Yuting Niu

Nanoparticles Mimicking Viral Surface Topography for Enhanced Cellular Delivery

Novel silica nanoparticles mimicking virus surface topography are prepared. It is demonstrated that increases in nanoscale surface roughness promote both binding of biomolecules and cellular uptake; thus, the cellular delivery efficiency is significantly increased (scale bars 20 μm).

Biphasic Synthesis of Large‐Pore and Well‐Dispersed Benzene Bridged Mesoporous Organosilica Nanoparticles for Intracellular Protein Delivery

Large pore (4.6-7.6 nm) and well-dispersed benzene bridged mesoporous organosilica nanoparticles with uniform particle size of ≈50 nm are prepared via a biphasic approach. They can be directly used as nanocarriers without surface modification for the intracellular delivery of therapeutic proteins.

Core-Cone Structured Monodispersed Mesoporous Silica Nanoparticles with Ultra-large Cavity for Protein Delivery.

A new type of monodispersed mesoporous silica nanoparticles with a core-cone structure (MSN-CC) has been synthesized. The large cone-shaped pores are formed by silica lamellae closely packed encircling a spherical core, showing a structure similar to the flower dahlia. MSN-CC has a large pore size of 45 nm and a high pore volume of 2.59 cm(3) g(-1). MSN-CC demonstrates a high loading capacity of large proteins and successfully delivers active β-galactosidase into cells, showing their potential as efficient nanocarriers for the cellular delivery of proteins with large molecular weights.

Rod-like mesoporous silica nanoparticles with rough surfaces for enhanced cellular delivery

Novel rod-like mesoporous silica nanoparticles with a rough surface have been prepared with 37% higher cellular uptake and drug delivery efficacy compared to their counterparts with a smooth surface.

Mesoporous Magnesium Oxide Hollow Spheres as Superior Arsenite Adsorbent: Synthesis and Adsorption Behavior

Arsenic contamination in natural water has posed a significant threat to global health due to its toxicity and carcinogenity. Adsorption technology is an easy and flexible method for arsenic removal with high efficiency. In this Article, we demonstrated the synthesis of mesoporous MgO hollow spheres (MgO-HS) and their application as high performance arsenite (As(III)) adsorbent. MgO-HS with uniform particle size (∼180 nm), high specific surface area (175 m(2) g(-1)), and distinguished mesopores (9.5 nm in size) have been prepared by hard-templating approach using mesoporous hollow carbon spheres as templates. An ultrahigh maximum As(III) adsorption capacity (Qmax) of 892 mg g(-1) was achieved in batch As(III) removal study. Adsorption kinetic study demonstrated that MgO-HS could enable As(III) adsorption 6 times faster as a commercial MgO adsorbent. The ultrahigh adsorption capacity and faster adsorption kinetics were attributed to the unique structure and morphology of MgO-HS that enabled fast transformation into a flower-like porous structure composed of ultrathin Mg(OH)2 nanosheets. This in situ formed structure provided abundant and highly accessible hydroxyl groups, which enhanced the adsorption performance toward As(III). The outstanding As(III) removal capability of MgO-HS showed their great promise as highly efficient adsorbents for As(III) sequestration from contaminated water.

Understanding the contribution of surface roughness and hydrophobic modification of silica nanoparticles to enhanced therapeutic protein delivery

Intracellular protein delivery holds great promise for cancer therapy. In this work, the individual and combined contribution of the surface roughness and hydrophobic modification (octadecyl-group) of silica nanoparticles has been studied in a number of events for cellular delivery of therapeutic proteins, including loading capacity, release behaviour, cellular uptake and endo/lysosomal escape. Both surface roughening and hydrophobic modification enhance the protein adsorption capacity and sustained release, while the contribution from the surface roughness is higher for loading capacity and hydrophobic modification is more effective for sustained protein release. Both structural parameters improve the cellular uptake performance; however the difference in the contribution is cell type-dependent. Only the hydrophobic modification shows a contribution to endo/lysosomal escape, independent of the surface topography. Octadecyl-functionalized rough silica nanoparticles thus show the best performance in therapeutic protein (RNase A) delivery, causing significant cell viability inhibition in different cancer cells among all groups under study.

