Branched-chain and dendritic lipids for nanoparticles

Meanwell, Michael; O’Sullivan, Connor; Howard, Perry L.; Fyles, Thomas M.

doi:10.1139/cjc-2016-0462

Cited by 2 publications

(1 citation statement)

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“…For our envisaged applications, we also require a survey of microfluidic‐formed bilayer membranes and the liposomal size distribution in the presence of poorly tolerated components. We are interested in highly branched lipids as surface‐anchoring groups, and it is essential to characterize how the device copes with unusual lipids in mixtures: Is there fouling of the device? what happens to excluded materials?…”

Section: Introductionmentioning

confidence: 99%

Properties of Liposomes Containing Natural and Synthetic Lipids Formed by Microfluidic Mixing

Zheng¹,

Fyles²

2018

Euro J Lipid Sci & Tech

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Vesicle formation by a staggered herringbone microfluidic mixer is investigated in comparison to a sonication‐extrusion method. Experiments focused on the incorporation efficiency of lipid components, on dye entrapment efficiency, and on the barrier properties of the vesicle bilayers produced. The microfluidic method produces vesicles largely under the control of thermodynamic factors. As a result, the molecular parameters of the lipids (chain length, chain volume, head group area) directly control vesicle diameter. A hydrophobic branched chain sulfonate lipid is incorporated by microfluidic mixing but not by sonication‐extrusion. The vesicles produced by microfluidic mixing can be used to study ion transport by known ionophores and appear to have directly comparable barrier properties to those produced by sonication‐extrusion. Vesicles containing the branched chain sulfonate are highly permeable. The microfluidic mixing method produces predominantly unilamellar vesicles. Practical Applications: The microfluidic device examined offers a new method to reproducibly produce vesicles that are directly controlled by the molecular components of the lipid mixture. The authors show that this method produces vesicles that are equivalent to currently used methods in the study of synthetic ion channels and carriers. Looking forward, thermodynamically controlled self‐assembly will find application in the creation of new membrane systems and assemblies where the vesicles themselves are the building blocks in more extensive structures, and the active components in inter‐vesicle functions. A staggered herringbone microfluidic mixer reproducibly gives size‐controlled unilamellar vesicles having low‐permeability bilayer membranes.

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Section: Introductionmentioning

confidence: 99%