic dendrimer. This dendrimer assembled spontaneously into uniform supramolecular nanomicelles with abundant PET reporting units on the surface. By harnessing both dendrimeric multivalence and the “enhanced permeation and retention” (EPR) effect, this dendrimer nanosystem effectively accumulated in tumors, leading to exceedingly sensitive and specific imaging of various tumors, especially those that are otherwise undetectable using the clinical gold reference 2-fluorodeoxyglucose ([18F]FDG). This study illustrates the power of nanotechnology based on self-assembling dendrimers to provide an effective platform for bioimaging and related biomedical applications. Bioimaging plays an important role in cancer diagnosis and treatment. However, imaging sensitivity and specificity still constitute key challenges. Nanotechnology-based imaging is particularly promising for overcoming these limitations because nanosized imaging agents can specifically home in on tumors via the “enhanced permeation and retention” (EPR) effect, thus resulting in enhanced imaging sensitivity and specificity. Here, we report an original nanosystem for positron emission tomography (PET) imaging based on an amphiphilic dendrimer, which bears multiple PET reporting units at the terminals. This dendrimer is able to self-assemble into small and uniform nanomicelles, which accumulate in tumors for effective PET imaging. Benefiting from the combined dendrimeric multivalence and EPR-mediated passive tumor targeting, this nanosystem demonstrates superior imaging sensitivity and specificity, with up to 14-fold increased PET signal ratios compared with the clinical gold reference 2-fluorodeoxyglucose ([18F]FDG). Most importantly, this dendrimer system can detect imaging-refractory low–glucose-uptake tumors that are otherwise undetectable using [18F]FDG. In addition, it is endowed with an excellent safety profile and favorable pharmacokinetics for PET imaging. Consequently, this dendrimer nanosystem constitutes an effective and promising approach for cancer imaging. Our study also demonstrates that nanotechnology based on self-assembling dendrimers provides a fresh perspective for biomedical imaging and cancer diagnosis.

[1]  W. Cai,et al.  Radiolabeled polyoxometalate clusters: Kidney dysfunction evaluation and tumor diagnosis by positron emission tomography imaging. , 2018, Biomaterials.

[2]  E. Laurini,et al.  Enantiomeric and Diastereomeric Self-Assembled Multivalent Nanostructures: Understanding the Effects of Chirality on Binding to Polyanionic Heparin and DNA. , 2018, Angewandte Chemie.

[3]  Jia Li,et al.  Negative dendritic effect on enzymatic hydrolysis of dendrimer conjugates. , 2018, Chemical communications.

[4]  Bruno Larrivée,et al.  Tumor angiogenesis and vascular normalization: alternative therapeutic targets , 2017, Angiogenesis.

[5]  V. Percec,et al.  Mimicking Complex Biological Membranes and Their Programmable Glycan Ligands with Dendrimersomes and Glycodendrimersomes. , 2017, Chemical reviews.

[6]  Karen Campbell,et al.  64Cu-MM-302 Positron Emission Tomography Quantifies Variability of Enhanced Permeability and Retention of Nanoparticles in Relation to Treatment Response in Patients with Metastatic Breast Cancer , 2017, Clinical Cancer Research.

[7]  B. Johansen,et al.  Anti‐angiogenic therapy affects the relationship between tumor vascular structure and function: A correlation study between micro–computed tomography angiography and dynamic contrast enhanced MRI , 2016, Magnetic resonance in medicine.

[8]  P. Kantoff,et al.  Cancer nanomedicine: progress, challenges and opportunities , 2016, Nature Reviews Cancer.

[9]  Thomas,et al.  Cu-MM-302 Positron Emission Tomography Quantifies Variability of Enhanced Permeability and Retention of Nanoparticles in Relation to Treatment Response in Patients with Metastatic Breast Cancer , 2017 .

[10]  Akinori Nakamura,et al.  Brain fluorodeoxyglucose (FDG) PET in dementia , 2016, Ageing Research Reviews.

