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Stimuli-responsive aqueous microgels: properties and applications

Mikhail Vladimirovich Anakhov 1
Mikhail Vladimirovich Anakhov
Rustam Anrikovich Gumerov 1, 2
Rustam Anrikovich Gumerov
Igor Ivanovich Potemkin 1, 2, 3
Igor Ivanovich Potemkin
10.1016/j.mencom.2020.09.002
Published 2020-08-31
Focus articleVolume 30, Issue 5, 555-562
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Anakhov M. V., Gumerov R. A., Potemkin I. I. Stimuli-responsive aqueous microgels: properties and applications // Mendeleev Communications. 2020. Vol. 30. No. 5. pp. 555-562.
GOST all authors (up to 50) Copy
Anakhov M. V., Gumerov R. A., Potemkin I. I. Stimuli-responsive aqueous microgels: properties and applications // Mendeleev Communications. 2020. Vol. 30. No. 5. pp. 555-562.
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TY - JOUR
DO - 10.1016/j.mencom.2020.09.002
UR - https://mendcomm.colab.ws/publications/10.1016/j.mencom.2020.09.002
TI - Stimuli-responsive aqueous microgels: properties and applications
T2 - Mendeleev Communications
AU - Anakhov, Mikhail Vladimirovich
AU - Gumerov, Rustam Anrikovich
AU - Potemkin, Igor Ivanovich
PY - 2020
DA - 2020/08/31
PB - Mendeleev Communications
SP - 555-562
IS - 5
VL - 30
ER -
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@article{2020_Anakhov,
author = {Mikhail Vladimirovich Anakhov and Rustam Anrikovich Gumerov and Igor Ivanovich Potemkin},
title = {Stimuli-responsive aqueous microgels: properties and applications},
journal = {Mendeleev Communications},
year = {2020},
volume = {30},
publisher = {Mendeleev Communications},
month = {Aug},
url = {https://mendcomm.colab.ws/publications/10.1016/j.mencom.2020.09.002},
number = {5},
pages = {555--562},
doi = {10.1016/j.mencom.2020.09.002}
}
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Anakhov, Mikhail Vladimirovich, et al. “Stimuli-responsive aqueous microgels: properties and applications.” Mendeleev Communications, vol. 30, no. 5, Aug. 2020, pp. 555-562. https://mendcomm.colab.ws/publications/10.1016/j.mencom.2020.09.002.
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Keywords

catalysis
drug delivery
emulsion stabilization
microgels
stimuli-responsiveness

Abstract

Water-soluble microgels have been known for over than three decades. Initially introduced as thermoresponsive polymer colloids with tunable softness, these macromolecular objects become a versatile platform for a broad range of potential applications due to the bursting growth of the diversity of their chemical architecture through the years. The recent progress in the design of stimuli-responsive microgels together with the notable examples of their applications is discussed in this paper.

References

1.
Functional Microgels and Microgel Systems
Plamper F.A., Richtering W.
Accounts of Chemical Research, 2017
2.
Nanogels and Microgels: From Model Colloids to Applications, Recent Developments, and Future Trends
Karg M., Pich A., Hellweg T., Hoare T., Lyon L.A., Crassous J.J., Suzuki D., Gumerov R.A., Schneider S., Potemkin I.I., Richtering W.
Langmuir, 2019
3.
The Polymer/Colloid Duality of Microgel Suspensions
Lyon L.A., Fernandez-Nieves A.
Annual Review of Physical Chemistry, 2012
6.
Designing responsive microgels for drug delivery applications
Smeets N.M., Hoare T.
Journal of Polymer Science, Part A: Polymer Chemistry, 2013
7.
Could multiresponsive hollow shell–shell nanocontainers offer an improved strategy for drug delivery?
Richtering W., Potemkin I.I., Rudov A.A., Sellge G., Trautwein C.
Nanomedicine, 2016
8.
Microgels at fluid-fluid interfaces for food and drinks
Murray B.S.
Advances in Colloid and Interface Science, 2019
10.
Preparation of aqueous latices with N-isopropylacrylamide
Pelton R.H., Chibante P.
Colloids and Surfaces, 1986
11.
Temperature-sensitive aqueous microgels
Pelton R.
Advances in Colloid and Interface Science, 2000
12.
