An Oral HS Responsive CuO Nanozyme Platform with Strong ROS/HS Scavenging Capacity for the Treatment of Colitis.

Inflammatory bowel disease involves excess reactive oxygen species (ROS) and hydrogen sulfide (HS) at inflammatory sites. Nanozyme-mediated ROS and HS scavenging therapy is promising for colitis treatment. Here, we synthesized a multiple ROS scavenging CuO nanoparticle and first explored its HS scavenging capacity.

Constrained Heterogeneous CoFeO/ZnO/PMS Fenton-Like System for Industrial Wastewater Remediation with Recyclability and Zero Metal Loss.

Although heterogeneous Fenton-like processes have attracted widespread attention in wastewater treatment, the mass leached active ions lead to secondary pollution and confuse the demarcation of reaction region. By constructing a constrained completely heterogeneous system and highlighting its reaction region concentrated within the slipping plane of particles, this work achieves efficient organic pollutants degradation without leaching of any free active metal components. Based on the Poisson-Boltzmann equation and electric double layer model, the specific existing of the constrained region is confirmed, and this neglected reaction region between solid interface and slipping plane in traditional heterogeneous Fenton-like reaction is clarified firstly.

Inhibition mechanism of leukemia cells HL-60 by exopolysaccharides from Botryococcus braunii in response to high-concentration cobalt.

The influence of metal elements on the biomedical activity of microalgal exopolysaccharides (EPS) remains underexplored. This study examined the antitumor properties of Botryococcus braunii EPS under high cobalt conditions and the role of exogenous 3-indole acetic acid (IAA) in enhancing its activity. Results showed that IAA mitigated cobalt-induced inhibition of B.

Tunable Mechanically Interlocked Semi-Crystalline Networks.

High-performance polymers based on dynamic chemistry have been widely explored for multi-field advanced applications. However, noncovalent sacrificial bond-mediated energy dissipation mechanism causes a trade-off between mechanical toughness and resilience. Herein, we achieved the synchronous boost of seemingly conflicting material properties including mechanical robustness, toughness and elasticity via the incorporation of mechanical chemistry into traditional semi-crystalline networks.

Surface-enhanced Raman spectroscopy: a half-century historical perspective.

Surface-enhanced Raman spectroscopy (SERS) has evolved significantly over fifty years into a powerful analytical technique. This review aims to achieve five main goals. (1) Providing a comprehensive history of SERS's discovery, its experimental and theoretical foundations, its connections to advances in nanoscience and plasmonics, and highlighting collective contributions of key pioneers.

Hydrothermally Constructed MoS/ZnInS Heterostructure for Promotion of Photocatalytic H Evolution.

The integration of the second material with unique properties into original material to fabricate heterostructure represents an effective strategy to enhance photocatalytic H evolution. Herein, we synthesized a MoS/ZnInS heterostructured photocatalyst using a two-step hydrothermal method. The resulting MoS/ZnInS displayed the flower-like morphology formed by staked nanosheets, significantly accelerating photocatalytic H evolution performance.

A Dynamic Metal-Organic Radical Emission System.

Developing new organic radical emission systems and regulating their luminescence properties presents a significant challenge. Herein, we build dynamic and multi-emission band radical luminescence systems by co-assembling inorganic metal salts with carbonyl compounds in ionic liquids. After the assembling, dual-band, and excitation wavelength-dependent emission was observed upon light irradiation, one emission band originates from carbonyl radical after light irradiation, the other band from the ligand-metal charge transfer (LMCT) state, which benefits from the charge transfer from the radicals to the metal salts.

Pyrazole-Mediated On-Surface Synthesis of Nickel/Nickel Oxide Hybrids for Efficient Urea-Assisted Hydrogen Production.

Creating densely functionalized supported materials without aggregation has been one of the ultimate goals for heterogeneous catalysts. Direct conversion of readily available bulk materials into highly dispersed supported materials could be highly beneficial for real applications. In this work, we invented an on-surface synthetic strategy for generating highly loaded and well-dispersed nickel nanoparticles on nickel oxide supports (Ni/NiO).

Creating Single-Crystalline β-CaSiO for High-Performance Dielectric Packaging Substrate.

β-CaSiO based glass-ceramics are among the most reliable materials for electronic packaging. However, developing a CaSiO glass-ceramic substrate with both high strength (>230 MPa) and low dielectric constant (<5) remains challenging due to its polycrystalline nature. The present work has succeeded in synthesizing single-crystalline β-CaSiO for a high-performance glass-ceramic substrate.

