Functional multi-layer graphene–algae hybrid material formed using vortex fluidics

Wahid, Mohd Haniff; Eroğlu, Ela; Chen, Xianjue; Smith, Steven M.; Raston, Colin L.

doi:10.1039/c2gc36892g

Cited by 63 publications

(68 citation statements)

References 39 publications

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“…[16] Importantly, the latter occurs at room temperature rather than requiring hydrothermal processing, and suggests that the constant ‘soft’ energy in the thin film has application in manipulating macromolecules, such as the refolding of proteins, without requiring heating. Other relevant applications and optimization of a similar vortex fluid device include exfoliating graphite and hexagonal boron-nitride to generate mono and multi-layer structures, [17, 18] controlling the formation of different calcium carbonate polymorphs, [19] and controlling chemical reactivity and selectivity. [20, 21] …”

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Shear‐Stress‐Mediated Refolding of Proteins from Aggregates and Inclusion Bodies

et al. 2015

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Recombinant protein overexpression of large proteins in bacteria often results in insoluble and misfolded proteins directed to inclusion bodies. We report the application of shear stress in micrometer-wide, thin fluid films to refold boiled hen egg white lysozyme, recombinant hen egg white lysozyme, and recombinant caveolin-1. Furthermore, the approach allowed refolding of the much larger protein, cAMP-dependent protein kinase A (PKA). The reported methods require only minutes, which is >100-times faster than conventional, overnight dialysis. This rapid refolding technique could significantly shorten the times, lower costs, and reduce the waste streams associated with protein expression for a wide-range of industrial and research applications.

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Shear‐Stress‐Mediated Refolding of Proteins from Aggregates and Inclusion Bodies

et al. 2015

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“…It can also operate under the ‘continuous flow mode' with jet feeds delivering liquid into the rotating tube where additional shear is generated in the thin films from the viscous drag as the liquid whirls along the tube. We have recently established that the VFD is effective in exfoliating graphite and h -BN2526, controlling the decoration of palladium nano-particles on carbon nano-onions arising from the high mass transfer of hydrogen gas27 and also palladium nano-particles on graphene28, disassembling self organised molecular capsules1429, the synthesis of superparamagnetic magnetite nanoparticles embedded in polyvinylpyrrolidone followed by entrapping microalgal cells within this material, and similarly in entrapping them in graphene oxide3031. The details of the VFD and the different types of shear regimes are now reported using selected organic reactions, initially for Diels-Alder dimerization of cyclopentadienes in optimising the operational parameters of the VFD, then sequential aldol condensation and Michael addition reactions, in gaining direct access to unusual 2,4,6-triarylpyridines which are not possible or inherently difficult and/or of limited practical convenience using traditional batch processing.…”

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Optimising a vortex fluidic device for controlling chemical reactivity and selectivity

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Chen

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et al. 2013

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A vortex fluidic device (VFD) involving a rapidly rotating tube open at one end forms dynamic thin films at high rotational speed for finite sub-millilitre volumes of liquid, with shear within the films depending on the speed and orientation of the tube. Continuous flow operation of the VFD where jet feeds of solutions are directed to the closed end of the tube provide additional tuneable shear from the viscous drag as the liquid whirls along the tube. The versatility of this simple, low cost microfluidic device, which can operate under confined mode or continuous flow is demonstrated in accelerating organic reactions, for model Diels-Alder dimerization of cyclopentadienes, and sequential aldol and Michael addition reactions, in accessing unusual 2,4,6-triarylpyridines. Residence times are controllable for continuous flow processing with the viscous drag dominating the shear for flow rates >0.1 mL/min in a 10 mm diameter tube rotating at >2000 rpm.

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“…5,6 Additionally, with the emerging advances in nanotechnology, innovative approaches such as the integration of nanomaterials and microorganisms provide access to novel functional materials. Some of these studies focus on interfacing nanomaterials with biological cells to detect biocomponents or to investigate biological phenomena, 7 in particular bioremediation, [8][9][10] the synthesis of bio-templated materials for various novel applications such as supercapacitors, 11 surface enhanced Raman scattering (SERS) substrates, 12 and lithium storage, 13 or for immobilization purposes.…”

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“…Related to this work is the use of the VFD to prepare functional multi-layer graphene-algae and graphene oxide (GO)-algae hybrid materials. 10,16 In the VFD, a rapidly rotating tube generates a thin microuidic lm with rapid micro-mixing of reagents therein, and the mechanoenergy in the lm is effective in increasing reaction rates, and therefore reducing the processing times. 33 Importantly, the VFD can be operated in the conned mode and also continuous ow mode, and it has a diversity of processing capabilities, including in organic synthesis, [33][34][35][36][37] controlled growth of the polymorphs of calcium carbonate, 38 formation of mesoporous silica at room temperature with control over the pore size, 39 compacting single walled carbon nanotube into toroidal structures, 40 exfoliation of graphene and boron nitride, 41 controlled decoration of nanoparticles on 2D nanomaterials, [42][43][44] preparation of functional hybrid bio-nanomaterials, 10,16,45 and the refolding of proteins.…”

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Microencapsulation of bacterial strains in graphene oxide nano-sheets using vortex fluidics

et al. 2015

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Wrapping bacterial cells with graphene oxide sheets using a vortex fluidic device (VFD) effectively limits cellular growth for a certain time period whilst sustaining biological activity. This simple and benign method in preparing such a composite material relies on the shear within the film in the device without compromising the cellular viability. In principle, the process is scalable for large volumes, for operating the VFD(s) under continuous flow mode. Moreover, acquiring SEM images was possible without precoating the composite material with a metallic film, with limited charging effects. This establishes the potential for interfacing material with graphene oxide, which could be extended to more conductive graphene layers, as an effective approach for simplifying characterization using SEM.

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Functional multi-layer graphene–algae hybrid material formed using vortex fluidics

Cited by 63 publications

References 39 publications

Shear‐Stress‐Mediated Refolding of Proteins from Aggregates and Inclusion Bodies

Shear‐Stress‐Mediated Refolding of Proteins from Aggregates and Inclusion Bodies

Optimising a vortex fluidic device for controlling chemical reactivity and selectivity

Microencapsulation of bacterial strains in graphene oxide nano-sheets using vortex fluidics

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