Structure and polymer dynamics within PNIPAM-based microgel particles.
Sierra-Martin B., Retama J.R., Laurenti M., Fernández Barbero A., López Cabarcos E.
Advances in Colloid and Interface Science, 2014
13.
Poly(N-vinylcaprolactam) Microgel Particles Grafted with Amphiphilic Chains
Laukkanen A., Hietala S., Maunu S.L., Tenhu H.
Macromolecules, 2000
16.
Temperature-Sensitive Core–Shell Microgel Particles with Dense Shell
Berndt I., Pedersen J.S., Richtering W.
Angewandte Chemie - International Edition, 2006
18.
Deformation of Microgels at Solid–Liquid Interfaces Visualized in Three-Dimension
Hoppe Alvarez L., Eisold S., Gumerov R.A., Strauch M., Rudov A.A., Lenssen P., Merhof D., Potemkin I.I., Simon U., Wöll D.
Nano Letters, 2019
20.
Smart Homopolymer Microgels: Influence of the Monomer Structure on the Particle Properties
Wedel B., Hertle Y., Wrede O., Bookhold J., Hellweg T.
Polymers, 2016
21.
Volume phase transition kinetics of smart N-n-propylacrylamide microgels studied by time-resolved pressure jump small angle neutron scattering
Wrede O., Reimann Y., Lülsdorf S., Emmrich D., Schneider K., Schmid A.J., Zauser D., Hannappel Y., Beyer A., Schweins R., Gölzhäuser A., Hellweg T., Sottmann T.
Scientific Reports, 2018
22.
Development of fluorescent microgel thermometers based on thermo-responsive polymers and their modulation of sensitivity range
Iwai K., Matsumura Y., Uchiyama S., de Silva A.P.
Journal of Materials Chemistry A, 2005
23.
Copolymer microgels by precipitation polymerisation of N-vinylcaprolactam and N-isopropylacrylamides in aqueous medium
Balaceanu A., Mayorga V., Lin W., Schürings M., Demco D.E., Böker A., Winnik M.A., Pich A.
Colloid and Polymer Science, 2012
24.
Cononsolvency of mono- and di-alkyl N-substituted poly(acrylamide)s and poly(vinyl caprolactam)
Scherzinger C., Balaceanu A., Hofmann C.H., Schwarz A., Leonhard K., Pich A., Richtering W.
Polymer, 2015
27.
Responsive P(NIPAM-co-NtBAM) microgels: Flory–Rehner description of the swelling behaviour
Hertle Y., Zeiser M., Hasenöhrl C., Busch P., Hellweg T.
Colloid and Polymer Science, 2010
29.
Anisotropic responsive microgels with tuneable shape and interactions
Crassous J.J., Mihut A.M., Månsson L.K., Schurtenberger P.
Nanoscale, 2015
31.
Sortase-Mediated Surface Functionalization of Stimuli-Responsive Microgels
Gau E., Mate D.M., Zou Z., Oppermann A., Töpel A., Jakob F., Wöll D., Schwaneberg U., Pich A.
Biomacromolecules, 2017
33.
Amphiphilic PVCL/TBCHA microgels: From synthesis to characterization in a highly selective solvent
Gumerov R.A., Gau E., Xu W., Melle A., Filippov S.A., Sorokina A.S., Wolter N.A., Pich A., Potemkin I.I.
Journal of Colloid and Interface Science, 2020
34.
Colloidal copolymer microgels of N-isopropylacrylamide and acrylic acid: pH, ionic strength and temperature effects
Snowden M.J., Chowdhry B.Z., Vincent B., Morris G.E.
Journal of the Chemical Society Faraday Transactions, 1996
35.
Temperature, pH, and Ionic Strength Induced Changes of the Swelling Behavior of PNIPAM−Poly(allylacetic acid) Copolymer Microgels
Karg M., Pastoriza-Santos I., Rodriguez-González B., von Klitzing R., Wellert S., Hellweg T.
Langmuir, 2008
38.
Preparation and characterization of poly ( N -isopropylacrylamide- co -dimethylaminoethyl methacrylate) microgel latexes
Zha L., Hu J., Wang C., Fu S., Elaissari A., Zhang Y.
Colloid and Polymer Science, 2002
39.
