Single cell optical transfection

David J. Stevenson; Frank J. Gunn-Moore; Paul Campbell; Kishan Dholakia

doi:10.1098/rsif.2009.0463

Single cell optical transfection

David J. Stevenson, Frank J. Gunn-Moore, Paul Campbell, Kishan Dholakia

Research output: Contribution to journal › Review article › peer-review

161 Citations (Scopus)

Abstract

The plasma membrane of a eukaryotic cell is impermeable to most hydrophilic substances, yet the insertion of these materials into cells is an extremely important and universal requirement for the cell biologist. To address this need, many transfection techniques have been developed including viral, lipoplex, polyplex, capillary microinjection, gene gun and electroporation. The current discussion explores a procedure called optical injection, where a laser field transiently increases the membrane permeability to allow species to be internalized. If the internalized substance is a nucleic acid, such as DNA, RNA or small interfering RNA ( siRNA), then the process is called optical transfection. This contactless, aseptic, single cell transfection method provides a key nanosurgical tool to the microscopist-the intracellular delivery of reagents and single nanoscopic objects. The experimental possibilities enabled by this technology are only beginning to be realized. A review of optical transfection is presented, along with a forecast of future applications of this rapidly developing and exciting technology.

Original language	English
Pages (from-to)	863-871
Number of pages	9
Journal	Journal of the Royal Society. Interface
Volume	7
Issue number	47
DOIs	https://doi.org/10.1098/rsif.2009.0463
Publication status	Published - 6 Jun 2010

Keywords

optical injection
optical transfection
optoinjection
phototransfection
optoporation
photoporation
FEMTOSECOND LASER-PULSES
MAMMALIAN-CELLS
TARGETED TRANSFECTION
STEM-CELLS
ASSISTED MICROINJECTION
EXOGENOUS MATERIAL
INFRARED-LASER
CULTURED-CELLS
GENE DELIVERY
ANIMAL-CELLS

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10.1098/rsif.2009.0463

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title = "Single cell optical transfection",

abstract = "The plasma membrane of a eukaryotic cell is impermeable to most hydrophilic substances, yet the insertion of these materials into cells is an extremely important and universal requirement for the cell biologist. To address this need, many transfection techniques have been developed including viral, lipoplex, polyplex, capillary microinjection, gene gun and electroporation. The current discussion explores a procedure called optical injection, where a laser field transiently increases the membrane permeability to allow species to be internalized. If the internalized substance is a nucleic acid, such as DNA, RNA or small interfering RNA ( siRNA), then the process is called optical transfection. This contactless, aseptic, single cell transfection method provides a key nanosurgical tool to the microscopist-the intracellular delivery of reagents and single nanoscopic objects. The experimental possibilities enabled by this technology are only beginning to be realized. A review of optical transfection is presented, along with a forecast of future applications of this rapidly developing and exciting technology.",

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author = "Stevenson, {David J.} and Gunn-Moore, {Frank J.} and Paul Campbell and Kishan Dholakia",

year = "2010",

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doi = "10.1098/rsif.2009.0463",

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AU - Stevenson, David J.

AU - Gunn-Moore, Frank J.

AU - Campbell, Paul

AU - Dholakia, Kishan

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N2 - The plasma membrane of a eukaryotic cell is impermeable to most hydrophilic substances, yet the insertion of these materials into cells is an extremely important and universal requirement for the cell biologist. To address this need, many transfection techniques have been developed including viral, lipoplex, polyplex, capillary microinjection, gene gun and electroporation. The current discussion explores a procedure called optical injection, where a laser field transiently increases the membrane permeability to allow species to be internalized. If the internalized substance is a nucleic acid, such as DNA, RNA or small interfering RNA ( siRNA), then the process is called optical transfection. This contactless, aseptic, single cell transfection method provides a key nanosurgical tool to the microscopist-the intracellular delivery of reagents and single nanoscopic objects. The experimental possibilities enabled by this technology are only beginning to be realized. A review of optical transfection is presented, along with a forecast of future applications of this rapidly developing and exciting technology.

AB - The plasma membrane of a eukaryotic cell is impermeable to most hydrophilic substances, yet the insertion of these materials into cells is an extremely important and universal requirement for the cell biologist. To address this need, many transfection techniques have been developed including viral, lipoplex, polyplex, capillary microinjection, gene gun and electroporation. The current discussion explores a procedure called optical injection, where a laser field transiently increases the membrane permeability to allow species to be internalized. If the internalized substance is a nucleic acid, such as DNA, RNA or small interfering RNA ( siRNA), then the process is called optical transfection. This contactless, aseptic, single cell transfection method provides a key nanosurgical tool to the microscopist-the intracellular delivery of reagents and single nanoscopic objects. The experimental possibilities enabled by this technology are only beginning to be realized. A review of optical transfection is presented, along with a forecast of future applications of this rapidly developing and exciting technology.

KW - optical injection

KW - optical transfection

KW - optoinjection

KW - phototransfection

KW - optoporation

KW - photoporation

KW - FEMTOSECOND LASER-PULSES

KW - MAMMALIAN-CELLS

KW - TARGETED TRANSFECTION

KW - STEM-CELLS

KW - ASSISTED MICROINJECTION

KW - EXOGENOUS MATERIAL

KW - INFRARED-LASER

KW - CULTURED-CELLS

KW - GENE DELIVERY

KW - ANIMAL-CELLS

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DO - 10.1098/rsif.2009.0463

M3 - Review article

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VL - 7

SP - 863

EP - 871

JO - Journal of the Royal Society. Interface

JF - Journal of the Royal Society. Interface

IS - 47

ER -

Single cell optical transfection

Abstract

Keywords

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