Issue 11, 2021

Efficient encapsulation of functional proteins into erythrocytes by controlled shear-mediated membrane deformation

Abstract

Red blood cells (RBCs) are attractive carriers of biomolecular payloads due to their biocompatibility and the ability to shelter their encapsulated cargo. Commonly employed strategies to encapsulate payloads into RBCs, such as hypotonic shock, membrane fusion or electroporation, often suffer from low throughput and unrecoverable membrane impairment. This work describes an investigation of a method to encapsulate protein payloads into RBCs by controlling membrane deformation either transiently or extendedly in a microfluidic channel. Under the optimized conditions, the loading efficiency of enhanced green fluorescent protein into mouse RBCs increased was about 2.5- and 4-fold compared to that with osmotic entrapment using transient and extended deformation, respectively. Significantly, mouse RBCs loaded with human arginase exhibit higher enzymatic activity and membrane integrity compared to their counterparts loaded by osmotic entrapment. These features together with the fact that this shear-mediated encapsulation strategy allows loading with physiological buffers highlight the key advantages of this approach compared to traditional osmotic entrapment.

Graphical abstract: Efficient encapsulation of functional proteins into erythrocytes by controlled shear-mediated membrane deformation

Supplementary files

Article information

Article type
Communication
Submitted
26 Oct 2020
Accepted
30 Apr 2021
First published
04 May 2021

Lab Chip, 2021,21, 2121-2128

Efficient encapsulation of functional proteins into erythrocytes by controlled shear-mediated membrane deformation

M. H. Rahman, C. H. N. Wong, M. M. Lee, M. K. Chan and Y. Ho, Lab Chip, 2021, 21, 2121 DOI: 10.1039/D0LC01077D

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