Physicochemical Properties of Poly(N-isopropylacrylamide-co-4-vinylpyridine) Cationic Polyelectrolyte Colloidal Microgels
Pinkrah V.T., Snowden M.J., Mitchell J.C., Seidel J., Chowdhry B.Z., Fern G.R.
Langmuir, 2003
42.
Flocculation of microgel particles
Rasmusson M., Vincent B.
Reactive and Functional Polymers, 2004
43.
Universal conformational properties of polymers in ionic nanogels
Kobayashi H., Winkler R.G.
Scientific Reports, 2016
45.
Polyampholyte Microgels with Anionic Core and Cationic Shell
Schachschal S., Balaceanu A., Melian C., Demco D.E., Eckert T., Richtering W., Pich A.
Macromolecules, 2010
48.
Stimuli-Responsive Zwitterionic Microgels with Covalent and Ionic Cross-Links
Schroeder R., Richtering W., Potemkin I.I., Pich A.
Macromolecules, 2018
49.
Preparation of thermosensitive nanogels by photo-cross-linking
Vo C.D., Kuckling D., Adler H.-., Sch�nhoff M.
Colloid and Polymer Science, 2002
51.
Microgel Size Modulation by Electrochemical Switching
Mergel O., Wünnemann P., Simon U., Böker A., Plamper F.A.
Chemistry of Materials, 2015
52.
Model-based design and synthesis of ferrocene containing microgels
Schneider S., Jung F., Mergel O., Lammertz J., Nickel A.C., Caumanns T., Mhamdi A., Mayer J., Mitsos A., Plamper F.A.
Polymer Chemistry, 2020
53.
Janus Microgels Prepared by Surfactant-Free Pickering Emulsion-Based Modification and Their Self-Assembly
Suzuki D., Tsuji S., Kawaguchi H.
Journal of the American Chemical Society, 2007
54.
Aqueous microgels modified with photosensitive wedge-shaped amphiphilic molecules: synthesis, structure and photochemical behaviour
Dolgopolov A.V., Grafskaia K.N., Bovsunovskaya P.V., Melnikova E.R., Ivanov D.A., Pich A., Zhu X., Möller M.
Photochemical and Photobiological Sciences, 2019
56.
The kinetics of poly(N-isopropylacrylamide) microgel latex formation
Wu X., Pelton R.H., Hamielec A.E., Woods D.R., McPhee W.
Colloid and Polymer Science, 1994
57.
Small-angle neutron scattering study of structural changes in temperature sensitive microgel colloids
Stieger M., Richtering W., Pedersen J.S., Lindner P.
Journal of Chemical Physics, 2004
59.
N -vinylcaprolactam-based microgels: Synthesis and characterization
Imaz A., Forcada J.
Journal of Polymer Science, Part A: Polymer Chemistry, 2008
61.
A comparison of the network structure and inner dynamics of homogeneously and heterogeneously crosslinked PNIPAM microgels with high crosslinker content
Witte J., Kyrey T., Lutzki J., Dahl A.M., Houston J., Radulescu A., Pipich V., Stingaciu L., Kühnhammer M., Witt M.U., von Klitzing R., Holderer O., Wellert S.
Soft Matter, 2019
62.
Dynamically Cross-Linked Self-Assembled Thermoresponsive Microgels with Homogeneous Internal Structures
Mueller E., Alsop R.J., Scotti A., Bleuel M., Rheinstädter M.C., Richtering W., Hoare T.
Langmuir, 2018
63.
A straightforward synthesis of fluorescent and temperature-responsive nanogels
Crespy D., Zuber S., Turshatov A., Landfester K., Popa A.
Journal of Polymer Science, Part A: Polymer Chemistry, 2011
64.
Multicompartment aqueous microgels with degradable hydrophobic domains
Kehren D., Lopez C.M., Theiler S., Keul H., Möller M., Pich A.
Polymer, 2019
65.
Doubly Temperature Sensitive Core−Shell Microgels
Berndt I., Richtering W.
Macromolecules, 2003
66.
Core–Shell Microgel-Based Surface Coatings with Linear Thermoresponse
Cors M., Wrede O., Genix A., Anselmetti D., Oberdisse J., Hellweg T.
Langmuir, 2017
67.
Solvent Induced Inversion of Core–Shell Microgels
Ghavami A., Winkler R.G.
ACS Macro Letters, 2017
68.
