Ashvin Nagaraja scite author profile

Nonspecific binding (NSB), a random adsorption of biocomponents such as proteins and bacteria on noncomplementary materials, is one of the biggest problems in biological applications including biosensors, protein chips, surgical instruments, drug delivery, and biomedicine. Polyoxyethylene sorbitan laurate (TWEEN), a commercially available chemical with aliphatic ester chains, has shown promise as a medical material and in overcoming problems associated with NSB. [1][2][3][4] However, stability during solution-based processing and uniformity of the materials that have TWEEN coating on flat substrates or nanomaterials using the selfassembled-monolayer (SAM) method has been an important issue. Further, biocompatible materials with high strength are important for several medical applications including stents, nail implants, and strong invasive instruments. Here, we present the production of a free-standing ''paperlike'' material composed of TWEEN and reduced graphene oxide (RGO) platelets and obtained by simple filtration of a homogeneous aqueous colloidal suspension of TWEEN/RGO hybrid. The ''TWEEN paper'' was highly stable in water without leakage of TWEEN and is compliant and sufficiently robust to be handled by hand without breaking. Furthermore, the TWEEN paper was noncytotoxic to three mammalian cell lines and biocompatible, inhibiting nonspecific binding of Gram-positive bacteria.[5] In contrast, RGO paper without TWEEN showed nonspecific bacterial binding.TWEEN is composed of three chemical parts (Fig. 1a): aliphatic ester chains that can prevent NSB of biomolecules, three-terminal hydroxyl groups that are hydrophilic and can be chemically modified for further applications, and an aliphatic chain that can easily be adsorbed on a hydrophobic surface by noncovalent interaction. Protein microarrays on flat substrates with SAM of TWEEN [4] and highly sensitive biosensors, [1][2][3]

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Impermeable Graphenic Encasement of Bacteria

Mohanty

et al. 2011

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Transmission electron microscopy (TEM) of hygroscopic, permeable, and electron-absorbing biological cells has been an important challenge due to the volumetric shrinkage, electrostatic charging, and structural degradation of cells under high vacuum and fixed electron beam.(1-3) Here we show that bacterial cells can be encased within a graphenic chamber to preserve their dimensional and topological characteristics under high vacuum (10(-5) Torr) and beam current (150 A/cm(2)). The strongly repelling π clouds in the interstitial sites of graphene's lattice(4) reduces the graphene-encased-cell's permeability(5) from 7.6-20 nm/s to 0 nm/s. The C-C bond flexibility(5,6) enables conformal encasement of cells. Additionally, graphene's high Young's modulus(6,7) retains cell's structural integrity under TEM conditions, while its high electrical(8) and thermal conductivity(9) significantly abates electrostatic charging. We envision that the graphenic encasement approach will facilitate real-time TEM imaging of fluidic samples and potentially biochemical activity.

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Nanotomy-based production of transferable and dispersible graphene nanostructures of controlled shape and size

et al. 2012

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Because of the edge states and quantum confinement, the shape and size of graphene nanostructures dictate their electrical, optical, magnetic and chemical properties. The current synthesis methods for graphene nanostructures do not produce large quantities of graphene nanostructures that are easily transferable to different substrates/solvents, do not produce graphene nanostructures of different and controlled shapes, or do not allow control of Gn dimensions over a wide range (up to 100 nm). Here we report the production of graphene nanostructures with predetermined shapes (square, rectangle, triangle and ribbon) and controlled dimensions. This is achieved by diamond-edge-induced nanotomy (nanoscalecutting) of graphite into graphite nanoblocks, which are then exfoliated. our results show that the edges of the produced graphene nanostructures are straight and relatively smooth with an I D /I G of 0.22-0.28 and roughness < 1 nm. Further, thin films of Gn-ribbons exhibit a bandgap evolution with width reduction (0, 10 and ~35 meV for 50, 25 and 15 nm, respectively).

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High‐Throughput, Ultrafast Synthesis of Solution‐ Dispersed Graphene via a Facile Hydride Chemistry

Mohanty¹,

Nagaraja²,

Armesto³

et al. 2010

Small

102

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Poly (vinylsulfonic acid) assisted synthesis of aqueous solution stable vaterite calcium carbonate nanoparticles

Nagaraja

Pradhan

McShane

2014

Journal of Colloid and Interface Science

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Ashvin Nagaraja

Biocompatible, Robust Free‐Standing Paper Composed of a TWEEN/Graphene Composite

Impermeable Graphenic Encasement of Bacteria

Nanotomy-based production of transferable and dispersible graphene nanostructures of controlled shape and size

High‐Throughput, Ultrafast Synthesis of Solution‐ Dispersed Graphene via a Facile Hydride Chemistry

Poly (vinylsulfonic acid) assisted synthesis of aqueous solution stable vaterite calcium carbonate nanoparticles

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