Magnesium-doped lithium manganese oxide composite with mesoporous silica for methylene blue dye and heavy metal removal.

In this study, magnesium-doped lithium manganese oxide nanoparticles were prepared through a solid-state reaction technique, and their surface was modified with mesoporous silica. The surface-modified material exhibited a significantly enhanced BET surface area from 5.791 to 66.

Biofouling dynamics and antifouling innovations: Transitioning from traditional biocides to nanotechnological interventions.

Biofouling is a common phenomenon caused by waterborne organisms such as bacteria, diatoms, mussels, barnacles, algae, etc., accumulating on the surfaces of engineering structures submerged under water. This leads to corrosion of such surfaces and decreases their moving efficiency.

Comprehensive Analysis of the NHX Gene Family and Its Regulation Under Salt and Drought Stress in Quinoa ( Willd.).

: Abiotic stresses such as salinity and drought significantly constrain crop cultivation and affect productivity. Quinoa ( Willd.), a facultative halophyte, exhibits remarkable tolerance to drought and salinity stresses, making it a valued model for understanding stress adaptation mechanisms.

Leveraging Long-Life Alkaline Redox Flow Batteries Using Durable and High-Hydroxide Exchange N-Bridged Triazine Framework Membranes.

Fluorine-free organic framework polyelectrolyte membranes showing near frictionless ionic conductivities are gaining cognitive insights. However, the co-precipitation of COFs in the membranes often brings trade-offs to commission long-life electrochemical energy storage solutions. Herein, a durable and ionically miscible dual-ion exchange membrane based on triazine organic framework (TOF) is designed for alkaline redox flow batteries (RFB).

Enhancing growth, yield, essential oil content, and composition of holy basil (Ocimum tenuiflorum L.) using red algae-based bio-stimulant under acidic conditions of the Western Himalayas.

Background: The rising costs of synthetic fertilizers highlight the need for eco-friendly alternatives to enhance essential oil production in aromatic plants. This study evaluated the effects of red algae seaweed extract [Solieria chordalis (C. Agardh) J.

Development and validation of a robust single extraction method for analysis of PAHs, HBCD, BDE, and PCBs in the coastal environment.

Monitoring persistent organic pollutants (POPs) with endocrine-disrupting properties poses significant analytical challenges due to labor-intensive, costly, and environmentally unsustainable procedures. This study developed an efficient and robust approach for the simultaneous detection of diverse groups of semi-volatile organics in water and sediment samples using gas chromatography-tandem mass spectrometry (GC-MS). Two extraction methods were studied for determining POPs in water and sediments.

Characterization, Bio-Prospection, and Comparative Metagenomics of Bacterial Communities Revealing the Predictive Functionalities in Wild and Cultured Samples of Industrially Important Red Seaweed Gracilaria dura.

The present study explores the microbial community associated with the industrially important red seaweed Gracilaria dura to determine the diversity and biotechnological potential through culture and metagenomics approaches. In the first part of the investigation, we isolated and characterized 75 bacterial morphotypes, with varied colony characteristics and metabolic diversity from the wild seaweed. Phylogenetic analysis identified isolates in Proteobacteria, Firmicutes, and Actinobacteria, with Bacillus sp.

Copper catalyzed C(sp)-H/C(sp)-H cross-coupling of arylacetic acid equivalents with methylarenes α-carbonyl radicals.

Arylacetic acid equivalents bearing a pyridine group undergo C(sp)-H/C(sp)-H cross coupling with diverse methylarenes in the presence of a copper based catalyst system. The reaction proceeds the formation of α-carbonyl radicals giving access to α,β-diarylpropionic acids. Preliminary study suggests that the catalyst system is capable of transforming arylbenzyl ketones into 1,2,3-triaryl ketones.

Empowering Sustainable Energy: Lead-Coated Plastic Chip Electrodes for Effective CO Reduction.

Electrochemical CO reduction is crucial in combatting climate change and advancing sustainable energy practices by converting CO into valuable chemicals and fuels, thereby reducing atmospheric CO levels and enabling the storage and utilization of renewable energy from intermittent sources like solar and wind. The selection of electrode materials and platform design plays a critical role in enhancing reaction efficiency and product selectivity during CO reduction. Various metals, both in their solid forms and coated over substrates, have been used in electrochemical CORR.

