Transfection of cells using flow-through electroporation based on constant voltage

Geng, Tao; Zhan, Yihong; Wang, Jun; Lu, Chao

doi:10.1038/nprot.2011.360

Cited by 73 publications

(93 citation statements)

References 43 publications

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“…For the successful genetic manipulation of stem cells, the cells must typically maintain their viability for an extended period of time after single or multiple siRNA transfections, without affecting the intrinsic cellular functions. However, many of the conventional methods used to deliver siRNA into stem cells, including lipid-based transfections, cationic polyplexes, viral vectors and electroporation techniques, result in significant cytotoxicity and undesirable side-effects9101112. This presents a considerable challenge for achieving robust and reliable siRNA delivery into stem cells to control their differentiation into the desired cell lineages.…”

mentioning

confidence: 99%

Nanotopography-mediated Reverse Uptake for siRNA Delivery into Neural Stem Cells to Enhance Neuronal Differentiation

Solanki

Shah

Yin

et al. 2013

Sci Rep

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RNA interference (RNAi) for controlling gene expression levels using siRNA or miRNA is emerging as an important tool in stem cell biology. However, the conventional methods used to deliver siRNA into stem cells result in significant cytotoxicity and undesirable side-effects. To this end, we have developed a nanotopography-mediated reverse uptake (NanoRU) delivery platform to demonstrate a simple and efficient technique for delivering siRNA into neural stem cells (NSCs). NanoRU consists of a self-assembled silica nanoparticle monolayer coated with extracellular matrix proteins and the desired siRNA. We use this technique to efficiently deliver siRNA against the transcription factor SOX9, which acts as a switch between neuronal and glial fate of NSCs. The knockdown of SOX9 enhanced the neuronal differentiation and decreased the glial differentiation of the NSCs. Our NanoRU platform demonstrates a novel application and the importance of nanotopography-mediated siRNA delivery into stem cells as an effective method for genetic manipulation.

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mentioning

confidence: 99%

Nanotopography-mediated Reverse Uptake for siRNA Delivery into Neural Stem Cells to Enhance Neuronal Differentiation

Solanki

Shah

Yin

et al. 2013

Sci Rep

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“…A microfluidic channel (with dimensions of 2.4 mm (W) × 0.2 mm (D) × 10 mm (L)) was fabricated using standard soft lithography4344. Briefly, a photomask with microscale pattern designed by FreeHand MX (Macromedia) was printed on transparencies (Infinity Graphics) at a resolution of 5,080 dpi.…”

Section: Methodsmentioning

confidence: 99%

Immunomagnetic separation of tumor initiating cells by screening two surface markers

Sun¹,

Hsieh

Ma³

et al. 2017

Sci Rep

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Isolating tumor initiating cells (TICs) often requires screening of multiple surface markers, sometimes with opposite preferences. This creates a challenge for using bead-based immunomagnetic separation (IMS) that typically enriches cells based on one abundant marker. Here, we propose a new strategy that allows isolation of CD44+/CD24− TICs by IMS involving both magnetic beads coated by anti-CD44 antibody and nonmagnetic beads coated by anti-CD24 antibody (referred to as two-bead IMS). Cells enriched with our approach showed significant enhancement in TIC marker expression (examined by flow cytometry) and improved tumorsphere formation efficiency. Our method will extend the application of IMS to cell subsets characterized by multiple markers.

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“…In our work, we generated electropermeabilization and DNA delivery using lowfrequency sine-wave or square-wave ac field of 10-10k Hz by modulating a constant AC field across a microfluidic channel. Similar to flow-through electroporation based on DC voltage [22,23,29], the AC field intensity in the narrow section was sufficiently high to generate electroporation while the low field in the wide sections did not disrupt the cell membrane.…”

Section: Ac-based Gene Deliverymentioning

confidence: 97%

Gene delivery by microfluidic flow-through electroporation based on constant DC and AC field

Geng

Zhan

2012

2012 Annual International Conference of the IEEE Engineering in Medicine and Biology Society

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Electroporation is one of the most widely used physical methods to deliver exogenous nucleic acids into cells with high efficiency and low toxicity. Conventional electroporation systems typically require expensive pulse generators to provide short electrical pulses at high voltage. In this work, we demonstrate a flow-through electroporation method for continuous transfection of cells based on disposable chips, a syringe pump, and a low-cost power supply that provides a constant voltage. We successfully transfect cells using either DC or AC voltage with high flow rates (ranging from 40 µl/min to 20 ml/min) and high efficiency (up to 75%). We also enable the entire cell membrane to be uniformly permeabilized and dramatically improve gene delivery by inducing complex migrations of cells during the flow.

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Transfection of cells using flow-through electroporation based on constant voltage

Cited by 73 publications

References 43 publications

Nanotopography-mediated Reverse Uptake for siRNA Delivery into Neural Stem Cells to Enhance Neuronal Differentiation

Nanotopography-mediated Reverse Uptake for siRNA Delivery into Neural Stem Cells to Enhance Neuronal Differentiation

Immunomagnetic separation of tumor initiating cells by screening two surface markers

Gene delivery by microfluidic flow-through electroporation based on constant DC and AC field

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