Liquid–liquid phase separation during amphiphilic self-assembly

Ianiro, Alessandro; Wu, Hanglong; Rijt, Mark M. J. van; Vena, María Paula; Keizer, Arthur D. A.; Esteves, A. Catarina C.; Tuinier, Remco; Friedrich, Heiner; Sommerdijk, Nico A. J. M.; Patterson, Joseph P.

doi:10.1038/s41557-019-0210-4

Cited by 217 publications

(293 citation statements)

References 53 publications

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“…[40] Much work remains to ChemBioChem 2019ChemBioChem , 20,2553ChemBioChem -2568 www.chembiochem.org 2019 Wiley-VCH Verlag GmbH &Co. KGaA, Weinheim be done, but this study demonstrates that reversible coacervate-to-vesicle transformations could be used to promote spontaneous transfer of DNA from membrane-freet om embrane-bound compartments, andu ltimately to sustain genetic information replication through substrate uptake and waste disposal. [101] These studies therefore suggest that coacervate-to-vesicle transitions might be ag eneral phenomenon that could be extended to other building units. It is worth mentioning here that ar ecent study reported the transformation of polymer-based coacervate droplets into polymersomes throughc hanges in the ionic strength [100] (Figure 2I).…”

Section: Controlled Matter Exchangest Hrough Interfacial Membrane Assmentioning

confidence: 87%

Dynamic Synthetic Cells Based on Liquid–Liquid Phase Separation

2019

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Living cells have long been a source of inspiration for chemists. Their capacity of performing complex tasks relies on the spatiotemporal coordination of matter and energy fluxes. Recent years have witnessed growing interest in the bottom‐up construction of cell‐like models capable of reproducing aspects of such dynamic organisation. Liquid–liquid phase‐separation (LLPS) processes in water are increasingly recognised as representing a viable compartmentalisation strategy through which to produce dynamic synthetic cells. Herein, we highlight examples of the dynamic properties of LLPS used to assemble synthetic cells, including their biocatalytic activity, reversible condensation and dissolution, growth and division, and recent directions towards the design of higher‐order structures and behaviour.

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Section: Controlled Matter Exchangest Hrough Interfacial Membrane Assmentioning

confidence: 87%

Dynamic Synthetic Cells Based on Liquid–Liquid Phase Separation

2019

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“…Liquids can enter the holder from one side through a plastic tube connected to the syringe and flow out from the same side through another plastic tube (Figure b‐ II ), allowing continued sample imaging under controllable liquid reaction conditions (Figure b‐ IV ). The flow rate of liquid could be adjusted by the syringe …”

Section: Construction Of In‐situ Temmentioning

confidence: 99%

In‐situ Transmission Electron Microscope Techniques for Heterogeneous Catalysis

Zhang

Liu

et al. 2020

ChemCatChem

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The physicochemical properties of heterogeneous catalysts in static or inert environments often deviate greatly from the properties under in‐situ or working conditions. To gain an insightful understanding of realistic catalyst properties and the corresponding catalytic mechanisms, it is essential to identify and rationalize changes in catalysts under reaction conditions. In recent years, in‐situ transmission electron microscope (in‐situ TEM) techniques have been increasingly developed, offering a unique approach to visualize the evolution of heterogeneous catalysis with ultra‐high spatial resolution, good energy resolution and reasonable temporal resolution under controllable or even realistic catalytic conditions. In this review, we have summarized recent advances in the in‐situ TEM analysis of heterogeneous catalysis, which suggests the great potential of this technique in this important field. Furthermore, technical challenges and possible solutions are discussed.

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“…Flüssig‐flüssig‐Phasenseparation (liquid‐liquid phase separation, LLPS) tritt in Zellen auf, spielt eine Rolle bei Infektionen und ist fundamental bei Selbstorganisationsprozessen von Amphiphilen . Andererseits werden flüssig‐flüssig separierte Vorstufenspezies in anorganischen Systemen, wie beispielsweise Oxidschmelzen und wässrigen Salzlösungen, gebildet.…”

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Stabile Calciumcarbonat‐Pränukleationscluster bestimmen die Flüssig‐flüssig‐Phasenseparation

et al. 2020

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Flüssig‐flüssig‐Phasenseparation (liquid‐liquid phase separation, LLPS) ist eine Zwischenstufe während der Fällung von Calciumcarbonat und man vermutet, dass sie eine entscheidende Rolle in Biomineralisationsprozessen spielt. In diesem Artikel stellen wir ein Modell vor, in dem die Flüssig‐flüssig‐Mischungslücke im wässrigen Calciumcarbonatsystem durch die Thermodynamik der Ionenassoziation in der homogenen Phase bestimmt wird, was experimentell durch potentiometrische Titrationen und kinetische Studien mittels ATR‐FTIR‐Spektroskopie bestätigt wird. Der vorgeschlagene Mechanismus erklärt die variable Löslichkeit von amorphen Calciumcarbonaten und räumt Widersprüche in Literaturdaten aus. Da flüssig‐flüssig amorphe Polymorphie berücksichtigt wird, liefert das Modell Hinweise zum Mechanismus der Polymorphselektion. Es ist allgemein und sollte für andere Systeme als Calciumcarbonat überprüft werden. Ausgehend von stabilen Pränukleationsclustern anstelle von in‐ oder metastabilen Fluktuationen ergibt sich ein neuer Blickwinkel auf die physikalische Chemie der Flüssig‐flüssig‐Phasenseparationen in Biomineralisationsprozessen und darüber hinaus.

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Liquid–liquid phase separation during amphiphilic self-assembly

Cited by 217 publications

References 53 publications

Dynamic Synthetic Cells Based on Liquid–Liquid Phase Separation

Dynamic Synthetic Cells Based on Liquid–Liquid Phase Separation

In‐situ Transmission Electron Microscope Techniques for Heterogeneous Catalysis

Stabile Calciumcarbonat‐Pränukleationscluster bestimmen die Flüssig‐flüssig‐Phasenseparation

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