Preparation of “Mushroom-like” Janus Particles by Site-Selective Surface-Initiated Atom Transfer Radical Polymerization in Aqueous Dispersed Systems

Tanaka, Takuya; Okayama, Masaru; Kitayama, Yukiya; Kagawa, Yasuyuki; Okubo, Masayoshi

doi:10.1021/la904701r

Cited by 123 publications

(114 citation statements)

References 59 publications

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“…In principle, this concept is not limited to macroscopic multilayer films, but can be achieved with colloidal materials, as long as the required anisotropy can be realized and different parts of the colloidal object will respond differently to the external stimulus. In recent years, compositionally anisotropic micro-and nanoparticles have been devised using a range of different synthesis methods including microfluidic and lithographic techniques, [18] particle replication in low surface energy templates, [19] selective crosslinking of polybutadiene segments in terpolymers, [20] lithographic patterning of microspheres, [21] electrochemical [22] and photochemical [23] reduction, templating of porous membranes [24,25] and nanotubes, [26] surfactant aided growth, [27] graft polymerization, [28][29][30] and processes based on controlled surface nucleation. [31] Alternatively, electrohydrodynamic co-jetting is a method to prepare particles and fibers with multiple compartments by transferring fluids through a set of capillaries that can process dissimilar materials.…”

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confidence: 99%

Chemically Controlled Bending of Compositionally Anisotropic Microcylinders

et al. 2011

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confidence: 99%

Chemically Controlled Bending of Compositionally Anisotropic Microcylinders

et al. 2011

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“…"Mushroom-like" PMMA/P(St-co-BIEM)-g-PDM Janus particles with pH-responsive PDM half-shells were fabricated by surface-initiated atom transfer radical polymerization (ATPR) of 2-(dimethylamino)ethylmethacrylate (DM) using spherical PMMA/P(St-co-BIEM) Janus particles with bromine end groups at one side of the surface as macroinitiator (Tanaka et al, 2010) (Figure 13c). …”

Section: Janus Particles and Non-spherical Particlesmentioning

confidence: 99%

“…In addition, the 25 polymer swelling weakens cohesive intermolecular forces between the two polymers due to reduced entanglement between PMMA and P(St-co-BIEM) chains at the interface. When the interfacial stresses caused by uneven swelling of the two hemispheres overcome cohesive forces between them, Janus particles split into two hemispheres, as shown in Figure 13c."Mushroom-like" PMMA/P(St-co-BIEM)-g-PDM Janus particles with pH-responsive PDM half-shells were fabricated by surface-initiated atom transfer radical polymerization (ATPR) of 2-(dimethylamino)ethylmethacrylate (DM) using spherical PMMA/P(St-co-BIEM) Janus particles with bromine end groups at one side of the surface as macroinitiator (Tanaka et al, 2010) (Figure 13c). …”

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confidence: 99%

Structured microparticles with tailored properties produced by membrane emulsification

Vladisavljević

2015

Advances in Colloid and Interface Science

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This paper provides an overview of membrane emulsification routes for fabrication of structured microparticles with tailored properties for specific applications. Direct (bottom-up) and premix (top-down) membrane emulsification processes are discussed including operational, formulation and membrane factors that control the droplet size and droplet generation regimes. A special emphasis was put on different methods of controlled shear generation on membrane surface, such as cross flow on the membrane surface, swirl flow, forward and backward flow pulsations in the continuous phase and membrane oscillations and rotations. Droplets produced by membrane emulsification can be used for synthesis of particles with versatile morphology (solid and hollow, matrix and core/shell, spherical and non-spherical, porous and coherent, composite and homogeneous), which can be surface functionalised and coated or loaded with macromolecules, nanoparticles, quantum dots, drugs, phase change materials and high molecular weight gases to achieve controlled/targeted drug release and impart special optical, chemical, electrical, acoustic, thermal and magnetic properties. The template emulsions including metal-in-oil, solid-in-oil-in-water, oil-in-oil, multilayer, and Pickering emulsions can be produced with high encapsulation efficiency of encapsulated materials and narrow size distribution and transformed into structured particles using a variety of different processes, such as polymerisation (suspension, mini-emulsion, interfacial and in-situ), ionic gelation, chemical crosslinking, melt solidification, internal phase separation, layer-by-layer electrostatic deposition, particle self-assembly, complex coacervation, spray drying, sol-gel processing, and molecular imprinting. Particles fabricated from droplets produced by membrane emulsification include nanoclusters, colloidosomes, carbon aerogel particles, nanoshells, polymeric (molecularly imprinted, hypercrosslinked, Janus and core/shell) particles, solder metal powders and inorganic particles. Membrane 2 emulsification devices operate under constant temperature due to low shear rates on the membrane surface, which range from (1−10) × 10 3 s −1 in a direct process to (1−10) × 10 4 s −1 in a premix process.Keywords: Membrane Emulsification; Polymeric microsphere; Microgel; Janus Particle; Core/Shell Particle, Colloidosome. Membrane emulsificationMembrane emulsification (ME) involves preparation of emulsions by pressing a pure dispersed phase or pre-emulsified mixture of the dispersed and continuous phase through a microporous membrane under controlled injection rate and shear conditions. In direct membrane emulsification (DME), one liquid (a dispersed phase) is injected through a microporous membrane into another immiscible liquid (the continuous phase) (Nakashima et al., 1991;, which leads to the formation of droplets at the membrane/continuous phase interface ( Figure 1a). In premix membrane emulsification (PME) (Figure 1b), a pre-emulsion is pressed through the membrane (...

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“…(a) A micrograph of droplets formed on the surface of SPG membrane in DME ; (b) Micrographs of droplets before PME and after passing 5 times through 8-mSPG membrane . prepared by DME, interfacial polymerisation and plasma-graft pore-filling polymerization (Chu et al, 2002); (c) "Mushroom-like" Janus particles prepared by DME, internal phase separation and surface-initiated atom transfer radical polymerisation (ATRP) (Tanaka et al, 2010); (d) Silica-encapsulated magnetite nanoparticle clusters prepared by DME, solvent pervaporation and sol-gel coating (Chang and Hatton, 2012); (e) PLGA particles coated with silica nanoparticles prepared by layer-by-layer electrostatic deposition of poly(allylamine hydrochloride) (PAH) and silica nanoparticles onto PLGA particles produced by DME ( …”

Section: Chitosanmentioning

confidence: 99%

High-pressure Homogenizer Design

Rayner¹

2015

Engineering Aspects of Food Emulsification and Homogenization

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Preparation of “Mushroom-like” Janus Particles by Site-Selective Surface-Initiated Atom Transfer Radical Polymerization in Aqueous Dispersed Systems

Cited by 123 publications

References 59 publications

Chemically Controlled Bending of Compositionally Anisotropic Microcylinders

Chemically Controlled Bending of Compositionally Anisotropic Microcylinders

Structured microparticles with tailored properties produced by membrane emulsification

High-pressure Homogenizer Design

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