Zirconium-containing nanoscale coordination polymers for positron emission tomography and fluorescence-guided cargo delivery to triple-negative breast tumors.

Nanoscale coordination polymer (NCP) is a class of hybrid materials formed by self-assembly of metal ions and organic ligands through coordination. The applications of NCP in biomedicine are quite extensive due to the diversity choice of metal ions and organic ligands. Here we designed Zr-P1 NCP based on Zr4+ selected as metal ion nodes and tetrakis(4-carboxyphenyl) ethylene as bridging ligands. Zr-P1 NCP was modified with functionalized pyrene derived polyethylene glycol (Py-PAA-PEG-Mal) on the surface and further conjugated with cRGD for active targeting of integrin αvß3 overexpressed in triple-negative breast cancer. Doxorubicin was loaded on Zr-P1 NCP with encapsulation efficiency up to 22 % for the treatment of triple negative breast cancer. 89Zr-P1 NCP can be used for in vivo tumor imaging due to the fluorescence properties resulting from the enhanced aggregation-induced Emission (AIE) behavior of P1 ligands and its positron emission tomography (PET) capability. Cellular evaluation indicated that the functionalized Zr-P1@PEG-RGD presented a good function for tumor cell targeting imaging and doxorubicin could be targeted to triple negative breast cancer when it was loaded onto Zr-P1@PEG-RGD, which corroborated with the in vivo results. In summary, 89Zr-P1@PEG-RGD can serve as a biocompatible nanoplatform for fluorescence and PET image-guided cargo delivery. STATEMENT OF SIGNIFICANCE: Nanoscale coordination polymer (NCP) is a class of hybrid materials formed by self-assembly of metal ions and organic ligands through coordination. The diversity of available metals and ligand structures upon NCP synthesis plays an advantage in establishing multimodal imaging platforms. Here we designed 89Zr-P1@PEG-RGD NCP based on Zr4+ selected as metal ion nodes and tetrakis(4-carboxyphenyl) ethylene as bridging ligands. 89Zr-P1@PEG-RGD nanomaterials have positron emission tomography (PET) capability due to the incorporation of zirconium-89, which can be used for in vivo tumor imaging with high sensitivity. The chemotherapeutic drug DOX was loaded on Zr-P1 NCP for the treatment of triple-negative breast cancer, and dual modality imaging can provide visual guidance for drug delivery.

The role of alkyl chain length in the melt and solution crystallization of paliperidone aliphatic prodrugs.

Fatty acid-derivative prodrugs have been utilized extensively to improve the physicochemical, biopharmaceutical and pharmacokinetic properties of active pharmaceutical ingredients. However, to our knowledge, the crystallization behavior of prodrugs modified with different fatty acids has not been explored. In the present work, a series of paliperidone aliphatic prodrugs with alkyl chain lengths ranging from C4 to C16 was investigated with respect to crystal structure, crystal morphology and crystallization kinetics. The paliperidone derivatives exhibited isostructural crystal packing, despite the different alkyl chain lengths, and crystallized with the dominant (100) face in both melt and solution. The rate of crystallization for paliperidone derivatives in the melt increases with alkyl chain length owing to greater molecular mobility. In contrast, the longer chains prolong the nucleation induction time and reduce the crystal growth kinetics in solution. The results show a correlation between difficulty of nucleation in solution and the interfacial energy. This work provides insight into the crystallization behavior of paliperidone aliphatic prodrugs and reveals that the role of alkyl chain length in the crystallization behavior has a strong dependence on the crystallization method.

Self-Cross-Linked Chitosan/Albumin-Bound Nanoparticle Hydrogel for Inhibition of Postsurgery Malignant Glioma Recurrence.

The development of chemoimmunotherapy with reduced systemic toxicity using local formulations is an effective strategy for combating tumor recurrence. Herein, we reported a localized hydrogel system for antitumor chemoimmunotherapy, formed by doxorubicin (DXR)-loaded bovine serum albumin (BSA) nanoparticles self-cross-linked with natural polysaccharide chitosan (CS). The drug-loaded hydrogel (DXR-CBGel) with antiswelling performance and prolonged drug-release profile was combined with antiprogrammed cell death protein 1 (aPD-1) as an in situ vaccine for treating glioblastoma multiforme (GBM) lesions. The antiswelling hydrogel system shows excellent biosafety for volume-sensitive GBM lesions. Both the albumin-bound formulation and the in situ gelation design facilitate the local retention and sustained release of DXR to generate long-term chemoimmunotherapy with reduced systemic toxicity. The chemotherapy-induced immunogenic cell death of DXR with the assistance of immunotherapeutic CS can trigger tumor-specific immune responses, which are further amplified by an immune checkpoint blockade to effectively inhibit cancer recurrence. The strategy of combining albumin-bound drug formulation and biocompatible polymer-based hydrogel for localized chemoimmunotherapy shows great potential against postsurgery glioblastoma recurrence.

