Temporal Sampling of Enzymes from Live Cells by Localized Electroporation and Quantification of Activity by SAMDI Mass Spectrometry

Mukherjee, Prithvijit; Berns, Eric J.; Patino, Cesar A.; Moully, Elamar Hakim; Chang, Lingqian; Nathamgari, S. Shiva P.; Kessler, John A.; Mrksich, Milan; Espinosa, Horacio D.

doi:10.1002/smll.202000584

Cited by 21 publications

(38 citation statements)

References 47 publications

(62 reference statements)

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“…Porous substrate electroporation is a particularly promising and under investigated engineered substrate method which we reviewed in detail. [155] -2000 µg mL −1 [154] DMEM, [154] PBS [155] [ 154,155] PI 0.668 0.6 nm r h + 2 [153] -20 [152] µg mL −1 , 100 µM [167] PBS [153] , high glucose DMEM [167] [ 152,153,159,160,163,165,167] Oligonucleotide Hypo-osmolar buffer, [152] Iso-osmolar buffer, [152] PBS [158] [ Plasmid DNA CS1-CAR 9 kb - [165] GFP ≈2000 3.3 kb -0.2 [151] -1000 [153] µg mL −1 DMEM [153] [ 151,153,159] gWiz GFP ≈3500 5.8 kb -<50 µg mL −1 [156] gWiz SEAP ≈4000 6.6 kb -5 [167] -100 [157] µg mL −1 High glucose DMEM [157,167] [ 156,157,167] mCherry ≈2400 4 kb -20 µg mL −1 [152] NF2 CRISPR/ Cas9 KO >5500 >9 kb - [168] OSKM pCAG ≈7900 13 kb - [160] pDsRed-C1 ≈2900 4.7 kb -100 µg mL −1 [154] pmaxGFP ≈2100 3.5 kb -5 µg mL −1 [167] High Glucose DMEM [167] [ 160,<...>…”

Section: Discussionmentioning

confidence: 99%

“…The last category of high throughput, high control systems, porous substrate systems ( Figure 2H) are substrates containing numerous micro-and nanopores on which cells are seeded and electroporated. Porous substrates can consist of commercially available membranes with random pore distribution, [151][152][153][154][155][156][157][158][159] or uniform arrays of pores on silicon chips. [160][161][162][163][164][165][166][167][168][169][170] Like nanostructures, cells seal around the pores which limits the electric field exposure to discrete regions of each cell.…”

Section: Engineered Substrate Methodsmentioning

confidence: 99%

“…Pulse frequencies have been reported from 1-200 Hz. The number of pulses applied per train range from 1-2400 pulses, while the number of trains is generally one and HeLa cervical epithelial Poly-L-Lysine [151] or Fibronectin [151,154] >95% [151] >80% [151] [ 151,153,154,159] HL-60 Promyeloblast, suspended >90% 65% a) [155] HT1080 Connective tissue Fibronectin [152] 50% [153] [ 152,153,159] Jurkat T lymphocyte, suspended Poly-L-Lysine or Fibronectin, [151] PEG-Silane [163] >95% [151] 75% [151] [ 151,163] KG1a Promyeloblast, suspended PEG-Silane 96% [163] K562 Lymphoblast, suspended PEG-Silane [163] 92% [163] 83.4% [163] [ 163,164] MDA-MB231 Mammary epithelial Fibronectin >99% [152] 70% [152] [ 152,158] NK-92 Natural killer, suspended 90% 74% [165] Mouse NIH3T3 Embryonic fibroblast Poly-l-lysine or fibronectin [151] >95% [151] 75% [151] […”

Section: Electroporation Waveformsmentioning

confidence: 99%

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High Throughput and Highly Controllable Methods for In Vitro Intracellular Delivery

Brooks

Minnick

Mukherjee

et al. 2020

Small

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Section: Discussionmentioning

confidence: 99%

Section: Engineered Substrate Methodsmentioning

confidence: 99%

Section: Electroporation Waveformsmentioning

confidence: 99%

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High Throughput and Highly Controllable Methods for In Vitro Intracellular Delivery

