Institute of Biochemistry and Physiology of Plants and Microorganisms, Russian Academy of Sciences, Saratov, Russia.
Saratov National Research State University, Saratov, Russia.
J Biophotonics. 2019 Jan;12(1):e201800166. doi: 10.1002/jbio.201800166. Epub 2018 Oct 5.
The recently developed laser-induced cell transfection mediated by Au nanoparticles is a promising alternative to the well-established lipid-based transfection or to electroporation. Optoporation is based on the laser plasmonic heating of nanoparticles located near the cell membrane. However, the uncontrollable cell damage from intense laser pulses and from random attachment of nanoparticles may be crucial for transfection. We present a novel plasmonic optoporation technique that uses Au nanostar layers immobilized in culture microplate wells. HeLa cells were grown directly on Au nanostar layers, after which they were subjected to continuous-wave 808 nm laser irradiation. An Au monolayer density ~15 μg/cm and an absorbed energy of about 15 to 30 J were found to be optimal for optoporation. Propidium iodide molecules were used as model penetrating agent. The transfection efficiency evaluated using fluorescence microscopy for HeLa cells transfected with pGFP under optimized optoporation conditions (95% ± 5%) was similar to the efficiency of TurboFect. The technique's efficiency (295 ± 10 relative light units, RLU), demonstrated by transfecting HeLa cells with the pCMV-GLuc 2 control plasmid, was greater than that obtained by transfection of HeLa cells with the TurboFect agent (220 ± 10 RLU). The cell viability in plasmonic optoporation (92% ± 7%), too, was greater than that in transfection with TurboFect (75% ± 7%).
最近开发的金纳米颗粒介导的激光诱导细胞转染技术是一种有前途的替代方法,可替代成熟的基于脂质的转染或电穿孔。光穿孔基于位于细胞膜附近的纳米颗粒的激光等离子体加热。然而,高强度激光脉冲和纳米颗粒随机附着所导致的不可控的细胞损伤可能对转染至关重要。我们提出了一种使用固定在培养微孔板井中的 Au 纳米星层的新型等离子体光穿孔技术。HeLa 细胞直接在 Au 纳米星层上生长,然后用连续波 808nm 激光照射。发现 Au 单层密度约为 15μg/cm,吸收能量约为 15 至 30J,这是光穿孔的最佳条件。碘化丙啶分子被用作模型穿透剂。使用荧光显微镜评估了在优化的光穿孔条件下转染 pGFP 的 HeLa 细胞(95%±5%)的转染效率与 TurboFect 相似。通过用 pCMV-GLuc 2 对照质粒转染 HeLa 细胞来证明该技术的效率(295±10 相对光单位,RLU)大于用 TurboFect 试剂转染 HeLa 细胞时的效率(220±10RLU)。等离子体光穿孔中的细胞活力(92%±7%)也大于 TurboFect 转染时的细胞活力(75%±7%)。
