Lipid-Bicelle-Coated Microfluidics for Intracellular Delivery with Reduced Fouling

Overview

Journal ACS Appl Mater Interfaces

Publisher American Chemical Society

Specialties Biomedical Engineering
Biotechnology

Date 2020 Sep 17

PMID 32940030

Citations 7

Authors

Jason N Belling

Liv K Heidenreich

Jae Hyeon Park

Lisa M Kawakami

Jack Takahashi

Isaura M Frost

Yao Gong

Thomas D Young

Joshua A Jackman

Steven J Jonas

Nam-Joon Cho

Paul S Weiss

Affiliations

Soon will be listed here.

Abstract

Innovative technologies for intracellular delivery are ushering in a new era for gene editing, enabling the utilization of a patient's own cells for stem cell and immunotherapies. In particular, cell-squeezing platforms provide unconventional forms of intracellular delivery, deforming cells through microfluidic constrictions to generate transient pores and to enable effective diffusion of biomolecular cargo. While these devices are promising gene-editing platforms, they require frequent maintenance due to the accumulation of cellular debris, limiting their potential for reaching the throughputs necessary for scalable cellular therapies. As these cell-squeezing technologies are improved, there is a need to develop next-generation platforms with higher throughput and longer lifespan, importantly, avoiding the buildup of cell debris and thus channel clogging. Here, we report a versatile strategy to coat the channels of microfluidic devices with lipid bilayers based on noncovalent lipid bicelle technology, which led to substantial improvements in reducing cell adhesion and protein adsorption. The antifouling properties of the lipid bilayer coating were evaluated, including membrane uniformity, passivation against nonspecific protein adsorption, and inhibition of cell attachment against multiple cell types. This surface functionalization approach was applied to coat constricted microfluidic channels for the intracellular delivery of fluorescently labeled dextran and plasmid DNA, demonstrating significant reductions in the accumulation of cell debris. Taken together, our work demonstrates that lipid bicelles are a useful tool to fabricate antifouling lipid bilayer coatings in cell-squeezing devices, resulting in reduced nonspecific fouling and cell clogging to improve performance.

Citing Articles

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Nanoarchitectured air-stable supported lipid bilayer incorporating sucrose-bicelle complex system.

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Lipid bilayer coatings for rapid enzyme-linked immunosorbent assay.

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