Vortex-assisted DNA delivery

Jun Wang; Yihong Zhan; Victor M. Ugaz; Chang Lu

doi:10.1039/c004472e

Vortex-assisted DNA delivery

Jun Wang
, Yihong Zhan
, Victor M. Ugaz
, Chang Lu

Biomedical Engineering

Stony Brook University

Research output: Contribution to journal › Article › peer-review

57 Scopus citations

Abstract

Electroporation is one of the most widely used methods to deliver exogenous DNA payloads into cells, but a major limitation is that only a small fraction of the total membrane surface is permeabilized. Here we show how this barrier can be easily overcome by harnessing hydrodynamic effects associated with Dean flows that occur along curved paths. Under these conditions, cells are subjected to a combination of transverse vortex motion and rotation that enables the entire membrane surface to become uniformly permeabilized. Greatly improved transfection efficiencies are achievable with only a simple modification to the design of existing continuous flow electroporation systems.

Original language	English
Pages (from-to)	2057-2061
Number of pages	5
Journal	Lab on a Chip
Volume	10
Issue number	16
DOIs	https://doi.org/10.1039/c004472e
State	Published - Aug 21 2010

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10.1039/c004472e

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abstract = "Electroporation is one of the most widely used methods to deliver exogenous DNA payloads into cells, but a major limitation is that only a small fraction of the total membrane surface is permeabilized. Here we show how this barrier can be easily overcome by harnessing hydrodynamic effects associated with Dean flows that occur along curved paths. Under these conditions, cells are subjected to a combination of transverse vortex motion and rotation that enables the entire membrane surface to become uniformly permeabilized. Greatly improved transfection efficiencies are achievable with only a simple modification to the design of existing continuous flow electroporation systems.",

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AU - Lu, Chang

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AB - Electroporation is one of the most widely used methods to deliver exogenous DNA payloads into cells, but a major limitation is that only a small fraction of the total membrane surface is permeabilized. Here we show how this barrier can be easily overcome by harnessing hydrodynamic effects associated with Dean flows that occur along curved paths. Under these conditions, cells are subjected to a combination of transverse vortex motion and rotation that enables the entire membrane surface to become uniformly permeabilized. Greatly improved transfection efficiencies are achievable with only a simple modification to the design of existing continuous flow electroporation systems.

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DO - 10.1039/c004472e

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Vortex-assisted DNA delivery

Abstract

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