TY  - JOUR
A1  - Schürings, Marco-Philipp
A1  - Nevskyi, Oleksii
A1  - Eliasch, Kamill
A1  - Michel, Ann-Katrin
A1  - Liu, Bing
A1  - Pich, Andrij
A1  - Böker, Alexander
A1  - von Plessen, Gero
A1  - Wöll, Dominik
T1  - Diffusive Motion of Linear Microgel Assemblies in Solution
JF  - Polymers
N2  - Due to the ability of microgels to rapidly contract and expand in response to external stimuli, assemblies of interconnected microgels are promising for actuation applications, e.g., as contracting fibers for artificial muscles. Among the properties determining the suitability of microgel assemblies for actuation are mechanical parameters such as bending stiffness and mobility. Here, we study the properties of linear, one-dimensional chains of poly(N-vinylcaprolactam) microgels dispersed in water. They were fabricated by utilizing wrinkled surfaces as templates and UV-cross-linking the microgels. We image the shapes of the chains on surfaces and in solution using atomic force microscopy (AFM) and fluorescence microscopy, respectively. In solution, the chains are observed to execute translational and rotational diffusive motions. Evaluation of the motions yields translational and rotational diffusion coefficients and, from the translational diffusion coefficient, the chain mobility. The microgel chains show no perceptible bending, which yields a lower limit on their bending stiffness.
KW  - microgels
KW  - linear assemblies
KW  - in situ fluorescence microscopy
KW  - shape analysis
KW  - rotational diffusion
KW  - translational diffusion
KW  - bending stiffness
KW  - actuation
Y1  - 2016
U6  - https://doi.org/10.3390/polym8120413
SN  - 2073-4360
VL  - 8
PB  - MDPI
CY  - Basel
ER  - 
TY  - GEN
A1  - Raju, Rajarshi Roy
A1  - Liebig, Ferenc
A1  - Hess, Andreas
A1  - Schlaad, Helmut
A1  - Koetz, Joachim
T1  - Temperature-triggered reversible breakdown of polymer-stabilized olive
BT  - silicone oil Janus emulsions
T2  - Postprints der Universität Potsdam Mathematisch-Naturwissenschaftliche Reihe
N2  - A one-step moderate energy vibrational emulsification method was successfully employed to produce thermo-responsive olive/silicone-based Janus emulsions stabilized by poly(N,N-diethylacrylamide) carrying 0.7 mol% oleoyl side chains. Completely engulfed emulsion droplets remained stable at room temperature and could be destabilized on demand upon heating to the transition temperature of the polymeric stabilizer. Time-dependent light micrographs demonstrate the temperature-induced breakdown of the Janus droplets, which opens new aspects of application, for instance in biocatalysis.
T3  - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe - 751 
KW  - microgels
KW  - step
Y1  - 2019
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-436461
SN  - 1866-8372
IS  - 751
SP  - 19271
EP  - 19277
ER  - 
TY  - JOUR
A1  - Raju, Rajarshi Roy
A1  - Liebig, Ferenc
A1  - Hess, Andreas
A1  - Schlaad, Helmut
A1  - Koetz, Joachim
T1  - Temperature-triggered reversible breakdown of polymer-stabilized olive
BT  - silicone oil Janus emulsions
JF  - RSC Advances
N2  - A one-step moderate energy vibrational emulsification method was successfully employed to produce thermo-responsive olive/silicone-based Janus emulsions stabilized by poly(N,N-diethylacrylamide) carrying 0.7 mol% oleoyl side chains. Completely engulfed emulsion droplets remained stable at room temperature and could be destabilized on demand upon heating to the transition temperature of the polymeric stabilizer. Time-dependent light micrographs demonstrate the temperature-induced breakdown of the Janus droplets, which opens new aspects of application, for instance in biocatalysis.
KW  - microgels
KW  - step
Y1  - 2019
U6  - https://doi.org/10.1039/c9ra03463c
SN  - 2046-2069
VL  - 9
IS  - 35
SP  - 19271
EP  - 19277
PB  - RSC Publishing
CY  - London
ER  - 
TY  - JOUR
A1  - Vukicevic, Radovan
A1  - Neffe, Axel T.
A1  - Luetzow, Karola
A1  - Pierce, Benjamin F.