Intramicrogel Complexation of Oppositely Charged Compartments As a Route to Quasi-Hollow Structures
Rudov A.A., Gelissen A.P., Lotze G., Schmid A., Eckert T., Pich A., Richtering W., Potemkin I.I.
Macromolecules, 2017
69.
Hollow Thermoresponsive Microgels
Nayak S., Gan D., Serpe M., Lyon L.?.
Small, 2005
70.
How Hollow Are Thermoresponsive Hollow Nanogels?
Dubbert J., Honold T., Pedersen J.S., Radulescu A., Drechsler M., Karg M., Richtering W.
Macromolecules, 2014
72.
Anisotropic Hollow Microgels That Can Adapt Their Size, Shape, and Softness
Nickel A.C., Scotti A., Houston J.E., Ito T., Crassous J., Pedersen J.S., Richtering W.
Nano Letters, 2019
73.
Tailoring the Cavity of Hollow Polyelectrolyte Microgels
Wypysek S.K., Scotti A., Alziyadi M.O., Potemkin I.I., Denton A.R., Richtering W.
Macromolecular Rapid Communications, 2019
74.
Multi-Shell Hollow Nanogels with Responsive Shell Permeability
Schmid A.J., Dubbert J., Rudov A.A., Pedersen J.S., Lindner P., Karg M., Potemkin I.I., Richtering W.
Scientific Reports, 2016
75.
Swelling of a Responsive Network within Different Constraints in Multi-Thermosensitive Microgels
Brugnoni M., Scotti A., Rudov A.A., Gelissen A.P., Caumanns T., Radulescu A., Eckert T., Pich A., Potemkin I.I., Richtering W.
Macromolecules, 2018
77.
Compartmentalized Jet Polymerization as a High‐Resolution Process to Continuously Produce Anisometric Microgel Rods with Adjustable Size and Stiffness
Krüger A.J., Bakirman O., Guerzoni L.P., Jans A., Gehlen D.B., Rommel D., Haraszti T., Kuehne A.J., De Laporte L.
Advanced Materials, 2019
78.
Soft temperature-responsive microgels of complex shape in stop-flow lithography
Wolff H.J., Linkhorst J., Göttlich T., Savinsky J., Krüger A.J., de Laporte L., Wessling M.
Lab on a Chip, 2020
80.
Synthesis of Polyampholyte Janus‐like Microgels by Coacervation of Reactive Precursors in Precipitation Polymerization
Xu W., Rudov A., Oppermann A., Wypysek S., Kather M., Schroeder R., Richtering W., Potemkin I.I., Wöll D., Pich A.
Angewandte Chemie - International Edition, 2019
83.
Dynamical behavior of microgels of interpenetrated polymer networks
Nigro V., Angelini R., Bertoldo M., Bruni F., Ricci M.A., Ruzicka B.
Soft Matter, 2017
84.
Shell–corona microgels from double interpenetrating networks
Rudyak V.Y., Gavrilov A.A., Kozhunova E.Y., Chertovich A.V.
Soft Matter, 2018
86.
The interaction of thermosensitive, anionic microgels with metal ion solution species
Morris G.E., Vincent B., Snowden M.J.
Colloid and Polymer Science, 1997
89.
Colloidal microgel in removal of water from biodiesel
Nur H., Snowden M.J., Cornelius V.J., Mitchell J.C., Harvey P.J., Benée L.S.
Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2009
90.
Interaction between lysozyme and colloidal poly(NIPAM-co-acrylic acid) microgels
Johansson C., Gernandt J., Bradley M., Vincent B., Hansson P.
Journal of Colloid and Interface Science, 2010
91.
Microgel/clay nanohybrids as responsive scavenger systems
Berger S., Singh R., Sudha J.D., Adler H., Pich A.
Polymer, 2010
93.
Poly (N-Isopropylacrylamide) Microgels for Organic Dye Removal from Water
Parasuraman D., Serpe M.J.
ACS applied materials & interfaces, 2011
95.
Dual-Stimuli-Sensitive Microgels as a Tool for Stimulated Spongelike Adsorption of Biomaterials for Biosensor Applications
Sigolaeva L.V., Gladyr S.Y., Gelissen A.P., Mergel O., Pergushov D.V., Kurochkin I.N., Plamper F.A., Richtering W.
Biomacromolecules, 2014
96.
