Optical transfection


Optical transfection is the process of introducing nucleic acids into cells using light. Typically, a laser is focussed to a diffraction limited spot using a high numerical aperture microscope objective. The plasma membrane of a cell is then exposed to this highly focussed light for a small amount of time, generating a transient pore on the membrane. The generation of a photopore allows exogenous plasmid DNA, RNA, organic fluorophores, or larger objects such as semiconductor quantum nanodots to enter the cell. In this technique, one cell at a time is treated, making it particularly useful for single cell analysis.
To put the above simply, cells do not usually allow certain types of substances into their interior space. Lasers can be used to burn a tiny hole on the cell surface, allowing those substances to enter. This is tremendously useful to biologists who are studying disease, as a common experimental requirement is to put things into cells.
This technique was first demonstrated in 1984 by Tsukakoshi et al., who used a frequency tripled Nd:YAG to generate stable and transient transfection of normal rat kidney cells. Since this time, the optical transfection of a host of mammalian cell types has been demonstrated using a variety of laser sources, including the 405 nm continuous wave, 488 nm cw, or pulsed sources such as the 800 nm femtosecond pulsed Ti:Sapphire or 1064 nm nanosecod pulsed Nd:YAG.

Terminology

The meaning of the term transfection has evolved. The original meaning of transfection was "infection by transformation", i.e. introduction of DNA from a prokaryote-infecting virus or bacteriophage into cells, resulting in an infection. Because the term transformation had another sense in animal cell biology, the term transfection acquired, for animal cells, its present meaning of a change in cell properties caused by introduction of DNA.
Because of this strict definition of transfection, optical transfection also refers only to the introduction of nucleic acid species. The introduction of other impermeable compounds into a cell, such as organic fluorophores or semiconductor quantum nanodots is not strictly speaking "transfection," and is therefore referred to as "optical injection" or one of the other many terms now outlined.
The lack of a unified name for this technology makes reviewing the literature on the subject very difficult. Optical injection has been described using over a dozen different names or phrases. Some trends in the literature are clear. The first term of the technique is invariably a derivation of word laser, optical, or photo, and the second term is usually in reference to injection, transfection, poration, perforation or puncture. Like many cellular perturbations, when a single cell or group of cells is treated with a laser, three things can happen: the cell dies, the cell membrane is permeabilised, substances enter, and the cell recovers, or nothing happens. There have been suggestions in the literature to reserve the term optoinjection for when a therapeutic dose is delivered upon a single cell, and the term optoporation for when a laser generated shockwave treats a cluster of many cells. The first definition of optoinjection is uncontroversial. The definition of optoporation, however, has failed to be adopted, with a similar number of references using the term to denote the dosing of single cells as those using the term to denote the simultaneous dosing of clusters of many cells
As the field stands, it is the opinion of the authors of a review article on the subject that the term optoinjection always be included as a keyword in future publications, regardless of their own naming preferences.
Terms agreed by consensus
Terms under deliberation

Some of the above was reproduced with permission from.

Methods

A typical optical transfection protocol is as follows:
1) Build an optical tweezers system with a high NA objective
2) Culture cells to 50-60% confluency
3) Expose cells to at least 10 µg/ml of plasmid DNA
4) Dose the plasma membrane of each cell with 10-40 ms of focussed laser, at a power of <100 mW at focus
5) Observe transient transfection 24-96h later
6) Add selective medium if the generation of stable colonies is desired