Xiu‐Ping Yan scite author profile

Interest in magnetic nanoparticles for capturing bacteria arises from a variety of attributes, including the similar size of nanoparticles, magnetic behavior, and attached biomolecules such as proteins and nucleotide probes. Here we report the application of amine-functionalized magnetic nanoparticles (AF-MNPs) for rapid and efficient capture and removal of bacterial pathogens. The AF-MNPs are used without the need for any further modifications with affinity biomolecules. The positive charges on the surface of AF-MNPs can promote strong electrostatic interaction with negatively charged sites on the surface of bacterial pathogens to exhibit efficient adsorptive ability. The hydrophobic interaction between the pendant propyl group of the amine functionality and the bacteria also plays a supplementary role. The amine groups on the surface of the magnetic nanoparticle are robust and inexpensive ligands to ensure a high binding affinity to at least eight different species of Gram-positive and Gram-negative bacteria. The amount of AF-MNPs, pH of phosphate buffer solution, and ionic strength are crucial in mediating fast and effective interactions between AF-MNPs and bacteria. The AF-MNPs allow rapid removal of bacteria from water samples, food matrixes, and a urine sample with efficiency from 88.5% to 99.1%. Though amino group offers less specificity/selectivity than biomolecules such as antibodies, AF-MNPs are attractive for capturing a wide range of bacteria.

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Cationic Covalent Organic Nanosheets for Rapid and Selective Capture of Perrhenate: An Analogue of Radioactive Pertechnetate from Aqueous Solution

Yang

Yan

2019

Environ. Sci. Technol.

204

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Capture of radioactive TcO4 – from nuclear wastes is extremely desirable for waste disposal and environmental restoration. Here, we report the synthesis of hydrolytically stable cationic covalent organic nanosheets (iCON) for efficient uptake of ReO4 –, a nonradioactive surrogate of TcO4 –. The iCON combines cationic guanidine-based knots with hydroxyl anchored neutral edge units and chloride ions loosely bonded in the pores, rendering extremely fast exchange kinetics toward ReO4 – with high uptake capacity of 437 mg g–1 and prominent distribution coefficient of 5.0 × 105. The removal efficiency remains stable over a pH range of 3–12 and allows selective capture of ReO4 – in the presence of excessive competing anions such as NO3 –, CO3 2–, PO4 3– and SO4 2– with good removal efficiency for ReO4 – in a simulated Hanford LAW Melter Recycle Stream. Anion exchange between the ReO4 – in solution and the chloride ion in iCON plays dominant role in the adsorption of ReO4 –. The iCON shows promise for effective removal of radioactive 99Tc from nuclear waste.

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A Room Temperature Ionic Liquid (RTIL)‐Mediated, Non‐Hydrolytic Sol–Gel Methodology to Prepare Molecularly Imprinted, Silica‐Based Hybrid Monoliths for Chiral Separation

et al. 2006

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Xiu‐Ping Yan

Amine-Functionalized Magnetic Nanoparticles for Rapid Capture and Removal of Bacterial Pathogens

Cationic Covalent Organic Nanosheets for Rapid and Selective Capture of Perrhenate: An Analogue of Radioactive Pertechnetate from Aqueous Solution

A Room Temperature Ionic Liquid (RTIL)‐Mediated, Non‐Hydrolytic Sol–Gel Methodology to Prepare Molecularly Imprinted, Silica‐Based Hybrid Monoliths for Chiral Separation

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