Biocompatible high performance hyperbranched epoxy/clay nanocomposite as an implantable material

Barua, Shaswat; Dutta, Nipu; Karmakar, Sanjeev; Chattopadhyay, Pronobesh; Aidew, Lipika; Buragohain, Alak Kumar; Karak, Niranjan

doi:10.1088/1748-6041/9/2/025006

Cited by 48 publications

(54 citation statements)

References 30 publications

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“…Functionalization with organic modifiers via an ion exchange reaction confers montmorillonite increased basal spacing and separation between its platelets [4,12] as well as better mixing ability, and facilitates its interactions with hydrophobic polymers [3,4,13] . Complementary, its high aspect ratio [5] ensures better reinforcement within the polymeric plane itself [14] by enhancing polymer’s properties at a fairly low silicate content [13] and leading to the formation of nanoclay-polymer-based composites with increased mechanical strength [3,14], barrier properties [3,15], UV dispersion [15], and fire resistance capabilities [3,16], to be used for food packaging [17,18], automotive [19,20], medical devices [21,22], and for coatings-related applications [23,24]. …”

Section: Introductionmentioning

confidence: 99%

Toxicity evaluations of nanoclays and thermally degraded byproducts through spectroscopical and microscopical approaches

Wagner

Eldawud

White

et al. 2017

Biochimica et Biophysica Acta (BBA) - General Subjects

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Background Montmorillonite is a type of nanoclay that originates from the clay fraction of the soil and is incorporated into polymers to form nanocomposites with enhanced mechanical strength, barrier, and flammability properties used for food packaging, automotive, and medical devices. However, with implementation in such consumer applications, the interaction of montmorillonite-based composites or derived byproducts with biological systems needs to be investigated. Methods Herein we examined the potential of Cloisite Na+ (pristine) and Cloisite 30B (organically modified montmorillonite nanoclay) and their thermally degraded byproducts’ to induce toxicity in model human lung epithelial cells. The experimental set-up mimicked biological exposure in manufacturing and disposal areas and employed cellular treatments with occupationally relevant doses of nanoclays previously characterized using spectroscopical and microscopical approaches. For nanoclay-cellular interactions and for cellular analyses respectively, biosensorial-based analytical platforms were used, with induced cellular changes being confirmed via live cell counts, viability assays, and cell imaging. Results Our analysis of byproducts’ chemical and physical properties revealed both structural and functional changes. Real-time high throughput analyses of exposed cellular systems confirmed that nanoclay induced significant toxic effects, with Cloisite 30B showing time-dependent decreases in live cell count and cellular viability relative to control and pristine nanoclay, respectively. Byproducts produced less toxic effects; all treatments caused alterations in the cell morphology upon exposure. Conclusions Our morphological, behavioral, and viability cellular changes show that nanoclays have the potential to produce toxic effects when used both in manufacturing or disposal environments. General significance The reported toxicological mechanisms prove the extensibility of a biosensorial-based platform for cellular behavior analysis upon treatment with a variety of nanomaterials.

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Section: Introductionmentioning

confidence: 99%

Toxicity evaluations of nanoclays and thermally degraded byproducts through spectroscopical and microscopical approaches

Wagner

Eldawud

White

et al. 2017

Biochimica et Biophysica Acta (BBA) - General Subjects

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“…However, direct nanoparticles cannot be used as antimicrobial agents for long duration as they lose their stability and functions due to agglomeration. In this milieu, fabrication of nanocomposite of the metal nanoparticles with polymer or immobilization of the organic biocides into such polymer nanocomposites is an advanced technique for destruction of microorganisms by slow release of the active agents [24,25]. This technique reduces the toxic effect of the active agents to the environment as well as provides Materials Science and Engineering C 56 (2015) 74-83 stability to the same with long durability.…”

Section: Introductionmentioning

confidence: 99%

Biocide immobilized OMMT-carbon dot reduced Cu2O nanohybrid/hyperbranched epoxy nanocomposites: Mechanical, thermal, antimicrobial and optical properties

Gupta

Mandal

et al. 2015

Materials Science and Engineering: C

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“…Epoxy resin possesses many favorable properties like good mechanical and thermal performance, high adhesive strength, low shrinkage during curing and low creep, excellent corrosion and weather resistance with good chemical resistance, dimensional stability and ease of processibilities. [16,17] In this milieu, epoxy with hyperbranched architecture is interesting because of structural uniqueness. Compared with the linear analog, hyperbranched polymer possesses low solution and melts viscosity, high peripheral functionality, and compact dimension.…”

Section: Introductionmentioning

confidence: 99%

Bio‐based high‐performance waterborne hyperbranched polyurethane thermoset

Gogoi

Karak

2015

Polymers for Advanced Techs

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Tannic-acid-based low volatile organic compound-containing waterborne hyperbranched polyurethane was prepared. In order to improve the performance, it was modified in an aqueous medium using a glycerol-based hyperbranched epoxy and vegetable-oil-based poly(amido amine) at different wt%. The combined system was cross-linked by heating at 100°C for 45 min. Fourier transform infrared spectroscopy and swelling study were used to confirm the curing. A dose-dependent improvement of properties was witnessed for the thermoset. Thermoset with 30 wt% epoxy showed excellent improvements in mechanical properties like tensile strength (~3.4 fold), scratch hardness (~2 fold), impact resistance (~1.3 fold), and toughness (~1.7 fold). Thermogravimetric analysis revealed enhancement of thermal properties (maximum 70°C increment of degradation temperature and 8°C increment of T g ). The modified system showed better chemical and water resistance compared with the neat polyurethane. Biodegradation study was carried out by broth culture method using Pseudomonas aeruginosa as the test organism. An adequate biodegradation was witnessed, as evidenced by weight loss profile, bacterial growth curve, and scanning electron microscope images. The work showed the way to develop environmentally benign waterborne polyurethane as a high-performance material by incorporating a reactive modifier into the polymer network. Use of benign solvent and bio-based materials as well as profound biodegradability justified eco-friendliness and sustainability of the modified system.

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Biocompatible high performance hyperbranched epoxy/clay nanocomposite as an implantable material

Cited by 48 publications

References 30 publications

Toxicity evaluations of nanoclays and thermally degraded byproducts through spectroscopical and microscopical approaches

Toxicity evaluations of nanoclays and thermally degraded byproducts through spectroscopical and microscopical approaches

Biocide immobilized OMMT-carbon dot reduced Cu2O nanohybrid/hyperbranched epoxy nanocomposites: Mechanical, thermal, antimicrobial and optical properties

Bio‐based high‐performance waterborne hyperbranched polyurethane thermoset

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