Liquid marble and water droplet interactions and stability

Ueno, K.; Bournival, Ghislain; Wanless, Erica J.; Nakayama, Saori; Giakoumatos, Emma C.; Nakamura, Yoshinobu; Fujii, Syuji

doi:10.1039/c5sm01584g

Cited by 23 publications

(16 citation statements)

References 67 publications

(156 reference statements)

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“…In literature several works studying and exploring the ability of LM to float can be found – Figure A . Taking advantage from this LM property, applications were developed on sensors field for pH‐sensing, to reveal water pollution, and also on development of floating self‐propelling devices . Generally, pH‐sensing LM were coated with pH‐responsive particles that change their wettability from hydrophobic to hydrophilic with pH variations.…”

Section: Liquid Marblesmentioning

confidence: 99%

“…Widely range of applications were found for LM, such as oil adsorption and separation, pH and gas sensing, chemical reactions, synthesizing microparticles, revealing water pollution on the water/vapor interface and manipulation of small amounts of liquids (micro‐reactors, micro‐pumps) . The LM use in cosmetics has been also suggested, due to the non‐oily feel imparted to skin by marbles .…”

Section: Introductionmentioning

confidence: 99%

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The Potential of Liquid Marbles for Biomedical Applications: A Critical Review

Oliveira

Reis

Mano

2017

Adv Healthcare Materials

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Liquid marbles (LM) are freestanding droplets covered by micro/nanoparticles with hydrophobic/hydrophilic properties, which can be manipulated as a soft solid. The phenomenon that generates these soft structures is regarded as a different method to generate a superhydrophobic behavior in the liquid/solid interface without modifying the surface. Several applications for the LM have been reported in very different fields, however the developments for biomedical applications are very recent. At first, the LM properties are reviewed, namely shell structure, LM shape, evaporation, floatability and robustness. The different strategies for LM manipulation are also described, which make use of magnetic, electrostatic and gravitational forces, ultraviolet and infrared radiation, and approaches that induce LM self-propulsion. Then, very distinctive applications for LM in the biomedical field are presented, namely for diagnostic assays, cell culture, drug screening and cryopreservation of mammalian cells. Finally, a critical outlook about the unexplored potential of LM for biomedical applications is presented, suggesting possible advances on this emergent scientific area.

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Section: Liquid Marblesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

The Potential of Liquid Marbles for Biomedical Applications: A Critical Review

Oliveira

Reis

Mano

2017

Adv Healthcare Materials

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“…Liquid marbles stabilized with polystyrene (PS) particles carrying poly[2‐(diethylamino)ethyl methacrylate] (PDEA) hairs were the first to be reported as stimuli‐responsive ( Figure ) . PDEA is a weak polybase with a p K a of 7.3 that is soluble in aqueous media below pH ∼7 because of protonation of its tertiary amine groups.…”

Section: Stimuli‐responsive Liquid Marblesmentioning

confidence: 99%

“…In particular, laser microscopy, confocal laser scanning microscopy, SEM and X‐ray computed tomography are powerful methods to characterize the surface roughness of the liquid marbles. It is expected that the combination of stereomicroscopy and optical microscopy techniques with high speed cameras will allow investigation of the dynamics of disruption, coalescence and motion of the liquid marbles induced by external stimuli at the millisecond timescale . The use of non‐volatile liquids, such as liquid metals, ionic liquids and liquid polymers, enables characterization by SEM and X‐ray photoelectron spectroscopy under high vacuum conditions.…”

Section: Conclusion and Future Research Directionsmentioning

confidence: 99%

Stimuli‐Responsive Liquid Marbles: Controlling Structure, Shape, Stability, and Motion

Fujii

Yusa

Nakamura

2016

Adv Funct Materials

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156

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Liquid marbles" are liquid-in-gas dispersed systems stabilized by hydrophobic solid particles adsorbed at the gas-liquid interface. The structure, stability and movement of these liquid marbles can be controlled by external stimuli such as pH, temperature, light, magnetic and electric fi elds, ultrasonic, mechanical stress and organic solvents. Stimuli-responsive modes can be categorized into fi ve classes: (i) liquid marbles whose stability can be controlled by adsorption/desorption of solid particles to/from liquid surfaces, (ii) liquid marbles that can open and close their particle-coated surface by moving particles to and from the gas-liquid surface, (iii) liquid marbles that can move, (iv) liquid marbles that can change their shape and (v) liquid marbles that can be split. As a result of these stimuli-responsive characteristics, liquid marbles offer potential in the areas of controlled encapsulation, delivery and release.

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“…Due to their several advantages, such as reduced amounts of reagents, shortened reaction rate, enhanced efficiency and flexibility, LMs have been proposed for various applications including gas and liquid sensing (Tian et al, 2010), microreactors (Arbatan et al, 2012), water pollution detection (Bormashenko and Musin, 2009) and medical applications (Avrămescu et al, 2018). There is also a growing interest to further improve their mechanical properties (Chin et al, 2013) or develop analogous systems with higher robustness (Ueno et al, 2015). In our previous research, electrospun nanofibres with engineered wetting properties and morphologies have been optimised and then used to encapsulate water and oil drops (Mele et al, 2014).…”

Section: Introductionmentioning

confidence: 99%