Reversible Modulation of Plasmonic Coupling of Gold Nanoparticles Confined within Swellable Polymer Colloidal Spheres.

Dynamic optical modulation in response to stimuli provides exciting opportunities for designing novel sensing, actuating, and authentication devices. Here, we demonstrate that the reversible swelling and deswelling of crosslinked polymer colloidal spheres in response to pH and temperature changes can be utilized to drive the assembly and disassembly of the embedded gold nanoparticles (AuNPs), inducing their plasmonic coupling and decoupling and, correspondingly, color changes. The multi-responsive colloids are created by depositing a monolayer of AuNPs on the surface of resorcinol-formaldehyde (RF) nanospheres, then overcoating them with an additional RF layer, followed by a seeded growth process to enlarge the AuNPs and reduce their interparticle separation to induce significant plasmonic coupling. This configuration facilitates dynamic modulation of plasmonic coupling through the reversible swelling/deswelling of the polymer spheres in response to pH and temperature changes. The rapid and repeatable transitions between coupled and decoupled plasmonic states of AuNPs enable reversible color switching when the polymer spheres are in colloidal form or embedded in hydrogel substrates. Furthermore, leveraging the photothermal effect and stimuli-responsive plasmonic coupling of the embedded AuNPs enables the construction of hybrid hydrogel films featuring switchable anticounterfeiting patterns, showcasing the versatility and potential of this multi-stimuli-responsive plasmonic system.

Dual-network fiber-hydrogel membrane for osmotic energy harvesting.

Osmotic energy harvesting was a promising way to alleviate energy crisis with reverse electrodialysis (RED) membrane-based technology. Charged hydrogel combined with other materials was an effective strategy to overcome problems, including restricted functional groups and complicated fabrication, but the effect of the respective charges of the two materials combined on the membrane properties has rarely been studied in depth. Herein, a new method was proposed that charged hydrogel was equipped with charged filter paper to form dual network fiber-hydrogel membrane for osmotic energy harvesting, which had excellent ion selectivity (beyond 0.9 under high concentration gradient), high ion transference number and energy conversion efficiency (beyond 32.5% under wide range concentration gradient), good property of osmotic energy conversion (∼4.84 W/m2 under 50-fold KCl and ∼6.75 W/m2 under simulated sea water and river water). Moreover, the power density was attributed to the surface-space charge synergistic effect from large amounts overlapping of electric double layer (EDL), so that the transmembrane ion transport was enhanced. It might be a valid mode to extensively develop the osmotic energy harvesting.

A comparative study on the adsorption behavior and mechanism of pesticides on agricultural film microplastics and straw degradation products.

Straw will degrade into segment, powder and crystalline cellulose, while the agricultural film will degrade into microplastics (MPs) in farmland soils. The specific surface area of these micro-particles increases and many new functional groups are formed in the degradation process, which can be a good vector of pesticides. To more accurately and truly analyze the risk of main imported substances and their degradation products against pollutants in soil, the adsorption behavior and mechanism of four commonly used pesticides on aged polyethylene microplastics (APE), wheat straw segment (WSS), wheat straw powder (WSP), and straw crystalline cellulose (SCC) were analyzed and compared through batch adsorption experiments and infrared spectrum. The adsorption kinetics of four pesticides on MPs and straw degradation products tended to be pseudo-second-order kinetics; the adsorption isotherms of pesticides on APE and SCC tended to fit the Freundlich model, while on WSP and WSS tended to fit the Langmuir model. The adsorption was a spontaneous endothermic increase process, suggesting that the main adsorption force of pesticides on MPs and straw degradation products was hydrophobic diffusion. The adsorption of pesticides against WSP and WSS still had a certain π-π conjugation and electrostatic interaction. And the adsorption amount on the straw degradation products followed the order of WSP > WSS > APE > SCC, presumably related to the specific surface area and pore volume of the adsorbent. As WSP, WSS could adsorb more pesticides, the straw returning to the field can be used for slow-release of pesticides to reduce the dosage of pesticides.

A metal oxide affinity probe derived from MIL-125 for selective enrichment of endogenous phosphopeptides.

Highly effective enrichment of endogenous phosphopeptides from complex biological samples is an essential and crucial theme in the analysis of phosphopeptidomics. Herein, an ordered mesoporous TiO2/C composite (denoted as Ti-MCM) was prepared by the pyrolysis of MIL-125 under a N2 atmosphere. The obtained Ti-MCM possesses a high specific surface area (165 m2 g-1), a uniform pore size (3.75 nm), and a large amount of Ti (46%). By utilizing the selective chelation between Ti-MCM and phosphopeptides, 25 phosphopeptides were detected in α-casein digest after enrichment. The material shows good selectivity even in the presence of 2000-fold excess of interference peptides. It was also used to enrich endogenous phosphopeptides from the complex samples of human serum and saliva and showed a good performance.

Core-shell magnetic bimetallic MOF material for synergistic enrichment of phosphopeptides.

In proteomics, phosphorylation is an important process for protein post-translational modification (PTM), which greatly improves the diversity of proteomes. The PTM regulates almost all physiological and pathological processes such as signal transduction, cell division, proliferation, differentiation and metabolism. The abnormal expression of protein phosphorylation is also associated with cellular metabolic disorders and a range of diseases. However, in mass spectrometry-based phosphorylated peptideomics studies, phosphorylated peptide signals were inhibited by a high abundance of non-phosphorylated peptides; thus, highly selective enrichment was required. In this study, a newly designed material named Fe3O4@MIL(Fe/Ti) was synthesized using a layer-by-layer self-assembly technique that coats the surface of magnetic oxide nanospheres with bimetallic MOF of iron and titanium. The synergistic synthetic coating of the bimetallic MOF gives the material a large surface area and excellent hydrophilicity, which endow the nanoparticles with excellent phosphopeptide enrichment ability, high selectivity (ß-casein/BSA molar ratio 1:500), a low detection limit (3 fmol), high recovery rate (85%), strong binding capacity, size exclusion ability, and ideal batch-to-batch repeatability. For comparison, we used Fe3O4@MIL(Fe/Ti) and two single-metal MOF materials Fe3O4@MIL-100(Fe) and Fe3O4@MIL-125(Ti), to enrich α-casein in the middle. Thus, the iron-titanium bimetallic MOF can not only enrich all the phosphorylated peptides enriched by Fe3O4@MIL-100(Fe) and Fe3O4@MIL-125(Ti), but can also specifically enrich four phosphorylated peptides. Encouraged by the excellent results of characterization and standard protein enrichment, we used this material to analyze human serum and found that bimetallic materials can effectively enrich all four phosphorylated peptides and exclude high molecular proteins. These experimental results indicate that the novel bimetallic MOF is a good candidate to analyze protein phosphorylation in complex samples.