Issue 7, 2024

A flexible electrode Array for genetic transfection of different layers of the retina by electroporation

Abstract

Electroporation (in which the permeability of a cell membrane is increased transiently by exposure to an appropriate electric field) has exhibited great potential of becoming an alternative to adeno-associated virus (AAV)-based retina gene delivery. Electroporation eliminates the safety concerns of employing exogenous viruses and exceeds the limit of AAV cargo size. Unfortunately, several concerns (e.g., relatively high electroporation voltage, poor surgical operability and a lack of spatial selectivity of retina tissue) have prevented electroporation from being approved for clinical application (or even clinical trials). In this study, a flexible micro-electrode array for retina electroporation (FERE) was developed for retina electroporation. A suitably shaped flexible substrate and well-placed micro-electrodes were designed to adapt to the retina curvature and generate an evenly distributed electric field on the retina with a significantly reduced electroporation voltage of 5 V. The FERE provided (for the first time) a capability of controlled gene delivery to the different structural layers of retina tissue by precise control of the distribution of the electrical field. After ensuring the surgical operability of the FERE on rabbit eyeballs, the FERE was verified to be capable of transfecting different layers of retina tissue with satisfactory efficiency and minimum damage. Our method bridges the technical gap between laboratory validation and clinical use of retina electroporation.

Graphical abstract: A flexible electrode Array for genetic transfection of different layers of the retina by electroporation

Supplementary files

Article information

Article type
Paper
Submitted
27 Nov 2023
Accepted
01 Feb 2024
First published
14 Feb 2024

Lab Chip, 2024,24, 1957-1964

A flexible electrode Array for genetic transfection of different layers of the retina by electroporation

Y. Zhang, T. Peng, Y. Ge, M. Li, C. Li, J. Xi, Z. Li, Z. Wei and Y. Hu, Lab Chip, 2024, 24, 1957 DOI: 10.1039/D3LC01014G

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