A novel dual-step transfer framework based on domain selection and feature alignment for motor imagery decoding.

In brain-computer interfaces (BCIs) based on motor imagery (MI), reducing calibration time is gradually becoming an urgent issue in practical applications. Recently, transfer learning (TL) has demonstrated its effectiveness in reducing calibration time in MI-BCI. However, the different data distribution of subjects greatly affects the application effect of TL in MI-BCI.

Recent Progress in Balancing the Activity, Durability, and Low Ir Content for Ir-Based Oxygen Evolution Reaction Electrocatalysts in Acidic Media.

Proton exchange membrane (PEM) electrolysis faces challenges associated with high overpotential and acidic environments, which pose significant hurdles in developing highly active and durable electrocatalysts for the oxygen evolution reaction (OER). Ir-based nanomaterials are considered promising OER catalysts for PEM due to their favorable intrinsic activity and stability under acidic conditions. However, their high cost and limited availability pose significant limitations.

Dual-mode exosome detection leveraging a nanozyme-active artificial receptor: PDA@Fe@Zn-based nucleic acid aptamer sensor.

Exosomes, extracellular vesicles crucial for intercellular communication, are emerging as significant biomarkers for disease diagnosis, especially in cancer. This study presented a dual-mode exosome detection platform using polydopamine microspheres doped with iron and zinc ions (PDA@Fe@Zn). These materials served as both artificial receptors for nucleic acid aptamers and nanozymes with peroxidase-like activity.

Silk Fibroin Hydrogel for Pulse Waveform Precise and Continuous Perception.

Precise and continuous monitoring of blood pressure and cardiac function is of great importance for early diagnosis and timely treatment of cardiovascular diseases. The common tests rely on on-site diagnosis and bulky equipments, hindering early diagnosis. The emerging hydrogels have gained considerable attention in skin bioelectronics by virtue of the similarities to biological tissues and versatility in mechanical, electrical, and biofunctional engineering.

Enhanced liquid-liquid phase separation of stress granules in a reconstructed model and their cytoplasmic targeting using a DNA nanodevice.

Biomolecular condensates (BCs) are crucial membraneless organelles formed through the process of liquid-liquid phase separation (LLPS) involving proteins and nucleic acids. These LLPS processes are tightly linked with essential cellular activities. Stress granules (SGs), functioning as cytoplasmic BCs, play indispensable roles in maintaining cellular homeostasis and are implicated in diseases like cancers and neurodegenerative disorders.

Ginsenoside Rd-Loaded Antioxidant Polymersomes to Regulate Mitochondrial Homeostasis for Bone Defect Healing in Periodontitis.

Periodontitis is the leading cause of tooth loss in adults. Initially triggered by bacterial infection, it is characterized by subsequent dysregulation of mitochondrial homeostasis, leading to ongoing loss of periodontal tissue. Mitophagic flux, a critical physiological mechanism for maintaining mitochondrial homeostasis, is compromised in periodontitis.

Design and synthesis of JNK1-targeted PROTACs and research on the activity.

Kinase dysregulation is greatly associated with cell growth, proliferation, differentiation and apoptosis, which indicates their great potential as therapeutic targets for treatment of numerous progressive disorders, including inflammatory, metabolic and autoimmune disorders, organ fibrosis and cancer. The c‑Jun N‑Terminal Kinase (JNK), as a member of MAPK family, is proved to be a potential target for the treatment of pulmonary fibrosis, which is the most common progressive and fatal fibrotic lung disease. As a new strategy, small-molecule-mediated targeted protein degradation pathway has the advantages of catalytic properties, overcoming drug resistance and expanding target space, which can circumvent the limitations associated with kinase inhibitors.

A-D-A Molecular Design Strategy Enabling Ultrasensitive NIR Vapor Sensing.

Thin-film fluorescent chemosensors, characterized by their tunable design, high selectivity, and exceptional sensitivity, hold significant promise for gas detection applications. However, the simultaneous realization of the 3S attributes (sensitivity, selectivity, and stability) remains a formidable challenge, particularly in the underexplored field of near-infrared (NIR) gas detection. In this work, we employ an acceptor-donor-acceptor (A-D-A) molecular design strategy to drive the development of an organic semiconductor fluorescent material with a progressive red shift in the emission wavelength.

