Issue 4, 2024

Vortex fluidic regulated phospholipid equilibria involving liposomes down to sub-micelle size assemblies

Abstract

Conventional channel-based microfluidic platforms have gained prominence in controlling the bottom-up formation of phospholipid based nanostructures including liposomes. However, there are challenges in the production of liposomes from rapidly scalable processes. These have been overcome using a vortex fluidic device (VFD), which is a thin film microfluidic platform rather than channel-based, affording ∼110 nm diameter liposomes. The high yielding and high throughput continuous flow process has a 45° tilted rapidly rotating glass tube with an inner hydrophobic surface. Processing is also possible in the confined mode of operation which is effective for labelling pre-VFD-prepared liposomes with fluorophore tags for subsequent mechanistic studies on the fate of liposomes under shear stress in the VFD. In situ small-angle neutron scattering (SANS) established the co-existence of liposomes ∼110 nm with small rafts, micelles, distorted micelles, or sub-micelle size assemblies of phospholipid, for increasing rotation speeds. The equilibria between these smaller entities and ∼110 nm liposomes for a specific rotational speed of the tube is consistent with the spatial arrangement and dimensionality of topological fluid flow regimes in the VFD. The prevalence for the formation of ∼110 nm diameter liposomes establishes that this is typically the most stable structure from the bottom-up self-assembly of the phospholipid and is in accord with dimensions of exosomes.

Graphical abstract: Vortex fluidic regulated phospholipid equilibria involving liposomes down to sub-micelle size assemblies

Supplementary files

Article information

Article type
Paper
Submitted
06 Dec 2023
Accepted
17 Jan 2024
First published
18 Jan 2024
This article is Open Access
Creative Commons BY-NC license

Nanoscale Adv., 2024,6, 1202-1212

Vortex fluidic regulated phospholipid equilibria involving liposomes down to sub-micelle size assemblies

N. Joseph, M. Mirzamani, T. Abudiyah, A. H. M. Al-Antaki, M. Jellicoe, D. P. Harvey, E. Crawley, C. Chuah, A. E. Whitten, E. P. Gilbert, S. Qian, L. He, M. Z. Michael, H. Kumari and C. L. Raston, Nanoscale Adv., 2024, 6, 1202 DOI: 10.1039/D3NA01080E

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