Dynamic Morphologies and Stability of Droplet Interface Bilayers

B. Guiselin; J.O. Law; B. Chakrabarti; H. Kusumaatmaja

doi:10.1103/PhysRevLett.120.238001

Dynamic Morphologies and Stability of Droplet Interface Bilayers

B. Guiselin, J.O. Law, B. Chakrabarti, H. Kusumaatmaja

School of Engineering

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Abstract / Description of output

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.

Original language	Undefined/Unknown
Article number	238001
Journal	Physical Review Letters
DOIs	https://doi.org/10.1103/PhysRevLett.120.238001
Publication status	Published - 6 Jun 2018

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title = "Dynamic Morphologies and Stability of Droplet Interface Bilayers",

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.",

author = "B. Guiselin and J.O. Law and B. Chakrabarti and H. Kusumaatmaja",

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doi = "10.1103/PhysRevLett.120.238001",

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AU - Guiselin, B.

AU - Law, J.O.

AU - Chakrabarti, B.

AU - Kusumaatmaja, H.

PY - 2018/6/6

Y1 - 2018/6/6

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AB - 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.

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DO - 10.1103/PhysRevLett.120.238001

M3 - Article

SN - 0031-9007

JO - Physical Review Letters

JF - Physical Review Letters

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ER -

Dynamic Morphologies and Stability of Droplet Interface Bilayers

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