Loading of PNIPAM Based Microgels with CoFe2O4 Nanoparticles and Their Magnetic Response in Bulk and at Surfaces
Backes S., Witt M.U., Roeben E., Kuhrts L., Aleed S., Schmidt A.M., von Klitzing R.
Journal of Physical Chemistry B, 2015
97.
Photosensitive microgels containing azobenzene surfactants of different charges
Schimka S., Lomadze N., Rabe M., Kopyshev A., Lehmann M., von Klitzing R., Rumyantsev A.M., Kramarenko E.Y., Santer S.
Physical Chemistry Chemical Physics, 2017
98.
An anionic shell shields a cationic core allowing for uptake and release of polyelectrolytes within core–shell responsive microgels
Gelissen A.P., Scotti A., Turnhoff S.K., Janssen C., Radulescu A., Pich A., Rudov A.A., Potemkin I.I., Richtering W.
Soft Matter, 2018
99.
Sandzhieva A.V., Sybachin A.V., Zaborova O.V., Ballauff M., Yaroslavov A.A.
Mendeleev Communications, 2018
100.
In Situ Growth and Size Regulation of Single Gold Nanoparticles in Composite Microgels
Thies S., Simon P., Zelenina I., Mertens L., Pich A.
Small, 2018
102.
Scavenging One of the Liquids versus Emulsion Stabilization by Microgels in a Mixture of Two Immiscible Liquids
Anakhov M.V., Gumerov R.A., Richtering W., Pich A., Potemkin I.I.
ACS Macro Letters, 2020
103.
Hydrophobic Monomers Recognize Microenvironments in Hydrogel Microspheres during Free‐Radical‐Seeded Emulsion Polymerization
Watanabe T., Nishizawa Y., Minato H., Song C., Murata K., Suzuki D.
Angewandte Chemie - International Edition, 2020
104.
Hard and soft colloids at fluid interfaces: Adsorption, interactions, assembly & rheology
Deshmukh O.S., van den Ende D., Stuart M.C., Mugele F., Duits M.H.
Advances in Colloid and Interface Science, 2015
105.
When Colloidal Particles Become Polymer Coils
Mourran A., Wu Y., Gumerov R.A., Rudov A.A., Potemkin I.I., Pich A., Möller M.
Langmuir, 2016
106.
Smart nanogels at the air/water interface: structural studies by neutron reflectivity
Zielińska K., Sun H., Campbell R.A., Zarbakhsh A., Resmini M.
Nanoscale, 2016
108.
Thermoresponsive microgels at the air–water interface: the impact of the swelling state on interfacial conformation
Maldonado-Valderrama J., del Castillo-Santaella T., Adroher-Benítez I., Moncho-Jordá A., Martín-Molina A.
Soft Matter, 2017
109.
Organization of Microgels at the Air–Water Interface under Compression: Role of Electrostatics and Cross-Linking Density
Picard C., Garrigue P., Tatry M., Lapeyre V., Ravaine S., Schmitt V., Ravaine V.
Langmuir, 2017
110.
The deformation of hydrogel microspheres at the air/water interface
Minato H., Murai M., Watanabe T., Matsui S., Takizawa M., Kureha T., Suzuki D.
Chemical Communications, 2018
111.
Stimuli-responsive behavior of PNiPAm microgels under interfacial confinement.
Harrer J., Rey M., Ciarella S., Löwen H., Janssen L.M., Vogel N.
Langmuir, 2019
112.
Novel emulsions stabilized by pH and temperature sensitive microgels
Ngai T., Behrens S.H., Auweter H.
Chemical Communications, 2005
113.
Poly(N-isopropylacrylamide) Microgels at the Oil−Water Interface: Interfacial Properties as a Function of Temperature
Monteux C., Marlière C., Paris P., Pantoustier N., Sanson N., Perrin P.
Langmuir, 2010
114.
Soft microgels as Pickering emulsion stabilisers: role of particle deformability
Destribats M., Lapeyre V., Wolfs M., Sellier E., Leal-Calderon F., Ravaine V., Schmitt V.
Soft Matter, 2011
115.
The Compressibility of pH-Sensitive Microgels at the Oil-Water Interface: Higher Charge Leads to Less Repulsion
Geisel K., Isa L., Richtering W.
Angewandte Chemie - International Edition, 2014
116.