Multifunctional theragnostic ultrasmall gold nanodot-encapsuled perfluorocarbon nanodroplets for laser-focused ultrasound sequence irradiation (LFSI)-based enhanced tumor ablation.

Despite the substantial potential of focused ultrasound therapy, its efficacy in cancer therapy has been limited due to the high cavitation threshold and safety concerns regarding the use of high-intensity energy pulses. Here, ultrasmall Au nanodot-loaded PEG-modified perfluorocarbon nanodroplets (Au-PFCnDs) were prepared and used as a therapeutic enhancer. A LFSI method was designed to achieve enhanced tumor ablation at a mild focused ultrasound (FUS) energy pulse with the assistance of the instinct photothermal effect of intratumor-permeable ultrasmall Au nanodots under 808 nm NIR laser irradiation. In addition to their therapeutic function, Au-PFCnDs can also generate multimodal images to provide information for tumor surveillance and treatment guidance. The experimental results also showed that the cRGD-targeted Au-PFCnDs could be more efficiently delivered into the tumor and selectively destroy tumors with no observable side effects on normal tissue under LFSI treatment.

Transforming Passive into Active: Multimodal Pheophytin-Based Carbon Dots Customize Protein Corona to Target Metastatic Breast Cancer.

Formation of protein corona on nanomaterials surface in vivo is usually considered as an unpredictable event for a predefined targeted delivery system for malignant cancers. In most situations, these protein coronas substantially change targeting efficiency or even cause adverse reactions which both hinder the clinical translation of the cargo-delivery systems. Active customization of protein corona onto nanomaterials surfaces can benefit their biomedical performances and open up new opportunities in construction of targeted delivery systems. Herein, lipid-PEG/pheophytin carbon dots (LPCDs) are prepared from natural chlorophyll and integrate seamlessly with positron emission tomography imaging, near-infrared fluorescence imaging, and photodynamic therapy capacity. In vitro measurements demonstrate that the LPCDs can actively absorb apolipoproteins into the protein corona to enhance their uptakes in breast cancer cells. In vivo studies confirm that LPCDs can give accurate delineation of metastatic breast cancer foci from surrounding normal tissues with multimodal biomedical functions. The feasibility of using LPCDs as a multimodal imaging and cancer-targeting nanoplatform may provide impetus for developing precise yet facile protein corona-targeted delivery systems for future clinical practice.

Activatable Core-Shell Metallofullerene: An Efficient Nanoplatform for Bimodal Sensing of Glutathione.

Metallofullerenes have attracted considerable attention as potential novel noninvasive high-relaxivity magnetic resonance contrast agents. However, the applications of metallofullerenes as stimuli-responsive biosensors to monitor biological processes are still scarce. Herein, manganese-fullerenes core-shell nanocomposites are prepared via a facile one-pot approach to achieve GSH-activatable magnetic resonance/fluorescence bimodal imaging functions. The nanocomposites initially have a FRET-induced quenched fluorescence, and water-resisting stimulated low T1-MRI contrast. Upon exposure to GSH, collapse of the outer MnO2 shell led to reconstruction of the nanoprobes and subsequently resulted in multicolor fluorescence recovery and longitudinal (T1) relaxivity enhancement (r1 value up to 29.8 mM-1 s-1 at 0.5 T based on Mn ion). Our work demonstrates feasibility of using fullerenes to fabricate activatable probes for molecular imaging of GSH, which may promote the development of new fullerene-based stimuli-responsive multimodal probes for the detection and regulation of particular biological processes in vivo.

Impact of Polymer Enrichment at the Crystal-Liquid Interface on Crystallization Kinetics of Amorphous Solid Dispersions.