Shaping Nanoparticles with Hydrophilic Compositions and Hydrophobic Properties as Nanocarriers for Antibiotic Delivery.

Inspired by the lotus effect in nature, surface roughness engineering has led to novel materials and applications in many fields. Despite the rapid progress in superhydrophobic and superoleophobic materials, this concept of Mother Nature’s choice is yet to be applied in the design of advanced nanocarriers for drug delivery. Pioneering work has emerged in the development of nanoparticles with rough surfaces for gene delivery; however, the preparation of nanoparticles with hydrophilic compositions but with enhanced hydrophobic property at the nanoscale level employing surface topology engineering remains a challenge. Herein we report for the first time the unique properties of mesoporous hollow silica (MHS) nanospheres with controlled surface roughness. Compared to MHS with a smooth surface, rough mesoporous hollow silica (RMHS) nanoparticles with the same hydrophilic composition show unusual hydrophobicity, leading to higher adsorption of a range of hydrophobic molecules and controlled release of hydrophilic molecules. RMHS loaded with vancomycin exhibits an enhanced antibacterial effect. Our strategy provides a new pathway in the design of novel nanocarriers for diverse bioapplications.

An approach to prepare polyethylenimine functionalized silica-based spheres with small size for siRNA delivery

A novel approach has been developed to prepare polyethylenimine functionalized hybrid silica spheres with a diameter of ∼10 nm, which show excellent delivery efficiency of siRNA into osteosarcoma cancer cells and human colon cancer cells with a significant cell inhibition comparable to commercial agents.

Size-dependent gene delivery of amine-modified silica nanoparticles

Silica-based nanoparticles are promising carriers for gene delivery applications. To gain insights into the effect of particle size on gene transfection efficiency, amine-modified monodisperse Stöber spheres (NH2-SS) with diameters of 125, 230, 330, 440, and 570 nm were synthesized. The in vitro transfection efficiencies of NH2-SS for delivering plasmid DNA encoding green fluorescent protein (GFP) (pcDNA3-EGFP, abbreviated as pcDNA, 6.1 kbp) were studied in HEK293T cells. NH2-SS with a diameter of 330 nm (NH2-SS330) showed the highest GFP transfection level compared to NH2-SS particles with other sizes. The transfection efficiency was found as a compromise between the binding capacity and cellular uptake performance of NH2-SS330 and pcDNA conjugates. NH2-SS330 also demonstrated the highest transfection efficiency for plasmid DNA (pDNA) with a bigger size of 8.9 kbp. To our knowledge, this study is the first to demonstrate the significance of particle size for gene transfection efficiency in silica-based gene delivery systems. Our findings are crucial to the rational design of synthetic vectors for gene therapy.

Kinetically Controlled Assembly of Nitrogen-Doped Invaginated Carbon Nanospheres with Tunable Mesopores.

Mesoporous hollow carbon nanospheres (MHCS) have been extensively studied owning to their unique structural features and diverse potential applications. A surfactant-free self-assembly approach between resorcinol/formaldehyde and silicon alkoxide has emerged as an important strategy to prepare MHCS. Extending such a strategy to other substituted phenols to produce heterogeneous-atom-doped MHCS remains a challenge due to the very different polymerization kinetics of various resins. Herein, we report an ethylenediamine-assisted strategy to control the cooperative self-assembly between a 3-aminophenol/formaldehyde resin and silica templates. Nitrogen-doped mesoporous invaginated carbon nanospheres (N-MICS) with an N content of 6.18 at %, high specific surface areas (up to 1118 m2  g-1 ), large pore volumes (2.47 cm3  g-1 ), and tunable mesopores (3.7-11.1 nm) have been prepared. When used as electrical double-layer supercapacitors, N-MICS show a high capacitance of 261 F g-1 , an outstanding cycling stability (≈94 % capacitance retention after 10 000 cycles), and a good rate performance.