Adsorption of microgels at an oil–water interface: correlation between packing and 2D elasticity
Pinaud F., Geisel K., Massé P., Catargi B., Isa L., Richtering W., Ravaine V., Schmitt V.
Soft Matter, 2014
118.
Adsorption of soft particles at fluid interfaces
Style R.W., Isa L., Dufresne E.R.
Soft Matter, 2015
120.
Mixing of Two Immiscible Liquids within the Polymer Microgel Adsorbed at Their Interface
Gumerov R.A., Rumyantsev A.M., Rudov A.A., Pich A., Richtering W., Möller M., Potemkin I.I.
ACS Macro Letters, 2016
121.
A polymer microgel at a liquid–liquid interface: theory vs. computer simulations
Rumyantsev A.M., Gumerov R.A., Potemkin I.I.
Soft Matter, 2016
122.
Compression and deposition of microgel monolayers from fluid interfaces: particle size effects on interface microstructure and nanolithography
Scheidegger L., Fernández-Rodríguez M.Á., Geisel K., Zanini M., Elnathan R., Richtering W., Isa L.
Physical Chemistry Chemical Physics, 2017
123.
Exploring the colloid-to-polymer transition for ultra-low crosslinked microgels from three to two dimensions
Scotti A., Bochenek S., Brugnoni M., Fernandez-Rodriguez M.A., Schulte M.F., Houston J.E., Gelissen A.P., Potemkin I.I., Isa L., Richtering W.
Nature Communications, 2019
124.
Microgels Adsorbed at Liquid–Liquid Interfaces: A Joint Numerical and Experimental Study
Camerin F., Fernández-Rodríguez M.Á., Rovigatti L., Antonopoulou M., Gnan N., Ninarello A., Isa L., Zaccarelli E.
ACS Nano, 2019
125.
Amphiphilic microgels adsorbed at oil–water interfaces as mixers of two immiscible liquids
Gumerov R.A., Filippov S.A., Richtering W., Pich A., Potemkin I.I.
Soft Matter, 2019
126.
Polyelectrolyte Microgels at a Liquid–Liquid Interface: Swelling and Long-Range Ordering
Gavrilov A.A., Richtering W., Potemkin I.I.
Journal of Physical Chemistry B, 2019
127.
Effect of the 3D Swelling of Microgels on Their 2D Phase Behavior at the Liquid–Liquid Interface
Bochenek S., Scotti A., Ogieglo W., Fernández-Rodríguez M.Á., Schulte M.F., Gumerov R.A., Bushuev N.V., Potemkin I.I., Wessling M., Isa L., Richtering W.
Langmuir, 2019
128.
Compression and Ordering of Microgels in Monolayers Formed at Liquid–Liquid Interfaces: Computer Simulation Studies
Bushuev N.V., Gumerov R.A., Bochenek S., Pich A., Richtering W., Potemkin I.I.
ACS applied materials & interfaces, 2020
133.
Tunable Adsorption of Soft Colloids on Model Biomembranes
Mihut A.M., Dabkowska A.P., Crassous J.J., Schurtenberger P., Nylander T.
ACS Nano, 2013
135.
Assembling responsive microgels at responsive lipid membranes
Wang M., Mihut A.M., Rieloff E., Dabkowska A.P., Månsson L.K., Immink J.N., Sparr E., Crassous J.J.
Proceedings of the National Academy of Sciences of the United States of America, 2019
136.
Ultrasoft microgels displaying emergent platelet-like behaviours
Brown A.C., Stabenfeldt S.E., Ahn B., Hannan R.T., Dhada K.S., Herman E.S., Stefanelli V., Guzzetta N., Alexeev A., Lam W.A., Lyon L.A., Barker T.H.
Nature Materials, 2014
138.
Multicompartment Microgel Beads for Co-Delivery of Multiple Drugs at Individual Release Rates
Lai W., Susha A.S., Rogach A.L.
ACS applied materials & interfaces, 2015
139.
Cross-linked Pluronic- g -Polyacrylic acid microgel system for the controlled release of doxorubicin in pharmaceutical formulations
Tian Y., Grishkewich N., Bromberg L., Hatton T.A., Tam K.C.
European Journal of Pharmaceutics and Biopharmaceutics, 2017
140.
