Abstract
In this paper, we demonstrate a new single-cell optoporation and transfection technique using a femtosecond Gaussian laser beam and optical tweezers. Tightly focused near-infrared (NIR) femtosecond laser pulse was employed to transiently perforate the cellular membrane at a single point in MCF-7 cancer cells. A distinct technique was developed by trapping the microparticle using optical tweezers to focus the femtosecond laser precisely on the cell membrane to puncture it. Subsequently, an external gene was introduced in the cell by trapping and inserting the same plasmid-coated microparticle into the optoporated cell using optical tweezers. Various experimental parameters such as femtosecond laser exposure power, exposure time, puncture hole size, exact focusing of the femtosecond laser on the cell membrane, and cell healing time were closely analyzed to create the optimal conditions for cell viability. Following the insertion of plasmid-coated microparticles in the cell, the targeted cells exhibited green fluorescent protein (GFP) under the fluorescent microscope, hence confirming successful transfection into the cell. This new optoporation and transfection technique maximizes the level of selectivity and control over the targeted cell, and this may be a breakthrough method through which to induce controllable genetic changes in the cell.
Highlights
Transfection is the process of deliberately introducing external genes into living cells
3.1 Confirmation of transfection A plasmid-coated microparticle is inserted into the cytoplasm through the punctured hole on the cell membrane, and the gene is transfected into the cytoplasm of the cell
After the plasmid-coated microparticle is inserted into the cell, it is difficult to see the particle by CCD
Summary
Transfection is the process of deliberately introducing external genes into living cells. There are many situations when it is desired to deliver a gene into the cell, such as in the case of gene therapy. This process is becoming increasingly accepted as a possible approach for the treatment of various and specific genetic diseases [1]. Major methods employed for multiple cell transfection are chemical-based transfection [2,3,4,5,6], electroporation [7], sonoporation [8,9,10,11,12], hydrodynamic [13,14,15], magnetofection [16] and gene gun techniques [17]; these techniques cannot be used where specific individual cells present in clusters of other cells need to be transfected
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