Modular Polymer-Caged Nanobins as a Theranostic Platform with Enhanced Magnetic Resonance Relaxivity and pH-Responsive Drug Release

Macrotheranostic Probe with Disease-Activated Near-Infrared Fluorescence, Photoacoustic, and Photothermal Signals for Imaging-Guided Therapy

Theranostics provides opportunities for precision cancer therapy. However, theranostic probes that simultaneously turn on their diagnostic signal and pharmacological action only in respond to a targeted biomarker have been less exploited. We herein report the synthesis of a macrotheranostic probe that specifically activates its near-infrared fluorescence (NIRF), photoacoustic (PA), and photothermal signals in the presence of a cancer-overexpressed enzyme for imaging-guided cancer therapy. Superior to the small-molecule counterpart probe, the macrotheranostic probe has ideal biodistribution and renal clearance, permitting passive targeting of tumors, in situ activation of multimodal signals, and effective photothermal ablation. Our study thus provides a macromolecular approach towards activatable multimodal phototheranostics.

Shape-Dependent Relaxivity of Nanoparticle-Based T1 Magnetic Resonance Imaging Contrast Agents

Gold nanostars functionalized with Gd(III) have shown significant promise as contrast agents for magnetic resonance imaging (MRI) because of their anisotropic, branched shape. However, the size and shape polydispersity of as-synthesized gold nanostars have precluded efforts to develop a rigorous relationship between the gold nanostar structure (e.g., number of branches) and relaxivity of surface-bound Gd(III). This paper describes the use of a centrifugal separation method that can produce structurally refined populations of gold nanostars and is compatible with Gd(III) functionalization. Combined transmission electron microscopy and relaxivity analyses revealed that the increased number of nanostar branches was correlated with enhanced relaxivity. By identifying the underlying relaxivity mechanisms for Gd(III)-functionalized gold nanostars, we can inform the design of high-performance MRI contrast agents.

High relaxivity Gd(III)-DNA gold nanostars: investigation of shape effects on proton relaxation

Gadolinium(III) nanoconjugate contrast agents (CAs) have distinct advantages over their small-molecule counterparts in magnetic resonance imaging. In addition to increased Gd(III) payload, a significant improvement in proton relaxation efficiency, or relaxivity (r1), is often observed. In this work, we describe the synthesis and characterization of a nanoconjugate CA created by covalent attachment of Gd(III) to thiolated DNA (Gd(III)-DNA), followed by surface conjugation onto gold nanostars (DNA-Gd@stars). These conjugates exhibit remarkable r1 with values up to 98 mM(-1) s(-1). Additionally, DNA-Gd@stars show efficient Gd(III) delivery and biocompatibility in vitro and generate significant contrast enhancement when imaged at 7 T. Using nuclear magnetic relaxation dispersion analysis, we attribute the high performance of the DNA-Gd@stars to an increased contribution of second-sphere relaxivity compared to that of spherical CA equivalents (DNA-Gd@spheres). Importantly, the surface of the gold nanostar contains Gd(III)-DNA in regions of positive, negative, and neutral curvature. We hypothesize that the proton relaxation enhancement observed results from the presence of a unique hydrophilic environment produced by Gd(III)-DNA in these regions, which allows second-sphere water molecules to remain adjacent to Gd(III) ions for up to 10 times longer than diffusion. These results establish that particle shape and second-sphere relaxivity are important considerations in the design of Gd(III) nanoconjugate CAs.

Magnetic targeting of novel heparinized iron oxide nanoparticles evaluated in a 9L-glioma mouse model

PURPOSE

A novel PEGylated and heparinized magnetic iron oxide nano-platform (DNPH) was synthesized for simultaneous magnetic resonance imaging (MRI) and tumor targeting.

METHODS

Starch-coated magnetic iron oxide nanoparticles ("D") were crosslinked, aminated (DN) and then simultaneously PEGylated and heparinized with different feed ratios of PEG and heparin (DNPH1-4). DNPH products were characterized by Fourier transform infrared spectroscopy (FTIR), transmission electron microscopy (TEM) and superconducting quantum interference device (SQUID). The magentic targeting of DNPH3, with appropriate amounts of conjugated PEG and heparin, in a mouse 9L-glioma subcutaneous tumor model was confirmed by magnetic resonance imaging (MRI)/electron spin resonance (ESR).

RESULTS

DNPH3 showed long circulating properties in vivo (half-life >8 h, more than 60-fold longer than that of parent D) and low reticuloendothelial system (RES) recognition in liver and spleen. Protamine, a model cationic protein, was efficiently loaded onto DNPH3 with a maximum loading content of 26.4 μg/mg Fe. Magnetic capture of DNPH3 in tumor site with optimized conditions (I.D. of 12 mg/kg, targeting time of 45 min) was up to 29.42 μg Fe/g tissue (12.26% I.D./g tissue).

CONCLUSION

DNPH3 showed the potential to be used as a platform for cationic proteins for simultaneous tumor targeting and imaging.