Yaroslavov A.A., Efimova A.A., Mulashkin F.D., Rudenskaya G.N., Krivtsov G.G.
Mendeleev Communications, 2018
142.
Smart microgels as drug delivery vehicles for the natural drug aescin: uptake, release and interactions
Dirksen M., Dargel C., Meier L., Brändel T., Hellweg T.
Colloid and Polymer Science, 2020
143.
Microgels as efficient adsorbents for the removal of pollutants from aqueous medium
Naseem K., Hussain Farooqi Z., Zia Ur Rehman M., Atiq Ur Rehman M., Ghufran M.
Reviews in Chemical Engineering, 2018
145.
Selenium‐Modified Microgels as Bio‐Inspired Oxidation Catalysts
Tan K.H., Xu W., Stefka S., Demco D.E., Kharandiuk T., Ivasiv V., Nebesnyi R., Petrovskii V.S., Potemkin I.I., Pich A.
Angewandte Chemie - International Edition, 2019
146.
Microgel-Stabilized Smart Emulsions for Biocatalysis
Wiese S., Spiess A.C., Richtering W.
Angewandte Chemie - International Edition, 2012
147.
Enhanced catalyst performance through compartmentalization exemplified by colloidal l-proline modified microgel catalysts
Kleinschmidt D., Fernandes M.S., Mork M., Meyer A.A., Krischel J., Anakhov M.V., Gumerov R.A., Potemkin I.I., Rueping M., Pich A.
Journal of Colloid and Interface Science, 2020
149.
Microgels as Stimuli-Responsive Stabilizers for Emulsions
Brugger B., Rosen B.A., Richtering W.
Langmuir, 2008
150.
Microgel stabilized emulsions: Breaking on demand
Wiese S., Tsvetkova Y., Daleiden N.J., Spieß A.C., Richtering W.
Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2016
151.
Fully Tunable Silicon Nanowire Arrays Fabricated by Soft Nanoparticle Templating
Rey B.M., Elnathan R., Ditcovski R., Geisel K., Zanini M., Fernandez-Rodriguez M., Naik V.V., Frutiger A., Richtering W., Ellenbogen T., Voelcker N.H., Isa L.
Nano Letters, 2015
152.
Moiré and honeycomb lattices through self-assembly of hard-core/soft-shell microgels: experiment and simulation
Volk K., Deißenbeck F., Mandal S., Löwen H., Karg M.
Physical Chemistry Chemical Physics, 2019
153.
Engineering Systems with Spatially Separated Enzymes via Dual-Stimuli-Sensitive Properties of Microgels
Sigolaeva L.V., Mergel O., Evtushenko E.G., Gladyr S.Y., Gelissen A.P., Pergushov D.V., Kurochkin I.N., Plamper F.A., Richtering W.
Langmuir, 2015
154.
Easy-Preparable Butyrylcholinesterase/Microgel Construct for Facilitated Organophosphate Biosensing
Sigolaeva L.V., Gladyr S.Y., Mergel O., Gelissen A.P., Noyong M., Simon U., Pergushov D.V., Kurochkin I.N., Plamper F.A., Richtering W.
Analytical Chemistry, 2017
155.
Inhibiting Bacterial Adhesion by Mechanically Modulated Microgel Coatings
Keskin D., Mergel O., van der Mei H.C., Busscher H.J., van Rijn P.
Biomacromolecules, 2018
156.
Temperature-Modulated Water Filtration Using Microgel-Functionalized Hollow-Fiber Membranes
Menne D., Pitsch F., Wong J.E., Pich A., Wessling M.
Angewandte Chemie - International Edition, 2014
157.
Tunable permeability and selectivity: Heatable inorganic porous hollow fiber membrane with a thermo-responsive microgel coating
Lohaus T., de Wit P., Kather M., Menne D., Benes N.E., Pich A., Wessling M.
Journal of Membrane Science, 2017
158.
Self-Propelled Microswimmer Actuated by Stimuli-Sensitive Bilayered Hydrogel
Nikolov S.V., Yeh P.D., Alexeev A.
ACS Macro Letters, 2014
159.
Dynamic Switching of Helical Microgel Ribbons
Zhang H., Mourran A., Möller M.
Nano Letters, 2017
160.
A Light‐Driven Microgel Rotor
Zhang H., Koens L., Lauga E., Mourran A., Möller M.
Small, 2019