Amorphous solid dispersions have been widely used as an effective formulation strategy in the oral delivery of poorly soluble drugs. However, one of the main challenges in the development of amorphous drugs is to maintain their physical stability. The underlying mechanism of amorphous drugs crystallized in polymeric matrices is still poorly understood. Herein, we report the phenomenon of polymer enrichment at the crystal-liquid interface during the crystallization of griseofulvin (GSF) containing poly(ethylene oxide) (PEO). Confocal Raman microscopy, scanning electron microscope (SEM), and energy-dispersive X-ray spectroscopy (EDS) are employed to reveal the heterogeneous distribution of GSF and PEO at the crystal growth front. The concentration of PEO in the polymer-rich phase at the crystal-liquid interface is determined by Raman spectroscopic analysis. At a given temperature, the crystal growth rates of GSF initially increase with increasing the PEO loading in the bulk and then reach a plateau at high polymer loadings. We propose that the crystal growth rates of GSF are predominantly controlled by the local concentration of PEO at the growth front rather than the overall bulk concentration. This study provides the direct evidence of physical mechanisms that contributes to the local phase separation occurred at the crystal-liquid interface, which governs the kinetics of crystal growth in amorphous solid dispersions. These results are important for understanding the crystallization behavior of amorphous solid dispersions and beneficial for the rational design of robust amorphous formulations.

Identification of the B-cell epitopes on N protein of type 2 porcine reproductive and respiratory syndrome virus, using monoclonal antibodies.

Porcine reproductive and respiratory syndrome virus (PRRSV) nucleocapsid protein (N) is the immunodominant region of PRRSV viral proteins. However, B cell epitopes present on N protein have not been well characterized. In this study, The ORF7 gene was amplified by RT-PCR and inserted into the expression vector pET-28a, the constructed pET-28a-N was transformed into Escherichia coli BL21. After expression, purification and identification, the recombined N protein was used as the target to generate monoclonal antibody (mAb). Strains of hybridoma cells secreting anti-N mAbs were obtained by the hybridoma technique. Three of them (named 1G4, 1C6, 3D11) were specifically reacted with PRRSV by IPMA and IFA. To identify the B-cell epitopes within PRRSV N protein, six serial overlapping synthesized peptides (P1-P6) covering the whole region of N were used to define the epitopes recognized by 1G4, 1C6, 3D11. Importantly, after the identification of dot-ELISA and indirect ELISA, we found that 1-15aa was a new epitope which had never been reported before and that it was highly conserved among some HP-PRRSV isolates of type 2 PRRSV. The results of this study might open new perspectives on the detection of PRRSV and have important implications for studing the structure of the N protein.

Positron emission tomography (PET) guided glioblastoma targeting by a fullerene-based nanoplatform with fast renal clearance.

Various carbonaceous nanomaterials, including fullerene, carbon nanotube, graphene, and carbon dots, have attracted increasing attention during past decades for their potential applications in biological imaging and therapy. In this study, we have developed a fullerene-based tumor-targeted positron emission tomography (PET) imaging probe. Water-soluble functionalized C60 conjugates were radio-labeled with 64Cu and modified with cyclo (Arg-Gly-Asp) peptides (cRGD) for targeting of integrin αvß3 in glioblastoma. The specificity of fluorescein-labeled C60 conjugates against cellular integrin αvß3 was evaluated in U87MG (integrin αvß3 positive) and MCF-7 cells (integrin αvß3 negative) by confocal fluorescence microscopy and flow cytometry. Our results indicated that cRGD-conjugated C60 derivatives showed better cellular internalization compared with C60 derivatives without the cRGD attachment. Moreover, an interesting finding on intra-nuclei transportation of cRGD-conjugated C60 derivatives was observed in U87MG cells. In vivo serial PET studies showed preferential accumulation of cRGD-conjugated C60 derivatives at in U87MG tumors. In addition, the pharmacokinetic profiles of these fullerene-based nanoparticles conjugated with cRGD and 1,4,7-triazacyclononane-1,4,7-triacetic acid (NOTA) fit well with the three compartment model. The renal clearance of C60-based nanoparticles is remarkably fast, which makes this material very promising for safer cancer theranostic applications. STATEMENT OF SIGNIFICANCE: Safety is one of the major concerns for nanomedicine and nanomaterials with fast clearance profile are highly desirable. Fullerene is a distinct type of zero-dimensional carbon nanomaterial with ultrasmall size, uniform dispersity, and versatile reactivity. Here we have developed a fullerene-based tumor-targeted positron emission tomography imaging probe using water-soluble functionalized C60 conjugates radio-labeled with 64Cu and modified with cyclo (Arg-Gly-Asp) peptides (cRGD) for glioblastoma targeting. The improved tumor targeting property along with fast renal clearance behavior of C60-based nanoparticles makes this material very promising for future safer cancer theranostic applications.