A1  - Lendlein, Andreas
T1  - Conditional Ultrasound Sensitivity of Poly[(N-isopropylacrylamide)-co-(vinyl imidazole)] Microgels for Controlled Lipase Release
JF  - Macromolecular rapid communications
N2  - Triggering the release of cargo from a polymer network by ultrasonication as an external, non-invasive stimulus can be an interesting concept for on-demand release. Here, it is shown that, in pH-and thermosensitive microgels, the ultrasound sensitivity of the polymer network depends on the external conditions. Crosslinked poly[(N-isopropylacrylamide)-co-(vinyl imidazole)] microgels showed a volume phase transition temperature (VPTT) of 25-50 degrees C, which increases with decreasing pH. Above the VPTT the polymer chains are collapsed, while below VPTT they are extended. Only in the case of maximum observed swelling, where the polymer chains are expanded, the microgels are mechanically fragmented through ultrasonication. In contrast, when the polymer chains are partially collapsed it is not possible to manipulate the microgels by ultrasound. Additionally, the ultrasound-induced on-demand release of wheat germ lipase from the microgels could be demonstrated successfully. The principle of conditional ultrasound sensitivity is likely to be general and can be used for selection of matrix-cargo combinations.
KW  - ultrasound
KW  - polymers
KW  - microgels
KW  - lipase release
KW  - controlled release
KW  - thermoresponsive polymers
KW  - biomaterials
Y1  - 2015
U6  - https://doi.org/10.1002/marc.201500311
SN  - 1022-1336
SN  - 1521-3927
VL  - 36
IS  - 21
SP  - 1891
EP  - 1896
PB  - Wiley-VCH
CY  - Weinheim
ER  - 
TY  - THES
A1  - Leiendecker, Mai-Thi
T1  - Physikalische Hydrogele auf Polyurethan-Basis
T1  - Physical hydrogels based on polyurethanes
N2  - Physical hydrogels have gained recent attention as cell substrates, since viscoelasticity or stress relaxation is a powerful parameter in mechanotransduction, which has long been neglected. We designed multi-functional polyurethanes to form physical hydrogels via a unique tunable gelation mechanism. The anionic polyurethanes spontaneously form aggregates in water that are kept in a soluble state through electrostatic repulsion. Fast subsequent gelation can be triggered by charge shielding which allows the aggregation and network building to proceed. This can be induced by adding either acids or salts, resulting in acidic (pH 4-5) or pH-neutral hydrogels, respectively. Whereas conventional polyurethane-based hydrogels are commonly prepared from toxic isocyanate precursors, the physical hydrogelation mechanism described here does not involve chemically reactive species which is ideal for in situ applications in sensitive environments. Both stiffness and stress relaxation can be tuned independently over a broad range and the gels exhibit excellent stress recovery behavior.
N2  - Physikalische Hydrogele gewinnen derzeit als Zellsubstrate zunehmend an Interesse, da Viskoelastizität oder Stressrelaxation ein bedeutender Parameter in der Mechanotransduktion ist, der bisher vernachlässigt wurde. In dieser Arbeit wurden multi-funktionelle Polyurethane entworfen, die über einen neuartigen Gelierungsmechanismus physikalische Hydrogele bilden. In Wasser bilden die anionischen Polyurethane spontan Aggregate, welche durch elektrostatische Abstoßung in Lösung gehalten werden. Eine schnelle Gelierung kann von hier aus durch Ladungsabschirmung erreicht werden, wodurch die Aggregation voranschreitet und ein Netzwerk ausgebildet wird. Dies kann durch die Zugabe von verschiedenen Säuren oder Salzen geschehen, sodass sowohl saure (pH 4 - 5) als auch pH-neutrale Hydrogele erhalten werden können. Während konventionelle Hydrogele auf Polyurethan-Basis in der Regel durch toxische isocyanat-haltige Präpolymere hergestellt werden, eignet sich der hier beschriebene physikalische Gelierungsmechanismus für in situ Anwendungen in sensitiven Umgebungen. Sowohl Härte als auch Stressrelaxation der Hydrogele können unabhängig voneinander über einen breiten Bereich eingestellt werden. Darüberhinaus zeichnen sich die Hydrogele durch exzellente Stressregeneration aus.
KW  - Polyurethane
KW  - Hydrogele
KW  - physikalische Hydrogele
KW  - Kolloidchemie
KW  - Viskoelastizität
KW  - Stressrelaxation
KW  - Stressrelaxierung
KW  - Bulkgele
KW  - Mikrogele
KW  - Mechanotransduktion
KW  - polyurethanes
KW  - hydrogels
KW  - physical hydrogels
KW  - colloidal chemistry
KW  - viscoelasticity
KW  - stress-relaxation
KW  - stress relaxation
KW  - bulk gels
KW  - microgels
KW  - mechanotransduction
Y1  - 2016
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-103917
ER  -