High-Throughput and Efficient Intracellular Delivery Method via a Vibration-Assisted Nanoneedle/Microfluidic Composite System.
Xuan LiYuan MaYu XueXuanhe ZhangLinwen LvQianghua QuanYiqing ChenGuoxu YuZhenwei LiangXinping ZhangDing WengLei ChenKui ChenXin HanJiadao WangPublished in: ACS nano (2022)
Intracellular delivery and genetic modification have brought a significant revolutionary to tumor immunotherapy, yet existing methods are still limited by low delivery efficiency, poor throughput, excessive cell damage, or unsuitability for suspension immune cells, specifically the natural killer cell, which is highly resistant to transfection. Here, we proposed a vibration-assisted nanoneedle/microfluidic composite system that uses large-area nanoneedles to rapidly puncture and detach the fast-moving suspension cells in the microchannel under vibration to achieve continuous high-throughput intracellular delivery. The nanoneedle arrays fabricated based on the large-area self-assembly technique and microchannels can maximize the delivery efficiency. Cas9 ribonucleoprotein complexes (Cas9/RNPs) can be delivered directly into cells due to the sufficient cellular membrane nanoperforation size; for difficult-to-transfect immune cells, the delivery efficiency can be up to 98%, while the cell viability remains at about 80%. Moreover, the throughput is demonstrated to maintain a mL/min level, which is significantly higher than that of conventional delivery techniques. Further, we prepared CD96 knockout NK-92 cells via this platform, and the gene-edited NK-92 cells possessed higher immunity by reversing exhaustion. The high-throughput, high-efficiency, and low-damage performance of our intracellular delivery strategy has great potential for cellular immunotherapy in clinical applications.
Keyphrases
- high throughput
- single cell
- nk cells
- crispr cas
- induced apoptosis
- high frequency
- high efficiency
- reactive oxygen species
- stem cells
- physical activity
- genome editing
- signaling pathway
- circulating tumor cells
- cell death
- endoplasmic reticulum stress
- body mass index
- climate change
- cell cycle arrest
- mesenchymal stem cells
- cell proliferation