Supported Lipid Bilayers With Controlled Curvature via Colloidal Lithography
Journal article, 2011

Supported lipid bilayers (SLBs) at surfaces provide a route to quantitatively study molecular interactions with and at lipid membranes via different surface-based analytical techniques. Here, a method to fabricate SLBs with controlled curvatures, in the nanometer regime over large areas, is presented, utilizing lipid vesicle rupture onto nanostructured sensor substrates. Heat treated colloidal particle masks were used as templates to produce silicon dioxide films with systematically varied radius of curvature (ROC, 70 to 170 nm are demonstrated) and quartz crystal microbalance with dissipation monitoring (QCM-D) was used to confirm vesicle rupture onto such structured surfaces. Fluorescence microscopy was used to show fluidity of the supported membranes. The formation of confluent SLBs is demonstrated at the nanostructured surfaces from vesicles composed of POPC lipids. However, at surfaces with decreasing ROCs, vesicle rupture was hindered but with an increasing fraction of the positively charged lipid POEPC in the vesicles, it was possible to form good quality supported bilayers on all curvatures studied. Curved SLBs open up the possibility to systematically study the influence of curvature on molecular interactions at lipid membranes.

membranes

vesicle rupture

adsorption

phospholipid-bilayers

supported lipid bilayer

Membrane curvature

quartz crystal microbalance with

dissipation

nanoparticles

silicon dioxide

quartz-crystal microbalance

surfaces

combined qcm-d

nanopatterning

quantification

liposomes

Author

M. Sundh

Aarhus University

M. Manandhar

Aarhus University

Sofia Svedhem

Chalmers, Applied Physics, Biological Physics

D. S. Sutherland

Aarhus University

IEEE Transactions on Nanobioscience

1536-1241 (ISSN)

Vol. 10 3 187-193 6018313

Subject Categories

Biochemistry and Molecular Biology

DOI

10.1109/TNB.2011.2166086

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4/5/2022 6