Qiu Bailing scite author profile

Field-flow fractionation (FFF) is a kind of mature separation technologies in the field of bioanalysis, feasible of separating analytes with the differences of certain physical and chemical properties by the combination effects of two orthogonal force fields (flow field and external force field). Asymmetrical flow field-flow fractionation (AF4) is a vital subvariant of FFF, which applying a vertical flow field as the second dimension force field. The separation in AF4 opening channel is carried out by any composition carrier fluid, universally and effectively used in separation of bioparticles and biopolymers due to the non-invasivity feature. Herein, bio-analytes are held in bio-friendly environment and easily sterilized without using degrading carrier fluid which is conducive to maintain natural conformation. In this review, FFF and AF4 principles are briefly described, and some classical and emerging applications and developments in the bioanalytical fields are concisely introduced and tabled. Also, special focus is given to the hyphenation of AF4 with highly specific, sensitive detection technologies.

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Optimization of experimental conditions for the separation of polystyrene particles by gravitational field-flow fractionation

Bailing¹,

Di²,

Guo³

et al. 2017

Chinese Journal of Chromatography

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Effects of carrier liquid and flow rate on the separation in gravitational field-flow fractionation

Guo¹,

Zhu²,

Yaya³

et al. 2016

Chinese Journal of Chromatography

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Gravitational field-flow fractionation is the simplest field-flow fractionation technique in terms of principle and operation. The earth' s gravity is its external field. Different sized particles are injected into a thin channel and carried by carrier fluid. The different velocities of the carrier liquid in different places results in a size-based separation. A gravitational field-flow fractionation (GrFFF) instrument was designed and constructed. Two kinds of polystyrene (PS) particles with different sizes (20 µm and 6 µm) were chosen as model particles. In this work, the separation of the sample was achieved by changing the concentration of NaN3, the percentage of mixed surfactant in the carrier liquid and the flow rate of carrier liquid. Six levels were set for each factor. The effects of these three factors on the retention ratio (R) and plate height (H) of the PS particles were investigated. It was found that R increased and H decreased with increasing particle size. On the other hand, the R and H increased with increasing flow rate. The R and H also increased with increasing NaN3 concentration. The reason was that the electrostatic repulsive force between the particles and the glass channel wall increased. The force allowed the samples approach closer to the channel wall. The results showed that the resolution and retention time can be improved by adjusting the experimental conditions. These results can provide important values to the further applications of GrFFF technique.

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Optimization of conditions for the isolation and preparation of glucosinolates from Maca by high-speed counter-current chromatography with orthogonal experiments

Wang¹,

Wu²,

Zhao³

et al. 2016

Chinese Journal of Chromatography

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Qiu Bailing

Effects of comprehensive function of factors on retention behavior of microparticles in gravitational field-flow fractionation

Present situation and development trends of asymmetrical flow field-flow fractionation

Optimization of experimental conditions for the separation of polystyrene particles by gravitational field-flow fractionation

Effects of carrier liquid and flow rate on the separation in gravitational field-flow fractionation

Optimization of conditions for the isolation and preparation of glucosinolates from Maca by high-speed counter-current chromatography with orthogonal experiments

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