Issue 27, 2022

Encapsulated droplet interface bilayers as a platform for high-throughput membrane studies

Abstract

Whilst it is highly desirable to produce artificial lipid bilayer arrays allowing for systematic high-content screening of membrane conditions, it remains a challenge due to the combined requirements of scaled membrane production, simple measurement access, and independent control over individual bilayer experimental conditions. Here, droplet bilayers encapsulated within a hydrogel shell are output individually into multi-well plates for simple, arrayed quantitative measurements. The afforded experimental throughput is used to conduct a 2D concentration screen characterising the synergistic pore-forming peptides Magainin2 and PGLa. Maximal enhanced activity is revealed at equimolar peptide concentrations via a membrane dye leakage assay, a finding consistent with models proposed from NMR data. The versatility of the platform is demonstrated by performing in situ electrophysiology, revealing low conductance pore activity (∼15 to 20 pA with 4.5 pA sub-states). In conclusion, this array platform addresses the aforementioned challenges and provides new and flexible opportunities for high-throughput membrane studies. Furthermore, the ability to engineer droplet networks within each construct paves the way for “lab-in-a-capsule” approaches accommodating multiple assays per construct and allowing for communicative reaction pathways.

Graphical abstract: Encapsulated droplet interface bilayers as a platform for high-throughput membrane studies

Supplementary files

Article information

Article type
Paper
Submitted
30 Jul 2021
Accepted
09 Jun 2022
First published
17 Jun 2022
This article is Open Access
Creative Commons BY-NC license

Soft Matter, 2022,18, 5089-5096

Encapsulated droplet interface bilayers as a platform for high-throughput membrane studies

D. K. Baxani, W. D. Jamieson, D. A. Barrow and O. K. Castell, Soft Matter, 2022, 18, 5089 DOI: 10.1039/D1SM01111A

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