Access to Bis-Silylene-Stabilized Group 13 Cations.

Herein, we report the isolation of pyridine moiety-functionalized SiNSi pincer-based bis-silylene ligand () and its reactivity toward various halide precursors (X = Br and I) of group 13 elements (M = Al, Ga, and In). This gave us straightforward access to the SiNSi pincer-coordinated group 13 cations (-). These complexes are duly characterized by single-crystal X-ray diffraction studies, multinuclear magnetic resonance spectroscopy (H, C, and Si), and high-resolution mass spectrometry techniques.

Open-Metal and Carboxamide-Tethered Redox-Active Undulated Framework for Mild-Condition Synthesis of Therapeutic Drugs and Tandem Catalysis with Size-Selectivity.

A mixed-ligand-based thermo-chemically robust and undulated metal-organic framework (MOF) is developed that embraces carboxamide moiety-grafted porous channels and activation-induced generation of open-metal site (OMS). The guest-free MOF acts as an outstanding heterogeneous catalyst in Hantzsch condensation for electronically assorted substrates with low catalyst loading and short duration under greener conditions than the reported materials. Besides Lewis acidic OMS, the carboxamide group activates the substrate via two-point hydrogen bonding, highlighting the effectiveness of custom-made functionalities in this multi-component reaction.

Highly Selective Hydrogenation of Nitriles to Primary Amines without an Additive Using Nanoscale Ni-Ni-bTiO Heterojunctions.

Despite significant progress in the catalytic hydrogenation of nitriles, the persistent challenge of requiring additives to prevent condensation byproducts and achieve selectivity toward primary amines demands urgent attention. In this work, we present an integrated approach utilizing a ligand-bridged Ni-Ti bimetallic complex as a precursor to tune Ni-NiO-NiO(OH) heterojunctions and phases of black titania (bTiO) by controlling pyrolytic conditions. This tailored phase distribution and charge dynamics across heterojunctions create an effective balance of acidic and basic sites, enabling the direct hydrogenation of nitriles to primary amines without the need for additives.

Cobalt-Catalyzed Regioselective C8-H Sulfoxamination of 1-Naphthylamine Derivatives with NH-Sulfoximines.

A simple cobalt-catalyzed, picolinamide-directed C8-H sulfoxamination of 1-naphthalamides with NH-sulfoximines has been developed. This cross-dehydrogenative C-H/N-H coupling reaction offers a facile route to N-arylated sulfoximines, exhibiting high yields, a broad substrate scope, and excellent functional group tolerance and scalability.

Light-Emitting Coordination Polymers: Stimuli-Responsive Gels, PMMA-Based Composite Films, and UV-Shielding.

Lanthanide-based light-emitting coordination polymers (CPs) and CP gels (CPGs) have significance for applications in optical systems, image processing/multiplexing, and optical sensors. In this study, we report two new luminescent CPs (EuL-CP () and TbL-CP ()) and CPGs (EuL-gel () and TbL-gel ()) using lanthanide(III) ions (Ln(III) = Eu(III) and Tb(III)) and 4-(4-carboxyphenyl)-2,2:6,2-terpyridine ligand () capable of forming stable thermoreversible gels. Probable structures of EuL-CP () and TbL-CP () and the formations of EuL-gel () and TbL-gel () are proposed based on adequate computational studies.

Microplastic contamination in Indian rice: A comprehensive characterization and health risk assessment.

In this study, we investigate, for the first time, the abundance, distribution, chemical composition, and exposure of microplastics (MPs) in Indian rice and their impact on human health. The physical and chemical characteristics of MPs were measured using a stereomicroscope, μ-Fourier transform infrared spectroscopy, and μ-Raman spectroscopy. MPs were identified in all samples, with an average abundance of 30.

Bimetallic PdPt Nanoparticles Decorated PES Membranes for Enhanced H Separation.

