Dummy molecularly imprinted polymers based on a green synthesis strategy for magnetic solid-phase extraction of acrylamide in food samples

Bagheri, Ahmad Reza; Arabi, Maryam; Ghaedi, Mehrorang; Ostovan, Abbas; Wang, Xiaoyan; Li, Jinhua; Chen, Lingxin

doi:10.1016/j.talanta.2018.11.065

Cited by 316 publications

(92 citation statements)

References 54 publications

(50 reference statements)

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“…Another application field is the monitoring of toxins or natural hormones in waters, 94 food 117,168,182 and biological fluids. 181 At last, recent works reported the use of dSPE-MIP for the extraction of pesticides from waters, 160,167 soil, 167 and food extracts, 144,162,185 and of industrial pollutants from waters, 31,33,37,47,158,166,179,183,186 food, 34,68,96,98,180,183 or samples collected in an industrial bioreactor. 53 Another objective of sample purification using MIP is the removal of a class of compounds that interfere with the analysis of the target analytes.…”

Section: Applications Of Mip In Dspementioning

confidence: 99%

“…51,147,165 For solid samples, as for MIP-SPE applications, which are subjected to a first treatment with a solvent, the resulting liquid extracts are put in contact with MIP particles either directly 117 or after a dilution with a buffer or a hydro-organic mixture. 34,59,96,180,182,185 While all these sample pretreatment procedures are varied and aim to make the sample less viscous or to eliminate certain interfering compounds such as proteins, the conditions are rarely, if ever, really justified. The desorption of small molecules is mainly achieved using organic solvents that may contain some acids to help desorption.…”

Section: Applications Of Mip In Dspementioning

confidence: 99%

“…62 A central composite design (CCD) with four parameters, selected after having set some other parameters, and a response surface methodology (RSM) or, in case of multi-criteria optimization, a desirability function were also employed to help optimize the dSPE conditions. 96,147,169,178…”

Section: Optimization Of the Dspe Proceduresmentioning

confidence: 99%

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Sample Preparation Using Molecularly Imprinted Polymers

2019

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Section: Applications Of Mip In Dspementioning

confidence: 99%

Section: Applications Of Mip In Dspementioning

confidence: 99%

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Sample Preparation Using Molecularly Imprinted Polymers

2019

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“…Combination of solid‐phase synthesis and imprinting technology produce imprinted materials in large scale and recycle templates first proposed by Piletsky's group 9c. Usually, template proteins were immobilized on glass beads first, small imprinted nanoparticles around each immobilized protein other than compact and intact imprinted shell could be obtained attributed to the low surface energy of glass beads.…”

Section: Biological Molecular Imprinting With Different Scalementioning

confidence: 99%

Molecularly Imprinted Materials for Selective Biological Recognition

Zhang

et al. 2019

Macromol. Rapid Commun.

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Molecular imprinting is an approach of generating imprinting cavities in polymer structures that are compatible with the target molecules. The cavities have memory for shape and chemical recognition, similar to the recognition mechanism of antigen–antibody in organisms. Their structures are also called biomimetic receptors or synthetic receptors. Owing to the excellent selectivity and unique structural predictability of molecularly imprinted materials (MIMs), practical MIMs have become a rapidly evolving research area providing key factors for understanding separation, recognition, and regenerative properties toward biological small molecules to biomacromolecules, even cell and microorganism. In this review, the characteristics, morphologies, and applicability of currently popular carrier materials for molecular imprinting, especially the fundamental role of hydrogels, porous materials, hierarchical nanoparticles, and 2D materials in the separation and recognition of biological templates are discussed. Moreover, through a series of case studies, emphasis is given on introducing imprinting strategies for biological templates with different molecular scales. In particular, the differences and connections between small molecular imprinting (bulk imprinting, “dummy” template imprinting, etc.), large molecular imprinting (surface imprinting, interfacial imprinting, etc.), and cell imprinting strategies are demonstrated in detail. Finally, future research directions are provided.

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“…Molecularly imprinted polymers (MIPs) are often referred to as “artificial antibodies” possessing high affinity and selectivity toward targets. MIPs are obtained by a copolymerization process in porogen solvent with template molecule, functional monomer, and cross‐linking agent [16–18]. Due to well‐known unique advantages of good stability, high selectivity, low cost, and ease in preparation [19–21], MIPs have been widely used in SPE process for different trace pesticide residues such as organophosphorus pesticides [22–24], imidazole fungicides [25], organochlorine fungicides [26], iprodione fungicides [27], triazole pesticides [28], phenoxyacetic acid fungicides [29], benzimidazole fungicide [30], and pyrethroids insecticides [31,32].…”

Section: Introductionmentioning

confidence: 99%

Synthesis of molecularly imprinted polymer adsorbents for solid‐phase extraction of strobilurin fungicides from agricultural products

Cao

Zhang

et al. 2020

J of Separation Science

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Molecularly imprinted polymers for strobilurin fungicides were prepared by precipitation polymerization employing azoxystrobin as template molecular together with methacrylic acid monomer and trimethylolpropane triacrylate cross-linker.Morphological characterization showed molecularly imprinted polymers were uniform spherical particles with about 0.2 μm in diameter, while the morphologies of nonimprinted polymers were irregular bulk. The equilibrium binding and selective experiments proved that molecularly imprinted polymers possessed a higher affinity toward four fungicides compared to nonimprinted polymers and heterogeneous binding sites were found in the molecularly imprinted polymers. Molecularly imprinted solid-phase extraction conditions, including sample loading solvents, selective washing, and elution solvents, were carefully optimized. The developed method showed good recoveries (70.0-114.0%) with relative standard deviations in range of 1.0-9.8% (n = 3) for samples (cucumber and peach) spiked at three different levels (10, 50, and 100 μg/ kg). The detection limit (signal/noise = 3) ranged from 0.01 to 0.08 μg/kg. The results demonstrated good potential use of this convenient and highly efficient method for determining trace strobilurin fungicides in agricultural products. K E Y W O R D Sagricultural products, molecularly imprinted polymers, solid-phase extraction, strobilurin fungicides

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Dummy molecularly imprinted polymers based on a green synthesis strategy for magnetic solid-phase extraction of acrylamide in food samples

Cited by 316 publications

References 54 publications

Sample Preparation Using Molecularly Imprinted Polymers

Sample Preparation Using Molecularly Imprinted Polymers

Molecularly Imprinted Materials for Selective Biological Recognition

Synthesis of molecularly imprinted polymer adsorbents for solid‐phase extraction of strobilurin fungicides from agricultural products

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