Surface Functionalization of Magnetic Nanoparticles Using a Thiol-Based Grafting-Through Approach

Biehl, Philip; Schacher, Felix H.

doi:10.3390/surfaces3010011

Cited by 8 publications

(2 citation statements)

References 47 publications

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“…There are two main categories for these types of stabilizing agent a follow: Thiols (Sulfur-containing compounds): Thiols (R-SH) can form strong covalent bonds with certain metal surfaces, such as gold, silver and Platinum NPs. [103][104][105][106][107][108][109] The sulfur atom in the thiol group has a lone pair of electrons that can coordinate with metal atoms on the nanoparticle surface, forming metal-sulfur bonds.…”

Section: Chemical Stabilizationmentioning

confidence: 99%

Nanotechnology in the Fabrication of Advanced Paints and Coatings: Dispersion and Stabilization Mechanisms for Enhanced Performance

Azani,

Hassanpour

2024

ChemistrySelect

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This review comprehensively analyzes the challenge of dispersing and stabilizing of various common nanomaterials (NMs), including TiO₂, SiO₂, Ag, ZnO, graphene, carbon nanotubes (CNTs) and some others, in paints and coatings. It delves into the critical factors influencing dispersion, such as nanoparticle size, shape, concentration, and their distribution within the coating matrix.The review encompasses all stages of dispersion methods, including wetting, separation techniques, and stabilization. Regarding stabilization, both chemical and physical stabilization methods are discussed, along with their mechanisms, involving surface modification or functionalization of NMs, particularly tailored for aqueous and solvent‐based coatings and common resins (Acrylic, Urethane, Epoxy, Alkyd, etc.). Furthermore, common blending methods to fabricate uniform paints, coatings, and nanocomposites (NCPs) are examined. By providing a comprehensive understanding of the mechanisms governing NM dispersion and stabilization, this review facilitates the selection of appropriate surface modifications based on the specific resins or solvents, thereby enabling the fabrication of high‐performance paints and coatings. In summary, this review elucidates the essence of addressing the challenges associated with NM dispersion and stabilization, outlines methodologies employed, discusses findings regarding their effects on coating properties, and recommends tailored approaches for fabricating high‐performance paints and coatings.

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Section: Chemical Stabilizationmentioning

confidence: 99%

Nanotechnology in the Fabrication of Advanced Paints and Coatings: Dispersion and Stabilization Mechanisms for Enhanced Performance

Azani,

Hassanpour

2024

ChemistrySelect

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“…The chemical composition of the nanostructure will contribute to the release of drugs once they reach inside the cell. For example, when medicines are grafted with nanomaterials through thiol groups, these nanostructures can be replaced with glutathione, which remains widely available throughout the cytosol, leading to the unleashing of almost any trapped medication 113 . In situations where the nanomaterial-medication framework is not directly absorbed or internalized into cancer cells as a whole, the drug could now be transported out of the cell, apart from the nanostructure, where it could then reach the cell through direct diffusion and possibly other transport mechanisms 91 .…”

Section: Nanostructures As Carriers For Drug Moleculesmentioning

confidence: 99%

Nanotechnology Advances in the Detection and Treatment of Cancer: An Overview

Mosleh-Shirazi¹,

Abbasi²,

Moaddeli³

et al. 2022

Nanotheranostics

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Over the last few years, progress has been made across the nanomedicine landscape, in particular, the invention of contemporary nanostructures for cancer diagnosis and overcoming complexities in the clinical treatment of cancerous tissues. Thanks to their small diameter and large surface-to-volume proportions, nanomaterials have special physicochemical properties that empower them to bind, absorb and transport high-efficiency substances, such as small molecular drugs, DNA, proteins, RNAs, and probes. They also have excellent durability, high carrier potential, the ability to integrate both hydrophobic and hydrophilic compounds, and compatibility with various transport routes, making them especially appealing over a wide range of oncology fields. This is also due to their configurable scale, structure, and surface properties. This review paper discusses how nanostructures can function as therapeutic vectors to enhance the therapeutic value of molecules; how nanomaterials can be used as medicinal products in gene therapy, photodynamics, and thermal treatment; and finally, the application of nanomaterials in the form of molecular imaging agents to diagnose and map tumor growth.

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Quantitative analysis of organosulphur compounds in crude oil samples using magnetic solid phase extraction based on Au-Fe3O4 adsorbent and gas chromatography with time-of-flight mass spectrometry

Mgiba,

Mhuka,

Hintsho-Mbita

et al. 2024

Chem. Pap.

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This study focused on the development of a magnetic solid phase extraction (m-SPE) method using Au-Fe3O4 as an adsorbent followed by GC-ToFMS analysis for the determination of organosulphur compounds (OSCs) in fuel samples. The m-SPE using Au-Fe3O4 NPs was preferred because of the low toxicity of the adsorbent1, high separation efficiency using external magnet2 and greater extraction selectivity between sulphur and Au atom3. The Au-Fe3O4 NPs were characterized using XRD, UV–Vis, TEM, SEM and FTIR. This method was optimized using multivariate analysis based on a two-level full factorial and central composite designs. The conditions which produced optimum efficiency were found to be 150 mg mass of sorbent, 100 µL eluent volume, 50 min extraction time and 6,5 pH of the sample. These optimum conditions showed a relatively low limit of detection in the range of 0.02–0.199nµg/g and limit of quantification of 0.08–0.602 µg/g. Furthermore, a relative standard deviation of triplicates analysis was between 0.8 and 2.3% with good linearity of 0.9816–0.9961. The percentage recovery for thiophene, 3-methylthiophene, benzothiophene and dibenzothiophene ranged from 76 to 95% for the spiked samples. The optimized m-SPE method was then applied in real fuel oil samples. The concentration of thiophene, 3-methylthiophene, benzothiophene and dibenzothiophene in crude oil, gasoline, diesel and kerosene ranged from 0.43–1.94 µg/g, 0.78–1.63 µg/g, 0.95–4.31 µg/g to 1.55–2.09 µg/g, respectively. The m-SPE, followed by GC-ToFMS method, proved to be efficient, inexpensive and an alternative method for OSCs analysis in fuel oils.

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Surface Functionalization of Magnetic Nanoparticles Using a Thiol-Based Grafting-Through Approach

Cited by 8 publications

References 47 publications

Nanotechnology in the Fabrication of Advanced Paints and Coatings: Dispersion and Stabilization Mechanisms for Enhanced Performance

Nanotechnology in the Fabrication of Advanced Paints and Coatings: Dispersion and Stabilization Mechanisms for Enhanced Performance

Nanotechnology Advances in the Detection and Treatment of Cancer: An Overview

Quantitative analysis of organosulphur compounds in crude oil samples using magnetic solid phase extraction based on Au-Fe3O4 adsorbent and gas chromatography with time-of-flight mass spectrometry

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