Dynamic Morphologies and Stability of Droplet Interface Bilayers.

Benjamin Guiselin,Buddhapriya Chakrabarti,Halim Kusumaatmaja,Jack O Law

doi:10.1103/physrevlett.120.238001

Benjamin Guiselin, Buddhapriya Chakrabarti + Show 2 more

Open Access

https://doi.org/10.1103/physrevlett.120.238001

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Abstract

We develop a theoretical framework for understanding dynamic morphologies and stability of droplet interface bilayers (DIBs), accounting for lipid kinetics in the monolayers and bilayer, and droplet evaporation due to imbalance between osmotic and Laplace pressures. Our theory quantitatively describes distinct pathways observed in experiments when DIBs become unstable. We find that when the timescale for lipid desorption is slow compared to droplet evaporation, the lipid bilayer will grow and the droplets approach a hemispherical shape. In contrast, when lipid desorption is fast, the bilayer area will shrink and the droplets eventually detach. Our model also suggests there is a critical size below which DIBs can become unstable, which may explain experimental difficulties in miniaturizing the DIB platform.

Highlights

We develop a theoretical framework for understanding dynamic morphologies and stability of droplet interface bilayers (DIBs), accounting for lipid kinetics in the monolayers and bilayer, and droplet evaporation due to imbalance between osmotic and Laplace pressures
We find that when the timescale for lipid desorption is slow compared to droplet evaporation, the lipid bilayer will grow and the droplets approach a hemispherical shape
Droplet interface bilayers (DIBs) are constructed by bringing together two lipid monolayer-encased water droplets submerged in oil [1,2]

Summary

Dynamic Morphologies and Stability of Droplet Interface Bilayers

A number of membrane proteins have been successfully reconstituted across DIBs, including the viral potassium channel, the light-driven proton pump bacteriorhodopsin, and the mechanosensitive channel of large conductance [17,18,19,20] Given these advantages, the potential applications of DIBs are wide ranging, from droplet arrays for ion channel screening [19,20] and chemical microreactors [21,22] to responsive materials [9,23,24] and mimics of electrical circuits and logic gates [25]. We elucidate a mechanistic understanding for both the dynamic morphology diagram and DIB stability, arising out of a competition between four characteristic timescales: lipid desorptions for the (i) monolayers and (ii) bilayers,

Published by the American Physical Society

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