Gold nanoparticles exhibiting absorption in the desirable near-infrared region are attractive candidates for photothermal therapy (PTT). Furthermore, the construction of one nanoplatform employing gold nanoparticles for complementary therapy is still a great challenge. Here, well-defined unique hollow silica nanostars with encapsulated gold caps (starlike Au@SiO2) are readily synthesized using a sacrificial template method. Ethanolamine-functionalized poly(glycidyl methacrylate) (denoted as BUCT-PGEA) brushes are then grafted controllably from the surface of starlike Au@SiO2 nanoparticles via surface-initiated atom transfer radical polymerization to produce starlike Au@SiO2-PGEA. The photothermal effect of gold caps with a cross cavity can be utilized for PTT. The interior hollow feature of starlike Au@SiO2 nanoparticles endows them with excellent drug loading capability for chemotherapy, while the polycationic BUCT-PGEA brushes on the surface provide good transfection performances for gene therapy, which will overcome the penetration depth limitation of PTT for tumor therapy. Compared with ordinary spherical Au@SiO2-PGEA counterparts, the starlike Au@SiO2-PGEA hybrids with sharp horns favor endocytosis, which can contribute to enhanced antitumor effectiveness. The rational integration of photothermal gold caps, hollow nanostars, and polycations through the facile strategy might offer a promising avenue for complementary cancer therapy.

It is of great significance to develop a multifunctional imaging-guided therapeutic platform with ideal resolution and sensitivity. Notably, rare-earth (RE) nanoparticles are attractive candidates for multimodal imaging due to their unique optical and magnetic properties. In this work, a rational design of hierarchical nanohybrids employing RE-Au hetero-nanostructures is proposed. 1D RE nanorods are adopted as the core to facilitate cellular internalization with the coating of gold nanoshells for photothermal performances. Hydroxyl-rich polycations with low cytotoxicity are grafted onto the surface of RE-Au to produce RE-Au-PGEA (ethanolamine-functionalized poly(glycidyl methacrylate)) nanohybrids with impressive gene transfection capability. Given the virtues of all the components, the feasibility of RE-Au-PGEA for multifunctional photoacoustic, computed tomography, magnetic resonance, upconversion luminescence imaging, and complementary photothermal therapy/gene therapy therapy is investigated in detail in vitro and in vivo. The visualization of the therapeutic processes with comprehensive information renders RE-Au-PGEA nanohybrid an intriguing platform to realize enhanced antitumor efficiency.

The development of new hetero-nanostructures for multifunctional applications in cancer therapy has attracted widespread attention. In this work, we put forward a facile approach to synthesize multifunctional hetero-nanostructures of cellulose nanocrystal (CNC)-gold nanoparticle hybrids wrapped with low-toxic hydroxyl-rich polycations to integrate versatile functions for effective cancer therapy. Biocompatible CNCs with the superior rod-like morphology for high cellular uptake were employed as substrates to flexibly load spherical gold nanoparticles (Au NPs) or gold nanorods (Au NRs) through gold-thiolate bonds, producing hetero-layered nanohybrids of CNC-Au NPs or CNC-Au NRs. Profound hydroxyl-rich cationic gene carrier, CD-PGEA (comprising β-cyclodextrin cores and ethanolamine-functionalized poly(glycidyl methacrylate) arms), was then assembled onto the surface of CNC-Au nanohybrids through host-guest interaction and gold-thiolate bonds, where PEG was employed as the intermediate and spacer. The resultant CNC-Au-PGEA hetero-nanostructures exhibited excellent performances as gene carriers. Furthermore, CNC-Au NR-PGEA comprising Au NRs demonstrated favorable optical absorption properties and were validated for photoacoustic imaging and combined photothermal/gene therapy with considerable antitumor effects. The present work provided a flexible strategy for the construction of new multifunctional hetero-nanostructures with high antitumor efficacy.Download high-res image (220KB)Download full-size image

Due to their unique properties, one-dimensional (1D) magnetic nanostructures are of great significance for biorelated applications. A facile and straightforward strategy to fabricate 1D magnetic structure with special shapes is highly desirable. In this work, well-defined peapod-like 1D magnetic nanoparticles (Fe3O4@SiO2, p-FS) are readily synthesized by a facile method without assistance of any templates, magnetic string or magnetic field. There are few reports on 1D gene carriers based on Fe3O4 nanoparticles. BUCT–PGEA (ethanolamine-functionalized poly(glycidyl methacrylate) is subsequently grafted from the surface of p-FS nanoparticles by atom transfer radical polymerization to construct highly efficient gene vectors (p-FS–PGEA) for effective biomedical applications. Peapod-like p-FS nanoparticles were proven to largely improve gene transfection performance compared with ordinary spherical Fe3O4@SiO2 nanoparticles (s-FS). External magnetic field was also utilized to further enhance the transfection efficiency. Moreover, the as-prepared p-FS–PGEA gene carriers could combine the magnetic characteristics of p-FS to well achieve noninvasive magnetic resonance imaging (MRI). We show here novel and multifunctional magnetic nanostructures fabricated for biomedical applications that realized efficient gene delivery and real-time imaging at the same time.Keywords: gene transfection; magnetic nanoparticles; MRI imaging; peapod-like; polycation