Hydrogen separation has significant importance in diverse applications ranging from clean energy production to gas purification. Membrane technology stands out as a low-cost and efficient method to address the purpose. The development of efficient gas-sensitive materials can further bolster the membrane's performance.

Unprecedented C-F bond cleavage in perfluoronaphthalene during cobaltocene reduction.

The C-F bond activation of perfluoronaphthalene by 5-SIDipp led to the formation of dicationic salts with two fluorides (3·2HF2 ) or heptafluorodiborate (3·2B2F7) as counter-anions. The anion exchange reaction of 3·2B2F7 with NBuPF afforded a highly luminescent 3·2PF6. The addition of cobaltocene in the reaction mixture of 5-SIDipp and perfluoronaphthalene led to a distinct Co(I) species.

Isolation and purification of esterase enzyme from marine bacteria associated with biodegradation of polyvinyl chloride (PVC).

Polyvinyl chloride (PVC) is the third most produced synthetic plastic and releases the most harmful and lethal environmental component after incineration and landfilling. Few studies on microbial degradation of PVC have been reported but very little knowledge about the enzymes. In the present study, esterase enzyme was isolated and partially purified from marine bacterial isolates (T-1.

Biogenic Ag-doped ZnO nanostructures induced cytotoxicity in luminal A and triple-negative human breast cancer cells.

To evaluate the apoptosis-inducing properties of undoped and silver-doped-zinc-oxide nanoparticles (SDZONs) synthesized using against MCF-7 (Luminal-A) and MDA-MB-231 (Triple-negative) breast cancer cell lines. Nanostructures were developed by facile biohydrothermal method and characterized by x-ray diffraction (XRD), Fourier transform infrared (FTIR), and high resolution transmission electron microscopy (HR-TEM). The comparative effect of doping and dose concentration of nanostructures on cytotoxicity was measured using MTT and trypan-blue-exclusion assay.

5H-benzo[c]fluorene derivative exhibits antiproliferative activity via microtubule destabilization.

Present study aimed at a single component cyclization of 2-benzylidene-1-tetralones for the preparation of 5H-benzo[c]fluorenes and their antiproliferative activity. This ring closure reaction underwent via reductive cyclization in the presence of a sodium borohydride-aluminium chloride system. Ten diverse 5H-benzo[c]fluorene derivatives were prepared and evaluated for antiproliferative activity against three human cancer cell lines by SRB assay.

Agarose Degrading Potential and Whole Genome Sequence Analysis of Marine Bacterium Aliagarivorans sp. Strain DM1 Isolated from the Arabian Sea.

In recent years, agar-degrading bacteria have gained significant interest due to their biotechnological, environmental, microbiological, and industrial applications. Agar poses challenges such as marine waste accumulation, difficult industrial processing, limited natural degradability, and sustainability concerns due to high demand and overharvesting of red algae. The present study addresses the need for efficient agar-degrading microorganisms by isolating Aliagarivorans sp.

Low Fouling Molecular Selective Channels through Self-assembly of Cross-linked Block Copolymer Micelles for Selective Separation of Dye and Salt.

We report the solvent-evaporation and ionic cross-linking mediated self-assembly of the shell cross-linked micelles of the amphiphilic triblock copolymer containing middle poly(methyl methacrylate) block (hydrophobic) and poly(2-dimethylamino)ethyl methacrylate end blocks (hydrophilic) on the membrane substrate to create molecular selective channels. The formation of selective channels on the substrate is attributed to the local increase of micelle concentration upon solvent evaporation, which leads to the core-core hydrophobic interaction. The post-ionic cross-linking of the shell part further reduces the intermicelle distance, thereby creating interstices for selective separation.

Novel nanoformulation for enhanced amphotericin B efficacy and sustained release using vetiver root cellulose nanofibers against Candida albicans.

The formidable antifungal agent, Amphotericin B, is well-known for its potency; however, its clinical application has been significantly limited due to toxicity and poor solubility. This study aims to address these challenges by developing and evaluating a novel nano-cellulose-based formulation of Amphotericin B to enhance its efficacy. Amphotericin B was encapsulated within cellulose nanofibers at varying ratios to optimize formulation parameters, including drug concentration, particle size, zeta potential, and entrapment efficiency.