Covalent attachment of Mn-porphyrin onto doxorubicin-loaded poly(lactic acid) nanoparticles for potential magnetic resonance imaging and pH-sensitive drug delivery

In this paper, theranostic nanoparticles (MnP-DOX NPs) were fabricated by conjugating Mn-porphyrin onto the surface of doxorubicin (DOX)-loaded poly(lactic acid) (PLA) nanoparticles (DOX NPs) for potential T1 magnetic resonance imaging and pH-sensitive drug delivery. An in vitro drug release study showed that the release rate of DOX from MnP-DOX NPs was slow at neutral pH but accelerated significantly in acidic conditions. It was found that MnP-DOX NPs could be easily internalized by HeLa cells and effectively suppressed the growth of HeLa cells and HT-29 cells due to the accelerated drug release in acidic lysosomal compartments. Magnetic resonance imaging (MRI) scanning analysis demonstrated that MnP-DOX NPs had much higher longitudinal relaxivity in water (r1 value of 27.8 mM(-1) s(-1) of Mn(3+)) than Mn-porphyrin (Mn(III)TPPS3NH2; r1 value of 6.70 mM(-1) s(-1) of Mn(3+)), behaving as an excellent contrast agent for T1-weighted MRI both in vitro and in vivo. In summary, such a smart and promising nanoplatform integrates multiple capabilities for effective cancer diagnosis and therapy.

Long-circulating heparin-functionalized magnetic nanoparticles for potential application as a protein drug delivery platform

Starch-coated, PEGylated, and heparin-functionalized iron oxide magnetic nanoparticles (DNPH) were successfully synthesized and characterized in detail. The PEGylation (20 kDa) process resulted in an average coating of 430 PEG molecules per nanoparticle. After that, heparin conjugation was carried out to attain the final DNPH platform with 35.4 μg of heparin/mg of Fe. Commercially acquired heparin-coated magnetic nanoparticles were also PEGylated (HP) and characterized for comparison. Protamine was selected as a model protein to demonstrate the strong binding affinity and high loading content of DNPH for therapeutically relevant cationic proteins. DNPH showed a maximum loading of 22.9 μg of protamine/mg of Fe. In the pharmacokinetic study, DNPH displayed a long-circulating half-life of 9.37 h, 37.5-fold longer than that (0.15 h) of HP. This improved plasma stability enabled extended exposure of DNPH to the tumor lesions, as was visually confirmed in a flank 9L-glioma mouse model using magnetic resonance imaging (MRI). Quantitative analysis of the Fe content in excised tumor lesions further demonstrated the superior tumor targeting ability of DNPH, with up to 31.36 μg of Fe/g of tissue (13.07% injected dose (I.D.)/g of tissue) and 7.5-fold improvement over that (4.27 μg of Fe/g of tissue; 1.78% I.D./g of tissue) of HP. Overall, this study shed light on the potential of DNPH to be used as a protein drug delivery platform.

Possible gadolinium ions leaching and MR sensitivity over-estimation in mesoporous silica-coated upconversion nanocrystals

Mesoporous silica (m-SiO2) coated gadolinium (Gd) ions-doped upconversion nanoparticles (UCNPs) are regarded as one of most attractive nano-platforms which hold great potential in future cancer theranostics. The current general synthetic strategy for such promising structures includes the extraction of surfactant molecules in the final step. Here, in this article, we focus our interest on probing the potential influence of hydrochloric acid extraction on lanthanide ions leakage, MR sensitivity over-estimation and the optical intensity weakening of m-SiO2 coated Gd-doped UCNPs. Control experiments provide evidence of inner core damage, Gd(3+) ion release and residual Gd(3+) ions "trapped" within the core@shell structures. Our investigation shows that: (1) the small Gd-doped UCNPs could be fragile and sensitive to the hydrochloric acid-extraction and thermal treatment processes; and (2) the presence of "trapped" Gd(3+) ions not only provokes the concerns of potential cytotoxicity but also interfere with the contrast imaging tests of Gd-doped UCNPs, providing possible erroneous information on the determination of the longitudinal relaxivities of given probes.

Functionalized polymersomes with outlayered polyelectrolyte gels for potential tumor-targeted delivery of multimodal therapies and MR imaging

A novel tumor-targeting polymersome carrier system capable of delivering magnetic resonance imaging (MRI) and chemotherapy is presented in this study. The doxorubicin (DOX)-loaded magnetic polymersomes were first attained by the self-assembly of lipid-containing copolymer, poly(acrylic acid-co-distearin acrylate), in aqueous solution containing citric acid-coated superparamagnetic iron oxide nanoparticles (SPIONs), and followed by DOX loading via electrostatic attraction. To further functionalize these artificial vesicles with superior in vivo colloidal stability, pH-tunable drug release and active tumor-targeting, chitosan and poly(γ-glutamic acid-co-γ-glutamyl oxysuccinimide)-g-poly(ethyleneglycol)-folate (FA) were deposited in sequence onto the assembly outer surfaces. The interfacial nanogel layers via complementary electrostatic interactions and in-situ covalent cross-linking were thus produced. These nanogel-caged polymersomes (NCPs) show excellent anti-dilution and serum proteins-repellent behaviors. Triggerable release of the encapsulated DOX was governed by dual external stimuli, pH and temperature. When these theranostic NCPs were effectively internalized by HeLa cells via FA receptor-mediated endocytosis and then exposed to high frequency magnetic fields (HFMF), the combined effects of both pH and magnetic hyperthermia-triggered drug release and thermo-therapy resulted in greater cytotoxicity than the treatment by DOX alone. By virtue of the SPION clustering effect in the assembly inner aqueous compartments, the SPION/DOX-loaded NCPs displayed an r₂ relaxivity value (255.2 F emM⁻¹ S⁻¹) higher than Resovist (183.4 F emM⁻¹ S⁻¹), a commercial SPION-based T₂ contrast agent. The high magnetic relaxivity of the tumor-targeting NCPs coupled with their enhanced cellular uptake considerably promoted the MRI contrast of targeted cancer cells. These results demonstrate the great potential of the FA-decorated SPION/DOX-loaded NCPs as an advanced cancer theranostic nanodevice.