Semiconductor quantum dots (QDs) are considered as ideal fluorescent probes owing to their intrinsic optical properties. It has been demonstrated that the size and shape of nanoparticles significantly influence their behaviors in biological systems. In particular, one-dimensional (1D) nanoparticles with larger aspect ratios are desirable for cellular uptake. Here, we explore a facile and green method to prepare novel 1D wormlike QDs@SiO2 nanoparticles with controlled aspect ratios, wherein multiple QDs are arranged in the centerline of the nanoparticles. Then, an excellent cationic gene carrier, ethanolamine-functionalized poly(glycidyl methacrylate) (denoted by BUCT-PGEA), was in-situ produced via atom transfer radical polymerization on the surface of the QDs@SiO2 nanoparticles to achieve stable surfaces (QDs@SiO2-PGEA) for effective bioapplications. We found that the wormlike QDs@SiO2-PGEA nanoparticles demonstrated much higher gene transfection performance than ordinary spherical counterparts. In addition, the wormlike nanoparticles with larger aspect ratio performed better than those with smaller ratio. Furthermore, the gene delivery processes including cell entry and plasmid DNA (pDNA) escape and transport were also tracked in real time by the QDs@SiO2-PGEA/pDNA complexes. This work realized the integration of efficient gene delivery and real-time imaging within one controlled 1D nanostructure. These constructs will likely provide useful information regarding the interaction of nanoparticles with biological systems.

Favorable physical and chemical properties endow Au nanoparticles (Au NPs) with various biomedical applications. After appropriate surface functionalization, Au NPs could construct promising drug/gene carriers with multiple functions. There is now ample evidence that physicochemical properties, such as size, shape, and surface chemistry, can dramatically influence the behaviors of Au NPs in biological systems. Investigation of these parameters could be fundamentally important for the application of Au NPs as drug/gene carriers. In this work, we designed a series of novel gene carriers employing polycation-functionalized Au NPs with five different morphologies (including Au nanospheres, Au nano-octahedra, arrow-headed Au nanorods, and Au nanorods with different aspect ratios). The effects of the particle size and shape of these different carriers on gene transfection were investigated in detail. The morphology of Au NPs is demonstrated to play an important role in gene transfection. The most efficient gene carriers are those fabricated with arrow-headed Au nanorods. Au nanosphere-based carriers exhibit the poorest performance in gene transfection. In addition, Au nanorods with smaller aspect ratios perform better than longer ones. These results may provide new avenues to develop promising gene carriers and gain useful information on the interaction of Au NPs with biological systems.

Comb-shaped polymeric vectors (SS-PGEADMs) consisting of ethanolamine/cystamine-functionalized poly(glycidyl methacrylate) (SS-PGEA-NH2) backbones and bioreducible poly((2-dimethyl amino)ethyl methacrylate) (PDMEAMA) side chains were prepared by a combination of the ring-opening reaction and atom transfer radical polymerization (ATRP). The SS-PGEA-NH2 backbones, which were prepared via the ring-opening reaction of the pendant epoxide groups of poly(glycidyl methacrylate) with the amine moieties of ethanolamine/cystamine, possess plentiful flanking secondary amine and hydroxyl groups and some flanking disulfide bond-containing cystamine derivatives. The primary amine groups of the cystamine derivatives were activated to produce bromoisobutylryl-terminated SS-PGEA (SS-PGEA-Br) as multifunctional initiators for subsequent ATRP of DMAEMA. The resultant disulfide-linked short PDMEAMA side chains possess pendant tertiary amine groups and are biocleavable. Such SS-PGEADMs can effectively condense pDNA. The cytotoxicity of SS-PGEADMs could be controlled by adjusting the grafting amount of PDMEAMA side chains. In comparison with the pristine SS-PGEA-NH2, the moderate introduction of PDMEAMA side chains can further enhance the gene transfection efficiency in different cell lines. The present approach to well-defined comb-shaped vectors with multifunctional groups could provide a versatile means for tailoring the functional structures of advanced gene/drug vectors.