Hydrodynamically Driven Self-Assembly of Giant Vesicles of Metal Nanoparticles for Remote-Controlled Release

Structural parameters of nanoparticles affecting their toxicity for biomedical applications: a review

Rapidly growing interest in using nanoparticles (NPs) for biomedical applications has increased concerns about their safety and toxicity. In comparison with bulk materials, NPs are more chemically active and toxic due to the greater surface area and small size. Understanding the NPs' mechanism of toxicity, together with the factors influencing their behavior in biological environments, can help researchers to design NPs with reduced side effects and improved performance. After overviewing the classification and properties of NPs, this review article discusses their biomedical applications in molecular imaging and cell therapy, gene transfer, tissue engineering, targeted drug delivery, Anti-SARS-CoV-2 vaccines, cancer treatment, wound healing, and anti-bacterial applications. There are different mechanisms of toxicity of NPs, and their toxicity and behaviors depend on various factors, which are elaborated on in this article. More specifically, the mechanism of toxicity and their interactions with living components are discussed by considering the impact of different physiochemical parameters such as size, shape, structure, agglomeration state, surface charge, wettability, dose, and substance type. The toxicity of polymeric, silica-based, carbon-based, and metallic-based NPs (including plasmonic alloy NPs) have been considered separately.

Vesicular self-assembly of copolymer-grafted nanoparticles with anisotropic shapes

Plasmonic nanovesicles show broad applications in areas such as cancer theranostics and drug delivery, but the preparation of nanovesicles from shaped nanoparticles remains challenging. This article describes the vesicular self-assembly of shaped nanoparticles, such as gold nanocubes grafted with amphiphilic block copolymers, in selective solvents. The nanocubes assembled within the vesicular membranes exhibit two distinctive packing modes, namely square-like and hexagonal packing, depending on the relative dimensions of the copolymer ligands and nanocubes. The corresponding optical properties of the plasmonic nanovesicles can be tuned by varying the length of the grafted copolymers and the size of the nanocubes. This work provides guidance for the fabrication of functional plasmonic vesicles for applications in catalysis, nanomedicines and optical devices.

Recent Advances in Microfluidics for the Preparation of Drug and Gene Delivery Systems

Drug delivery systems (DDSs) have great potential for improving the treatment of several diseases, especially microbial infections and cancers. However, the formulation procedures of DDSs remain challenging, especially at the nanoscale. Reducing batch-to-batch variation and enhancing production rate are some of the essential requirements for accelerating the translation of DDSs from a small scale to an industrial level. Microfluidic technologies have emerged as an alternative to the conventional bench methods to address these issues. By providing precise control over the fluid flows and rapid mixing, microfluidic systems can be used to fabricate and engineer different types of DDSs with specific properties for efficient delivery of a wide range of drugs and genetic materials. This review discusses the principles of controlled rapid mixing that have been employed in different microfluidic strategies for producing DDSs. Moreover, the impact of the microfluidic device design and parameters on the type and properties of DDS formulations was assessed, and recent applications in drug and gene delivery were also considered.

Quantitative Study of the Nonlinearly Enhanced Photoacoustic/Photothermal Effect by Strong LSPR-Coupled Nanoassemblies

The extensive exploration of the collective optical and thermal effects for localized surface plasmon resonance (LSPR)-coupled nanoassemblies has propelled much recent research and development in fields of photoacoustic (PA) imaging and photothermal (PT) therapy, while the rational design and proper engineering of these assemblies under quantitative guidance is still a highly challenging task. In this work, by utilizing the finite element analysis (FEA) method and taking gold nanochains as example, the authors quantitatively studied the coupling optical/thermal response of the nanoassemblies and the associated nonlinearly enhanced PA/PT effect. Results show that compared with their individuals, the strong electromagnetic/thermal coupling between the individuals of the nanoassemblies results in a several-time enhancement of the per-particle-weighted optical absorption, consequential thermal field enhancement, and initial PA pressure, resulting in nonlinearly amplified energy conversion from incident light to heat and PA waves. The dependence of the nonlinear PA/PT enhancement on the assembly chain length, the size of the individuals, the interparticle distance, and the size uniformity of the building blocks is quantitatively discussed. PA experiments on gold nanochains and gold nanospheres are performed to validate the proposition, and the experiments well silhouetted the theoretical discussion. This work paves the way for the rational construction and optimization of plasmonic nanoassemblies with improved PA/PT conversion efficiency.

Short peptide mediated self-assembly of platinum nanocrystals with selective spreading property

Nanosize spherical assemblies of platinum nanocrystals with core/shell configurations and selective spreading properties are prepared through short peptide mediation.

Folding Up of Gold Nanoparticle Strings into Plasmonic Vesicles for Enhanced Photoacoustic Imaging

The stepwise self-assembly of hollow plasmonic vesicles with vesicular membranes containing strings of gold nanoparticles (NPs) is reported. The formation of chain vesicles can be controlled by tuning the density of the polymer ligands on the surface of the gold NPs. The strong absorption of the chain vesicles in the near-infrared (NIR) region leads to a much higher efficiency in photoacoustic (PA) imaging than for non-chain vesicles. The chain vesicles were further employed for the encapsulation of drugs and the NIR light triggered release of payloads. This work not only offers a new platform for controlling the hierarchical self-assembly of NPs, but also demonstrates that the physical properties of the materials can be tailored by controlling the spatial arrangement of NPs within assemblies to achieve a better performance in biomedical applications.

Loading and triggered release of cargo from hollow spherical gold nanoparticle superstructures

Hollow spherical gold nanoparticle superstructures having different average diameters (∼75 nm and ∼150 nm) and near-infrared (NIR) extinction were loaded with the anti-cancer drug, doxorubicin (DOX), and enzyme- and NIR-triggered DOX release were monitored.

Simultaneous synthesis and assembly of noble metal nanoclusters with variable micellar templates

Simultaneous synthesis and assembly of Au, Pt, and Pd nanoclusters (NCs; with sizes ≤3 nm) into mesoscale structures with defined boundaries are achieved using their metal halides, cetyltrimethylammonium bromide (CTAB), and thiourea (Tu). Geometric shape, hierarchical organization, and packing density of resultant assemblages vary depending on metal precursors and CTAB concentration. For example, rod- or tube-like assemblages are formed from Au NCs, giant vesicles and/or dandelion-like assemblages from Pt NCs, and rhombic/hexagonal platelet assemblages from PdS NCs and Pd NCs. These assemblages inherit pristine shapes from their respective variable micelles of CTA(+)-metal halide complexes. Owing to dynamical nature, the assembled NCs demonstrate various structural reforming behaviors. The metal halides, which serve as counterions of positively charged surfactant heads, screen the electrostatic repulsion among the surfactant molecules as well as the micelles, providing the driving force for the formation of soft templates. Meanwhile, the formation of NCs can be addressed from the perspective of nucleation and growth kinetics. The unique protecting role of surface sulfur, controlled release of S(2-) from Tu, and formation of NCs of metal sulfides as intermediates together lead to a relatively low rate-ratio of growth to nucleation and thus limit the size of product NCs. Our preliminary study also indicates that the assembled noble metal NCs have high catalytic activity and recyclability. In this regard, the present approach not only provides a facile means to construct NC-based metal catalysts but serves also as a simple way to visualize interaction and evolution of micelles of CTA(+)-metal halide complexes.