Massively-Parallelized, Deterministic Mechanoporation for Intracellular Delivery

Dixit, Harish G; Starr, Renate; Dundon, Morgan L.; Pairs, Pranee I; Yang, Xin; Zhang, Yanyan; Nampe, Daniel; Ballas, Christopher B.; Tsutsui, Hideaki; Forman, Stephen J.; Brown, Christine E.; Rao, Masaru P.

doi:10.1021/acs.nanolett.9b03175

Cited by 46 publications

(57 citation statements)

References 46 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…VNS‐based platforms can be built in microfluidic devices to achieve massively parallelized, deterministic mechanoporation (DMP) for intracellular delivery into suspension cells. [ 149 ] SiNWs (or penetrators) were specially designed and fabricated in confined wells (Figure 8d,e), where only a single cell can be captured and porated by impingement upon the penetrator under a negative aspiration flow (Figure 8f); cells were released by reversal of flow after which intracellular delivery occurs via diffusive influx of exogenous cargos (pGFP) through the single transient plasma membrane pore. Moreover, high cell viability and transfection efficiency were detected (both >87%) for DMP‐transfected Jurkat cells; mean pGFP transfection yield by the DMP device (88%) was over four times that by conventional BEP methods (20%) (Figure 8g).…”

Section: Vns‐mediated Intracellular Delivery Into Immune Cellsmentioning

confidence: 99%

Emerging Roles of 1D Vertical Nanostructures in Orchestrating Immune Cell Functions

Chen

et al. 2020

Advanced Materials

View full text Add to dashboard Cite

nanotopographies optimized to facilitate biomolecular delivery, genome editing, and cellular modulation-have enormous potential to build capacity over a range of collaborating disciplines associated with biomedical research. High-aspect-ratio nanostructures are now providing major advantages in precise manipulation of increasingly complex cellular processes, assisting the translation into clinical applications such as tissue engineering, regenerative medicine, drug delivery, biosensing, and cancer immunotherapies. [2-5] In particular, 1D vertical nanostructures (1D-VNS)-nanowires, nanoneedles, nanopillars, nanotubes, nanosyringes, nanostraws, nanocones, and nanospikes (Figure 1a)-have helped tackle various biological problems such as intracellular recording and genetic interrogation. [6-16] Unlike other highaspect-ratio nanostructures, such as freestanding carbon nanotubes, 1D-VNS can be rationally designed and synthesized, via top-down and/or bottom-up approaches, with defined key parameters-including topological geometry (pitch, diameter, length), chemical composition, doping, and electronic propert ies. [17-21] So by well-controlled programming coupled with selective surface functionality, 1D-VNS can provide unprecedented spatial and mechanical resolution to enable direct, Engineered nano-bio cellular interfaces driven by 1D vertical nanostructures (1D-VNS) are set to prompt radical progress in modulating cellular processes at the nanoscale. Here, tuneable cell-VNS interfacial interactions are probed and assessed, highlighting the use of 1D-VNS in immunomodulation, and intracellular delivery into immune cells-both crucial in fundamental and translational biomedical research. With programmable topography and adaptable surface functionalization, 1D-VNS provide unique biophysical and biochemical cues to orchestrate innate and adaptive immunity, both ex vivo and in vivo. The intimate nanoscale cell-VNS interface leads to membrane penetration and cellular deformation, facilitating efficient intracellular delivery of diverse bioactive cargoes into hard-to-transfect immune cells. The unsettled interfacial mechanisms reported to be involved in VNS-mediated intracellular delivery are discussed. By identifying up-to-date progress and fundamental challenges of current 1D-VNS technology in immune-cell manipulation, it is hoped that this report gives timely insights for further advances in developing 1D-VNS as a safe, universal, and highly scalable platform for cell engineering and enrichment in advanced cancer immunotherapy such as chimeric antigen receptor-T therapy.

show abstract

Section: Vns‐mediated Intracellular Delivery Into Immune Cellsmentioning

confidence: 99%

Emerging Roles of 1D Vertical Nanostructures in Orchestrating Immune Cell Functions

Chen

et al. 2020

Advanced Materials

View full text Add to dashboard Cite

show abstract

“…Reproduced with permission. [ 150 ] Copyright 2019, American Chemical Society. f) Schematic illustration of the design and operating principles of the hydroporator device that permeabilizes cells by fluid shear forces at a cross‐sectional junction with opposing flows.…”

Section: Micro‐ and Nanostructure‐induced Cell Membrane Disruptionmentioning

confidence: 99%

“…Following a similar concept, cell membrane disruption was also achieved by Dixit et al on a microfluidic platform that first aspirates cells onto a sharp tip, after which the flow direction is reversed to release the punctured cell (Figure 13e). [ 150 ] Although they did not apply this platform for intracellular label delivery, successful plasmid DNA delivery indicated that it could be used for that purpose as well, even with large‐sized labels. In another approach, cells were permeabilized by the fluid streams themselves, such as the hydroporator that was developed by Kizer et al (Figures 11c and 12f).…”

