Four reversible and reconfigurable structures for three-phase emulsions: extended morphologies and applications.

Here in this article, we classify and conclude the four morphologies of three-phase emulsions. Remarkably, we achieve the reversible transformations between every shape. Through theoretical analysis, we choose four liquid systems to form these four morphologies.

Water-oil Janus emulsions: microfluidic synthesis and morphology design.

In this work we developed a facile method to prepare water-oil Janus emulsions in situ with tunable morphologies by using a double-bore capillary microfluidic device. In addition, by combining the theory model and our liquids' properties, we propose a method to design the morphology of water-oil Janus emulsions. To systematically research Janus morphologies we combined the theory model and the fluids' properties.

Controlled stimulation-burst targeted release by smart decentered core-shell microcapsules in gravity and magnetic field.

By combining gravity and magnetic force, we have developed a versatile and facile microfluidic method for forming magnetic decentered core-shell microcapsules in which the directions of the oil core and the magnetic nanoparticles are either opposed or the same. When the temperature rises above the LCST of the PNIPAm, the shell shrinks rapidly and the core targets burst release towards the converse or the same direction as the magnet. By adjusting the direction of the magnet, the release direction of the active substance could be correspondingly accurately controlled.

Microfluidic generation of multicolor quantum-dot-encoded core-shell microparticles with precise coding and enhanced stability.

A novel microfluidic approach is developed to prepare multicolor QDs-encoded core-shell microparticles with precise and various barcode and enhanced stability performance. With the protection of the hydrogel shell, the leakage of QDs is avoided and the fluorescent stability is enhanced greatly. By embedding different QDs into different cores, no interaction between different QDs existed and the fluorescence spectrum of each kind of QDs can be recorded, respectively.

A novel microfluidic approach for preparing chitosan-silica core-shell hybrid microspheres with controlled structures and their catalytic performance.

A facile microfluidic approach to prepare chitosan-silica core-shell hybrid microspheres with different pore structures has been developed. The hybrid microspheres showed good performance in mechanics and adsorption and are outstanding and green catalyst supports. Under optimum conditions, the adsorption capacity of Cu(ii) is about 1.

Direct measurement of the differential pressure during drop formation in a co-flow microfluidic device.

In this study, we developed a new method for the direct measurement of differential pressures in a co-flow junction microfluidic device using a Capillary Laplace Gauge (CLG). The CLG - used inside the microchannel device--was designed using a tapered glass-capillary set up in co-flow junction architecture with a three-phase liquid-liquid-gas system with two flowing liquid phases and an entrained gas phase. By taking advantage of the Laplace equation, basic geometric relations and an integrated image analysis program, the movement of the entrained gas phase with the flow of the liquid-phases is tracked and monitored, allowing the gauge to function as an ultra-sensitive, integrated, differential pressure sensor measuring fluctuations in the liquid-dispersed phase channel pressure as small as tens of Pascals caused by droplet formation.

A novel microfluidic approach for monodispersed chitosan microspheres with controllable structures.

A novel and simple approach to prepare monodispersed chitosan microspheres with relative small size and controlled structures was developed by combining the solidification methods of solvent extraction and chemical crosslinking in a capillary-embedded microfluidic decive. The microspheres with different structures are used in the field of protein drug controlled release and immobilization lipases and they show different release profiles and good stability, respectively.

Controllable microfluidic production of gas-in-oil-in-water emulsions for hollow microspheres with thin polymer shells.

Here we developed a simple and novel one-step approach to produce G/O/W emulsions with high gas volume fractions in a capillary microfluidic device. The thickness of the oil layer can be controlled easily by tuning the flow rates. We successfully used the G/O/W emulsions to prepared hollow microspheres with thin polymer shells.

Controllable gas/liquid/liquid double emulsions in a dual-coaxial microfluidic device.

This article presents a simple and novel approach to prepare monodispersed gas-in-oil-in-water (G/O/W) and gas-in-water-in-oil (G/W/O) double-emulsions in the same dual-coaxial microfluidic device. The effects of three phase flow rates on the sizes of microbubbles and droplets and the number of the encapsulated microbubbles were systematically studied. We successfully synthesized two different types of gas/liquid/liquid (G/L/L) double emulsions with different inner structures in the same geometry by adjusting the flow rates sequentially.

Chiral separation performance of micrometer-sized monodispersed silica spheres with high protein loading.

Micrometer-sized monodispersed silica spheres (approximately 360 microm) with high loading of bovine serum albumin (BSA) (approximately 450 mg/g) were prepared as an adsorbent for large-scale chiral separation. The new adsorbent was characterized with scanning electron microscopy (SEM), nitrogen adsorption-desorption isotherms, the mercury intrusion method, infrared spectroscopic analysis, and elementary analysis. The extent of chiral separation was tested with rac-tryptophan (rac-Trp) and rac-phenylalanine (rac-Phe) as solutes.

Preferential interaction between DNA and small ions in mixed-size counterion systems: Monte Carlo simulation and density functional study.

Competitive binding between counterions around DNA molecule is characterized using the preferential interaction coefficient of individual ion in single and mixed electrolyte solutions. The canonical Monte Carlo (MC) simulation, nonlinear Poisson-Boltzmann (PB) equation, and density functional theory (DFT) proposed in our previous work [Wang, Yu, Gao, and Luo, J. Chem.

Density-functional theory and Monte Carlo simulation study on the electric double layer around DNA in mixed-size counterion systems.

A density-functional approach and canonical Monte Carlo simulations are presented for describing the ionic microscopic structure around the DNA molecule immersed in mixed-size counterion solutions. In the density-functional approach, the hard-sphere contribution to the Helmholtz energy functional is obtained from the modified fundamental measure theory [Y.-X.