Rational design and characterization of enhanced alcohol-inducible synthetic promoters in .

The C1 and C2 alcohols hold great promise as substrates for biomanufacturing due to their low cost and rich resources. is considered a preferred host for methanol and ethanol bioconversion due to its natural utilization of methanol and ethanol. However, the scarcity of strong and tightly regulated alcohol-inducible promoters limits its extended use.

Biodegradable Nanobowls with Controlled Dents.

Nanobowls show promising potential in biomedical applications, such as bioimaging, cargo delivery, and disease theranostics, due to their unique concave structure and interior cavities. However, the lack of biodegradable nanobowls with manipulable size (especially the dent size) still exists as an obstacle for their in-depth exploration and application in biomedical fields. Herein, polypeptide-based nanobowls are successfully obtained by the self-assembly of a graft polypeptide [named TPE-P(GAAzo--GA)] via a solvent-switch method.

Postexercise downregulation of in regulating non-small cell lung cancer progression via the PTEN/AKT signaling pathway.

Background: Research interest into regulation of gene expression by physical activity and its effect on cancer prognosis has intensified. This study investigated the role of an exercise-related gene, , in the progression of non-small cell lung cancer (NSCLC) and its potential as therapy target.

Methods: Using the GSE41914 dataset, which includes data related to exercise, and the Cancer Genome Atlas (TCGA)-NSCLC dataset, we identified differentially expressed genes (DEGs) and selected as a hub gene for further analysis.

The regulatory effect of chitooligosaccharides on islet inflammation in T2D individuals after islet cell transplantation: the mechanism behind abundance and macrophage polarization.

Islet cell transplantation (ICT) represents a promising therapeutic approach for addressing diabetes mellitus. However, the islet inflammation during transplantation significantly reduces the surgical outcome rate, which is related to the polarization of macrophages. Chitooligosaccharides (COS) was previously reported which could modulate the immune system, alleviate inflammation, regulate gut microecology, and repair the intestinal barrier.

Balanced water and heat energy recycling by full evaporation of wastewater (FEW) in dry biorefining processes of lignocellulose biomass.

Lignocellulosic biorefinery technology requires minimum energy consumption and wastewater generation to overcome challenges in industrial applications. This study established a rigorous model and a comprehensive physical property database of dry biorefining process on Aspen Plus platform for production including L-lactic acid, citric acid, sodium sugar acids, amino acid, and ethanol based on the experimental data. Full evaporation of wastewater (FEW) approach was proposed to completely replaced the external steam supply, and significantly reduced the freshwater input by 67% ∼ 85% and wastewater generation by 64% ∼ 89%, depending on the specific products.

Coimmobilized Dual Enzymes in a Continuous Flow Reactor for the Efficient Synthesis of Optically Pure γ/δ-Lactones.

Enzyme catalysis is a promising method for producing chiral chemicals with high stereoselectivity under mild conditions. However, the traditional batch reaction suffers from low enzyme stability, low cofactor recycling, and poor enzyme reusability. Here, we present a continuous-flow method using coimmobilized dual enzymes for the synthesis of chiral γ-/δ-lactones, which are widely used in fragrances and flavors.

Enhanced Acidic Oxygen Evolution Reaction Performance by Anchoring Iridium Oxide Nanoparticles on CoO.

The sluggish kinetics of the anodic process, known as the oxygen evolution reaction (OER), has posed a significant challenge for the practical application of proton exchange membrane water electrolyzers in industrial settings. This study introduces a high-performance OER catalyst by anchoring iridium oxide nanoparticles (IrO) onto a cobalt oxide (CoO) substrate via a two-step combustion method. The resulting IrO@CoO catalyst demonstrates a significant enhancement in both catalytic activity and stability in acidic environments.

Injectable Self-Healing and Anti-Dissolving Low-Molecular-Weight Hydrogels Enabled by Ionic Cross-Linking for Cell Encapsulation.

Injectable behavior is often observed in polymer-based hydrogels yet is rarely achieved in low-molecular-weight hydrogels (LMWHs), the realization of which may boost the development of new soft materials for biomedical applications. Here, we report on injectable self-healing and antidissolving LMWHs that are formed through a simple ionic cross-linking strategy, showing a fundamental application for the encapsulation of living cells. The LMWHs are formed by simply mixing Ca with negatively charged supramolecular polymers.