[11]  Yang Wang,et al.  Mastering Dendrimer Self-Assembly for Efficient siRNA Delivery: From Conceptual Design to In Vivo Efficient Gene Silencing. , 2016, Small.

[12]  M. Filippi,et al.  Novel stable dendrimersome formulation for safe bioimaging applications. , 2015, Nanoscale.

[13]  Andreas Kjær,et al.  Positron Emission Tomography Based Elucidation of the Enhanced Permeability and Retention Effect in Dogs with Cancer Using Copper-64 Liposomes. , 2015, ACS nano.

[14]  Maurizio Fermeglia,et al.  Anticancer drug nanomicelles formed by self-assembling amphiphilic dendrimer to combat cancer drug resistance , 2015, Proceedings of the National Academy of Sciences.

[15]  J. Rossi,et al.  Promoting siRNA delivery via enhanced cellular uptake using an arginine-decorated amphiphilic dendrimer. , 2015, Nanoscale.

[16]  Sanjiv S. Gambhir,et al.  Endoscopic molecular imaging of human bladder cancer using a CD47 antibody , 2014, Science Translational Medicine.

[17]  Yang Wang,et al.  Adaptive amphiphilic dendrimer-based nanoassemblies as robust and versatile siRNA delivery systems. , 2014, Angewandte Chemie.

[18]  M. Filippi,et al.  Dendrimersomes: a new vesicular nano-platform for MR-molecular imaging applications. , 2014, Chemical communications.

[19]  Chun Li,et al.  A targeted approach to cancer imaging and therapy. , 2014, Nature materials.

[20]  Chris Orvig,et al.  Matching chelators to radiometals for radiopharmaceuticals. , 2014, Chemical Society reviews.

[21]  Dean Ho,et al.  Cancer Nanomedicine: From Drug Delivery to Imaging , 2013, Science Translational Medicine.

[22]  R. Jain,et al.  Strategies for advancing cancer nanomedicine. , 2013, Nature materials.

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

[24]  C. Liu,et al.  An amphiphilic dendrimer for effective delivery of small interfering RNA and gene silencing in vitro and in vivo. , 2012, Angewandte Chemie.

[25]  M. Bartholomä Recent developments in the design of bifunctional chelators for metal-based radiopharmaceuticals used in Positron Emission Tomography , 2012 .

[26]  Sanjiv S Gambhir,et al.  A molecular imaging primer: modalities, imaging agents, and applications. , 2012, Physiological reviews.

[27]  Thomas Beyer,et al.  The future of hybrid imaging—part 2: PET/CT , 2011, Insights into imaging.

[28]  M. Klein,et al.  Self-Assembly of Janus Dendrimers into Uniform Dendrimersomes and Other Complex Architectures , 2010, Science.

[29]  C. Anderson,et al.  Coordinating radiometals of copper, gallium, indium, yttrium, and zirconium for PET and SPECT imaging of disease. , 2010, Chemical reviews.

[30]  Mark E. Davis,et al.  Pharmacokinetics and tumor dynamics of the nanoparticle IT-101 from PET imaging and tumor histological measurements , 2009, Proceedings of the National Academy of Sciences.

[31]  S. Gambhir Molecular imaging of cancer with positron emission tomography , 2002, Nature Reviews Cancer.

[32]  Jean-Marie Lehn,et al.  Toward Self-Organization and Complex Matter , 2002, Science.

[33]  R. Pastor,et al.  Molecular Dynamics Simulations of Octyl Glucoside Micelles: Structural Properties , 2000 .

[34]  H. Maeda,et al.  Tumor vascular permeability and the EPR effect in macromolecular therapeutics: a review. , 2000, Journal of controlled release : official journal of the Controlled Release Society.

[35]  E. W. Meijer,et al.  Amphiphilic dendrimers as building blocks in supramolecular assemblies , 1998 .

[36]  J. Odom Handbook of High Resolution Multinuclear NMR , 1982 .