Layer-by-Layer Deposition of Vesicles Mediated by Supramolecular Interactions

Roling, Oliver; Wendeln, Christian; Kauscher, Ulrike; Seelheim, Patrick; Galla, Hans‐Joachim; Ravoo, Bart Jan

doi:10.1021/la4011218

Cited by 38 publications

(54 citation statements)

References 46 publications

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“…Composite films, in which SAv functions as a supramolecular glue to assemble multiple layers of nano-objects, have also been realized. 19,21 The efficiency of surface functionalization and the stability of the whole surface-confined architecture depend in these systems on the residual valency, i.e., the amount of biotin-binding sites that remain accessible after SAv attachment to the surface.…”

Section: Introductionmentioning

confidence: 99%

Controlling Multivalent Binding through Surface Chemistry: Model Study on Streptavidin

et al. 2017

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Although multivalent binding to surfaces is an important tool in nanotechnology, quantitative information about the residual valency and orientation of surface-bound molecules is missing. To address these questions, we study streptavidin (SAv) binding to commonly used biotinylated surfaces such as supported lipid bilayers (SLBs) and self-assembled monolayers (SAMs). Stability and kinetics of SAv binding are characterized by quartz crystal microbalance with dissipation monitoring, while the residual valency of immobilized SAv is quantified using spectroscopic ellipsometry by monitoring binding of biotinylated probes. Purpose-designed SAv constructs having controlled valencies (mono-, di-, trivalent in terms of biotin-binding sites) are studied to rationalize the results obtained on regular (tetravalent) SAv. We find that divalent interaction of SAv with biotinylated surfaces is a strict requirement for stable immobilization, while monovalent attachment is reversible and, in the case of SLBs, leads to the extraction of biotinylated lipids from the bilayer. The surface density and lateral mobility of biotin, and the SAv surface coverage are all found to influence the average orientation and residual valency of SAv on a biotinylated surface. We demonstrate how the residual valency can be adjusted to one or two biotin binding sites per immobilized SAv by choosing appropriate surface chemistry. The obtained results provide means for the rational design of surface-confined supramolecular architectures involving specific biointeractions at tunable valency. This knowledge can be used for the development of well-defined bioactive coatings, biosensors and biomimetic model systems.

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Section: Introductionmentioning

confidence: 99%

Controlling Multivalent Binding through Surface Chemistry: Model Study on Streptavidin

et al. 2017

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“…As a proof of concept for the tethering of biomolecules to P3OT using the PFB molecular handle, we synthesized a previously reported biotinylated thiol derivative 41 and reacted it with P3OT–PFB under the same conditions as other typical thiol nucleophiles. Despite the low solubility of biotin–SH in organic solvents, the reaction proceeded to completion within 12 hours, albeit with a substantial detrimental effect on the solubility of the resulting polymer.…”

Section: Resultsmentioning

confidence: 99%

“…For example biotin, a molecule extensively studied and used for its strong binding to the protein avidin, was tethered to the mono-functionalized polymer via a thiol linker, opening the door for further biomarkers to be investigated. 41–43 …”

Section: Introductionmentioning

confidence: 99%

Pentafluorobenzene end-group as a versatile handle for para fluoro “click” functionalization of polythiophenes

et al. 2017

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“…The potentials of the method for the fabrication of films with relatively complex but yet well controlled structures, have been explored in many varied fields of technology, since its introduction (Agarwal, et al, 2010;Aldea-Nunzi, Chan, Man, & Nunzi, 2013;Carosio, Alongi, & Malucelli, 2013;Du, Yang, Zhang, & Jiao, 2009;Johnston, Cortez, Angelatos, & Caruso, 2006;Kochan, Wintgens, Wong, & Melin, 2010;Podsiadlo, et al, 2009;Ramsden, Lvov, & Decher, 1995;Song, et al, 2013). The technique has been extended to include deposition of alternating layers of polymers and small nanoparticles (B. S. Kim, Park, & Hammond, 2008) and, more recently, vesicles (Roling, et al, 2013).…”

Section: Introductionmentioning

confidence: 99%

Colloidal interactions induced by overlap of mixed protein+polysaccharide interfacial layers

Ettelaie

Akinshina

2014

Food Hydrocolloids

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Colloidal interaction potentials induced by the overlap of mixed protein + polysaccharide interfacial layers, formed solely as a result of electrostatic attraction between these two biopolymers, have been calculated using the Self Consistent Field Theory. A significant difference between the nature and magnitude of these interactions, depending on the manner in which the charge is distributed along the length of the polysaccharide molecules, was predicted. For chains with an even distribution of charge, the repulsive interactions are in general weaker than those mediated by pure protein layers. For strongly charged polysaccharide chains, these become even attractive at a certain range of particle-particle separations. In part this is due to bridging by polysaccharides, occurring between opposite layers. However, in systems containing strongly charged polyelectrolyte, it is also the result of what in practice may be interpreted as a coacervate of protein + polysaccharide, with a tendency for aggregation, forming interfacial layers on the surface of the particles. In contrast, when the charge of the polysaccharide chains is unevenly distributed, the induced repulsive forces are much enhanced and become longer ranged compared to those for pure protein layers. Once the layers begin to overlap, the electro-steric interactions produced are found to completely overwhelm any van der Waals attraction, thus dictating the inter-particle interactions. We also present some preliminary calculations investigating the competitive adsorption of different polysaccharides onto the protein layer. The initial results, for polysaccharides of the same size and overall charge, suggest that the heterogeneously charged polyelectrolyte completely dominates the adsorption onto the surface, displacing all uniformly charged chains from the interface.

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Layer-by-Layer Deposition of Vesicles Mediated by Supramolecular Interactions

Cited by 38 publications

References 46 publications

Controlling Multivalent Binding through Surface Chemistry: Model Study on Streptavidin

Controlling Multivalent Binding through Surface Chemistry: Model Study on Streptavidin

Pentafluorobenzene end-group as a versatile handle for para fluoro “click” functionalization of polythiophenes

Colloidal interactions induced by overlap of mixed protein+polysaccharide interfacial layers

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