Optimising a vortex fluidic device for controlling chemical reactivity and selectivity

Yasmin, Lyzu; Chen, Xianjue; Stubbs, Keith A.; Raston, Colin L.

doi:10.1038/srep02282

Cited by 97 publications

(185 citation statements)

References 35 publications

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“…2B,C). This is despite the short processing time for a finite volume of liquid moving through the VFD under continuous flow three times, being less than three minutes6. Presumably the intense micro-mixing and subsequent shear in the VFD results in the majority of the P4C6 molecules on the solution face of the bilayer (immediately accessible) to bind carboplatin.…”

Section: Resultsmentioning

confidence: 99%

“…The vesicles were loaded with carboplatin using a recently developed vortex fluidic device (VFD)6 which has a rapidly rotating tube open at one end (Figure S2). The high rotational speed generates shear in the resulting thin films arising from viscous drag, Stewartson/Ekman layers6, and resonance effect8, in tracking towards conditions beyond diffusion control. The constant shear in this microfluidic platform is effective in disassembling self-organized molecular capsules for small molecule inclusion or encapsulation,9101112 as has been established for the related spinning disc processor13.…”

Section: Resultsmentioning

confidence: 99%

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Shear induced carboplatin binding within the cavity of a phospholipid mimic for increased anticancer efficacy

Eggers

Chen

et al. 2015

Sci Rep

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Vesicles 107 ± 19 nm in diameter, based on the self-assembly of tetra-para-phosphonomethyl calix[4]- arene bearing n-hexyl moieties attached to the phenolic oxygen centres, are effective in binding carboplatin within the cavity of the macrocycle under shear induced within a dynamic thin film in a continuous flow vortex fluidic device. Post shearing the vesicles maintain similar diameters and retain carboplatin within the cavity of the calixarene in a hierarchical structure, with their size and morphology investigated using DLS, TEM, SEM and AFM. Location of the carboplatin was confirmed using NMR, FTIR, ESI-MS and EFTEM, with molecular modelling favouring the polar groups of carboplatin hydrogen bonded to phosphonic acid moieties and the four member cyclobutane ring directed into the cavity of the calixarene. The loading efficiency and release profile of carboplatin was investigated using LC-TOF/MS, with the high loading of the drug achieved under shear and preferential released at pH 5.5, offering scope for anti-cancer drug delivery. The hierarchical structured vesicles increase the efficacy of carboplatin by 4.5 fold on ovarian cancer cells, lowered the IC50 concentration by 10 fold, and markedly increased the percent of cells in the S-phase (DNA replication) of the cell cycle.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Shear induced carboplatin binding within the cavity of a phospholipid mimic for increased anticancer efficacy

Eggers

Chen

et al. 2015

Sci Rep

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“…Full workings and schematicso ft he VFD havebeen previouslyreported. [17] chemistry systems. Though notable exceptionse xist, [20][21][22] am ore general solution to these problemsi sw arranted.…”

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confidence: 99%

Rapid Vortex Fluidics: Continuous Flow Synthesis of Amides and Local Anesthetic Lidocaine

Britton

Chalker

Raston

2015

Chemistry A European J

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Thin film flow chemistry using a vortex fluidic device (VFD) is effective in the scalable acylation of amines under shear, with the yields of the amides dramatically enhanced relative to traditional batch techniques. The optimized monophasic flow conditions are effective in ≤80 seconds at room temperature, enabling access to structurally diverse amides, functionalized amino acids and substituted ureas on multigram scales. Amide synthesis under flow was also extended to a total synthesis of local anesthetic lidocaine, with sequential reactions carried out in two serially linked VFD units. The synthesis could also be executed in a single VFD, in which the tandem reactions involve reagent delivery at different positions along the rapidly rotating tube with in situ solvent replacement, as a molecular assembly line process. This further highlights the versatility of the VFD in organic synthesis, as does the finding of a remarkably efficient debenzylation of p-methoxybenzyl amines.

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“…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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Optimising a vortex fluidic device for controlling chemical reactivity and selectivity

Cited by 97 publications

References 35 publications

Shear induced carboplatin binding within the cavity of a phospholipid mimic for increased anticancer efficacy

Shear induced carboplatin binding within the cavity of a phospholipid mimic for increased anticancer efficacy

Rapid Vortex Fluidics: Continuous Flow Synthesis of Amides and Local Anesthetic Lidocaine

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

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