Section: Micro‐ and Nanostructure‐induced Cell Membrane Disruptionmentioning

confidence: 99%

Intracellular Labeling with Extrinsic Probes: Delivery Strategies and Applications

Liu

Fraire

Smedt

et al. 2020

Small

View full text Add to dashboard Cite

Extrinsic probes have outstanding properties for intracellular labeling to visualize dynamic processes in and of living cells, both in vitro and in vivo. Since extrinsic probes are in many cases cell‐impermeable, different biochemical, and physical approaches have been used to break the cell membrane barrier for direct delivery into the cytoplasm. In this Review, these intracellular delivery strategies are discussed, briefly explaining the mechanisms and how they are used for live‐cell labeling applications. Methods that are discussed include three biochemical agents that are used for this purpose—purpose‐different nanocarriers, cell penetrating peptides and the pore‐foraming bacterial toxin streptolysin O. Most successful intracellular label delivery methods are, however, based on physical principles to permeabilize the membrane and include electroporation, laser‐induced photoporation, micro‐ and nanoinjection, nanoneedles or nanostraws, microfluidics, and nanomachines. The strengths and weaknesses of each strategy are discussed with a systematic comparison provided. Finally, the extrinsic probes that are reported for intracellular labeling so‐far are summarized, together with the delivery strategies that are used and their performance. This combined information should provide for a useful guide for choosing the most suitable delivery method for the desired probes.

show abstract

“…To address the challenges facing viral and conventional non-viral techniques, microfluidics and nanotechnology have appeared as powerful tools that have shown tremendous potential for adoption in clinical settings and research labs ( 11 ). Notable examples include methods based on cell deformation ( 12, 13 ), nanostructures for localized electroporation ( 10, 14–16 ), mechanoporation ( 17, 18 ), acoustofluidics sonoporation ( 19 ), flow-through electroporation ( 20 ), droplet microfluidics ( 21 ), and inertial microfluidics ( 18, 22 ). For safe, efficient, and controllable intracellular delivery, these methods focus on precise control of cellular permeabilization and uptake, down to the single-cell level.…”

Section: Introductionmentioning

confidence: 99%

High-throughput and dosage-controlled intracellular delivery of large cargos by an acoustic-electric micro-vortices platform

Aghaamoo

Chen

et al. 2021

Preprint

View full text Add to dashboard Cite

Intracellular delivery of cargos for cell engineering plays a pivotal role in transforming medicine and biomedical discoveries. Recent advances in microfluidics and nanotechnology have opened up new avenues for efficient, safe, and controllable intracellular delivery, as they improve precision down to the single-cell level. Based on this capability, several promising micro- and nanotechnology approaches outperform viral and conventional non-viral techniques in offering dosage-controlled delivery and/or intracellular delivery of large cargos. However, to achieve this level of precision and effectiveness, they are either low in throughput, limited to specific cell types (e.g., adherent vs. suspension cells), or complicated to operate with. To address these challenges, here we introduce a versatile and simple-to-use intracellular delivery microfluidic platform, termed Acoustic-Electric Shear Orbiting Poration (AESOP). Hundreds of acoustic microstreaming vortices form the production line of the AESOP platform, wherein hundreds of thousands of cells are trapped, permeabilized, and mixed with exogenous cargos. Using AESOP, we show intracellular delivery of a wide range of molecules (from <1 kDa to 2 MDa) with high efficiency, cell viability, and dosage-controlled capability into both suspension and adherent cells and demonstrate throughput at 1 million cells/min per single chip. In addition, we demonstrate AESOP for two gene editing applications that require delivery of large plasmids: i) eGFP plasmid (6.1 kbp) transfection, and ii) CRISPR-Cas9-mediated gene knockout using a 9.3 kbp plasmid DNA encoding Cas9 protein and sgRNA. Compared to alternative platforms, AESOP not only offers dosage-controlled intracellular delivery of large plasmids (>6kbp) with viabilities over 80% and comparable delivery efficiencies, but also is an order of magnitude higher in throughput, compatible with both adherent and suspension cell lines, and simple to operate.

show abstract

Massively-Parallelized, Deterministic Mechanoporation for Intracellular Delivery

Cited by 46 publications

References 46 publications

Emerging Roles of 1D Vertical Nanostructures in Orchestrating Immune Cell Functions

Emerging Roles of 1D Vertical Nanostructures in Orchestrating Immune Cell Functions

Intracellular Labeling with Extrinsic Probes: Delivery Strategies and Applications

High-throughput and dosage-controlled intracellular delivery of large cargos by an acoustic-electric micro-vortices platform

Contact Info

Product

Resources

About