Elaboration and Rheological Investigation of Magnetic Sensitive Nanocomposite Biopolymer Networks

Galindo-Gonzalez, C.; Gantz, Stéphanie; Ourry, Laurence; Mammeri, Fayna; Ammar, Souad; Ponton, Alain

doi:10.1021/ma402655g

Cited by 21 publications

(17 citation statements)

References 29 publications

(34 reference statements)

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“…At higher strain, the system deviates from the linear viscoelasticity: the storage modulus decreases, whereas simultaneously the loss modulus increases and then passes through maximum. This behaviour is usually associated with the breakage of chain-like structures of particles: 5,34,45 it reduces the fraction of aggregates attached to both plates of the measuring cell thus decreasing G 0 , at the same time it augments the fraction of "free" strings thereby enhancing the loss modulus G 00 . The deviations from linear viscoelasticity are more pronounced at higher strength of magnetic eld (Fig.…”

Section: Linear Viscoelastic Responsementioning

confidence: 99%

Soft magnetic nanocomposites based on adaptive matrix of wormlike surfactant micelles

et al. 2018

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Section: Linear Viscoelastic Responsementioning

confidence: 99%

Soft magnetic nanocomposites based on adaptive matrix of wormlike surfactant micelles

et al. 2018

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Section: Introductionmentioning

confidence: 99%

“…A higher loading of magnetic nanoparticle fillers results in enhanced magnetic responsiveness; however, the mechanical performance of the polymer matrix is negatively impacted upon increase in nanoparticle loading . While the addition of low amounts of nanoparticle fillers can enhance the mechanical properties by improving stress transfer from the soft polymer matrix to the stiffer nanoparticle fillers, a higher loading of nanoparticle fillers can significantly weaken the mechanical properties due to reduced interactions between the polymer strands . Therefore, ensuring good interfacial interactions between the MNPs and PE matrix is an important factor to consider in order to preserve the mechanical properties of the polymer matrix at high filler loadings.…”

Section: Introductionmentioning

confidence: 99%

“…The physical and chemical properties of previously fabricated magnetic nanocomposites have been shown to be directly linked to the amount of magnetic nanoparticle fillers incorporated in the polymer matrix. [27][28][29][30] A higher loading of magnetic nanoparticle fillers results in enhanced magnetic responsiveness; however, the mechanical performance of the polymer matrix is negatively impacted upon increase in nanoparticle loading. [28] While the addition of low amounts of nanoparticle fillers can enhance the mechanical properties by improving stress transfer from the soft polymer matrix to the stiffer nanoparticle fillers, a higher loading of nanoparticle fillers can significantly weaken the mechanical properties due to reduced interactions between the polymer strands.…”

Section: Introductionmentioning

confidence: 99%

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Reactive Extrusion Strategies to Fabricate Magnetite–Polyethylene Nanocomposites with Enhanced Mechanical and Magnetic Hyperthermia Properties

Situ

Chen

Abenojar

et al. 2016

Macro Materials & Eng

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Biofouling is a major problem in water filtration units, which leads to premature system failure. Conventional treatment methods involving the use of chemicals or high‐pressure hydraulics exert mechanical strain on filter materials, leading to shortened service lifetimes. In this study, a novel magnetic polymer nanocomposite is fabricated using a blend of high density/ultrahigh molecular weight polyethylene with magnetite nanoparticle (MNP) fillers. The resulting magnetite–polyethylene nanocomposite (MPE‐NC) is mechanically robust and can be externally actuated with an alternating magnetic field to generate localized heating that is effective in eradicating bacterial biofilms. The MNPs are functionalized with silane‐based coupling agents and crosslinked onto the polyethylene backbone via a reactive extrusion approach, which results in a twofold enhancement in mechanical properties of the polymer matrix. Furthermore, the magnetic hyperthermia performance of the MPE‐NC is improved eightfold by replacing undoped magnetite nanospheres with zinc‐doped magnetite nanocube fillers, and the magnetic hyperthermia treatment approach is shown to be 12 times more effective in destroying bacterial biofilms compared to a direct heat‐treatment method. During hyperthermia treatment, the mechanical integrity of the MPE‐NC is preserved, thereby validating the potential of the MPE‐NC as a new filter material with high efficiency in biofilm removal and extended durability.

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“…Among the most researched on are those that are highly responsive to the external stimuli. A wide range of polymeric nanomaterials carrying smart switchable components has been developed over the decades [1][2][3][4][5][6][7]. For example, multistimuli responsive nanomaterials based on amphiphilic polymer composites containing hydrophilic and lipophilic macromers with environment-sensitive micellar properties have been reported [8].…”

Section: Introductionmentioning

confidence: 99%

Perspectives on the Emerging Applications of Multifaceted Biomedical Polymeric Nanomaterials

Gumel

Annuar

Yusuf

2015

Journal of Nanomaterials

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Biodegradable and biocompatible polymeric nanomaterials, serving as biomedical devices have garnered significant attention as a promising solution to therapeutic management of many chronic diseases. Despite their potentials, majority of the synthetic nanomaterials used in biomedical applications lack crucial properties, for example, ligand binding sites, responsiveness, and switchability to efficiently deliver intended drugs to the target site. Advancements in manipulating nanoscale geometry have incurred the incorporation of triggered release mechanism within the nanomaterials design. This expanded their potential applications beyond nanocarriers to theranostics exhibiting both tandem drug delivery and diagnostic capabilities. Additionally, it highlights possibilities to design nanomaterials that could translate chemical response(s) to photometric display, thus making affordable biosensors and actuators readily available for biomedical exploitation. It is anticipated that, in the near future, these implementations could be made to access some of the most difficult therapy locations, for example, blood brain barrier to provide efficient management of Alzheimer, Huntington, and other neurodegenerative diseases. This review aims to serve as a reference platform by providing the readers with the overview of the recent advancements and cutting-edge techniques employed in the production and instrumentation of such nanomaterials.

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Elaboration and Rheological Investigation of Magnetic Sensitive Nanocomposite Biopolymer Networks

Cited by 21 publications

References 29 publications

Soft magnetic nanocomposites based on adaptive matrix of wormlike surfactant micelles

Soft magnetic nanocomposites based on adaptive matrix of wormlike surfactant micelles

Reactive Extrusion Strategies to Fabricate Magnetite–Polyethylene Nanocomposites with Enhanced Mechanical and Magnetic Hyperthermia Properties

Perspectives on the Emerging Applications of Multifaceted Biomedical Polymeric Nanomaterials

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