Brooks

Minnick

Mukherjee

et al. 2020

Small

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“…Instead of having nanotubes piercing into the cells, devices called the live cell analysis device (LCAD) used nanochannels (radius ~250 nm) formed by a nanoporous polycarbonate membrane, on which cells were cultured. 302,303 Similar to nanostraws, LCAD operated on the principle of membrane permeabilization using electroporation followed by an outflow of cytosol primarily by diffusion. The LCAD was sandwiched between two indium tin oxide electrodes.…”

Section: Nanoporous Membranementioning

confidence: 99%

Microfluidic Surgery in Single Cells and Multicellular Systems

Zhang¹,

Nadkarni²,

Paul³

et al. 2021

Preprint

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Microscale surgery on single cells and small organisms have enabled major advances in fundamental biology and in engineering biological systems. Examples of applications range from wound healing and regeneration studies to the generation of hybridoma to produce monoclonal antibodies. Even today, these surgical operations are often performed manually, but they are labor-intensive and lack reproducibility. Microfluidics has emerged as a powerful technology to control and manipulate cells and multicellular systems at the micro- and nanoscale with high precision. Here, we review the physical and chemical mechanisms of microscale surgery, and the corresponding design principles, applications, and implementations in microfluidic systems. We consider four types of surgical operations: 1) Sectioning, which splits a biological entity into multiple parts, 2) ablation, which destroys part of an entity, 3) biopsy, which extracts materials from within a living cell, and 4) fusion, which joins multiple entities into one. For each type of surgery, we summarize the motivating applications and the microfluidic devices developed. Throughout the review, we highlight existing challenges and opportunities. We hope that this review will inspire scientists and engineers to continue to explore and improve microfluidic surgical methods.

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“…[ 6 ] In the field of bioengineering, to deliver DNAs or drugs into the cells, electroporation is an effective way to open holes on the cell membrane, basically made up of phospholipid. [ 7 ] The cell membrane can be self‐healing to seal the holes owning to the good fluidity of the phospholipid membrane. [ 8 ] Inspired by flowing cell membrane, liquid gate with electrical control is emerging to the surface.…”

Section: Introductionmentioning

confidence: 99%

Electrochemically and Mechanically Regulated Liquid Metal Gate via Giant Surface Tension Alteration

Wang

Guo

Fang

et al. 2021

Adv Materials Inter

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Liquid gates can provide an effective method to control the release of substances. However, the size of liquid gates and the control methods limit their broad applications. The controllable large deformation of liquid metals (LMs) makes it possible to be used in liquid gate design with simple actuation methods. Here an LM gate that can be easily driven under moderate conditions is proposed, on demand opening at mild electrical voltage (2–5 V) and closing at an oscillating mechanical force (≈0.05 N) in a wide range of pH (2–12). The gating mechanism relies on the large surface tension alteration at these conditions, which directly changes the shape of the LM from a flat film to a contracted meniscus to one side of the copper gate‐frame. As demonstrated, this gate can be applied to release substances such as liquid (ink), biomolecule (insulin) by free diffusion. Moreover, single‐channel and multichannel gates can be realized for high throughput control. The biocompatibility of the whole gate is also proved by cytotoxicity assays. Above all, a novel LM gate is offered with simple structure and easy control, which may bring inspiration to applications in controlled substance release and separation.

show abstract

Temporal Sampling of Enzymes from Live Cells by Localized Electroporation and Quantification of Activity by SAMDI Mass Spectrometry

Cited by 21 publications

References 47 publications

High Throughput and Highly Controllable Methods for In Vitro Intracellular Delivery

High Throughput and Highly Controllable Methods for In Vitro Intracellular Delivery

Microfluidic Surgery in Single Cells and Multicellular Systems

Electrochemically and Mechanically Regulated Liquid Metal Gate via Giant Surface Tension Alteration

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