Low level electricity increases the secretion of extracellular vesicles from cultured cells

Fukuta, Tatsuya; Nishikawa, Akina; Kogure, Kentaro

doi:10.1016/j.bbrep.2019.100713

Cited by 42 publications

(48 citation statements)

References 42 publications

(58 reference statements)

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“…They demonstrated that ET did not impair viability of donor cells, and importantly, did not affect the quality and functionality of the collected EVs from each kind of donor cell tested. [87] These results are promising although further studies are needed to evaluate ET on other cell types. Moreover, the development of a well-defined methodology to apply ET to a higher number of cells will contribute to the general improvement of this novel technology for EV production.…”

Section: Improving the Ev-producer Cellsmentioning

confidence: 91%

“…Indeed, given their higher flexibility in production and easier functionalization, polymersomes can be envisaged as an advantageous and cheaper alternative to liposomes. Extracellular vesicles + Difficult massive production and purification; biomolecules as only building blocks; limited tunability of the physicochemical properties [ 87,240] +++ Generally safe; extraction from biological sources with high biocompatibility [80,83] ++ Excellent loading of biomolecules; challenging loading of synthetic molecules; good delivery efficiency;rapid clearance [ 186,187] Liposomes ++ Easy production and purification; pre-and postsynthetic functionalization; tunable physicochemical properties [ 124,161] +++ Generally safe, unless modified with charged phospholipids; similar composition to EVs, but without cell-mediated modifications [103,213] ++ Good natural and synthetic molecules loading; preassembly and postassembly loading; good delivery efficiency; tunable clearance properties [ 198,199] Polymersomes +++ Customizable massive production; pre-and postsynthetic functionalization; tunable physicochemical properties [ 136,155] + Possible accumulations in the body; possibility to introduce biodegradable polymers [229,230] + Preassembly and postassembly loading; cell uptake dependent on the vesicle and cell membrane characteristic; tunable clearance properties [ 222,224]…”

Section: Productionmentioning

confidence: 99%

See 1 more Smart Citation

Mastering the Tools: Natural versus Artificial Vesicles in Nanomedicine

Leggio

Arrabito

Ferrara

et al. 2020

Adv Healthcare Materials

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Naturally occurring extracellular vesicles and artificially made vesicles represent important tools in nanomedicine for the efficient delivery of biomolecules and drugs. Since its first appearance in the literature 50 years ago, the research on vesicles is progressing at a fast pace, with the main goal of developing carriers able to protect cargoes from degradation, as well as to deliver them in a time‐ and space‐controlled fashion. While natural occurring vesicles have the advantage of being fully compatible with their host, artificial vesicles can be easily synthetized and functionalized according to the target to reach. Research is striving to merge the advantages of natural and artificial vesicles, in order to provide a new generation of highly performing vesicles, which would improve the therapeutic index of transported molecules. This progress report summarizes current manufacturing techniques used to produce both natural and artificial vesicles, exploring the promises and pitfalls of the different production processes. Finally, pros and cons of natural versus artificial vesicles are discussed and compared, with special regard toward the current applications of both kinds of vesicles in the healthcare field.

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Section: Improving the Ev-producer Cellsmentioning

confidence: 91%

Section: Productionmentioning

confidence: 99%

Mastering the Tools: Natural versus Artificial Vesicles in Nanomedicine

Leggio

Arrabito

Ferrara

et al. 2020

Adv Healthcare Materials

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show abstract

“…The quality of EVs exhibited no significant changes compared with the EVs secreted without electrical stimulation. In conclusion, electrical stimulation does not change the properties and/or function of EVs themselves, but accelerates the process of intracellular production and processing [63]. As shown in Figure 2, other methods that can promote EV production will be summarized in the latter part of this review.…”

Section: Indirect Drug Loadingmentioning

confidence: 97%

“…Given that the quantity of EVs secreted by natural cells falls far short of production requirements, researchers have tried to explore various ways to boost secretion amount without reducing quality. Fukuta et al found that stimulating cells with a low-level electric treatment (with a voltage of 0.34 mA/cm 2 ) for about 60 min can accelerate cell signal transduction and cell throughput, and promote the release of EVs [63]. The quality of EVs exhibited no significant changes compared with the EVs secreted without electrical stimulation.…”

Section: Indirect Drug Loadingmentioning

confidence: 99%

Extracellular Vesicles as Drug Vectors for Precise Cancer Treatment

Cao

Liang

et al. 2021

Nanomedicine (Lond.)

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Extracellular vesicles (EVs) are nano-sized vesicle structures secreted from a variety of cells, which carry numerous biological macromolecules, participate in cell signal transduction and avoid immune system clearance. EVs have a plethora of specific signal recognition factors, and many studies have shown that they can play an important role in the precise treatment of tumors. This review aims to compile the applications of EVs as nanocarriers for antitumor drugs, gene drugs and other nanomaterials with anticancer capability. Additionally, we systematically summarize the preparation methodology and expound upon how to improve the drug loading and cancer-targeting capacity of EVs. We highlight that EV-based drug delivery has the potential to become the future of precise cancer treatment.

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“…Importantly, modification of cell culture parameters has previously been shown to significantly reshape EV intraluminal cargo composition, [ 213–238 ] augment EV production (e.g., number of EVs produced per cell), [ 213,216,219,220,229,232,237,239–247 ] and increase EV potency in a diverse array of applications including neurological disorders and injuries, wound healing, cartilage repair, kidney disease, ischemia/reperfusion (I/R) injury, myocardial infarction, and sepsis. [ 53,146,215,220,222,224,229,230,232,240,241,243,247–252 ] These changes can be produced through the adjustment of numerous upstream variables including cell seeding density, [ 240 ] media composition (i.e., serum‐free media), [ 213,228,231 ] collection frequency of EVs, [ 240 ] architecture of the culture vessel (i.e., 2D vs 3D; 2D vs 3D), [ 220,222,227,229,230,239,242,243,247,248,250,253,254 ] fluid shear stress (i.e., static vs dynamic flow), [ 250,255 ] mechanical stimulation (e.g., cyclic stretch), [ 256–258 ] exposure to hypoxia, [ 143,217,219,224,228,231,232,241,245,246,251,259–265 ] heat, [ 266 ] oxidative stress, [ 225,266 ] electrical stimulation, [ …”

Section: Lessons Learned and Future Opportunitiesmentioning

confidence: 99%

Therapeutic Potential of Extracellular Vesicles for Sepsis Treatment

Kronstadt

Pottash

Levy

et al. 2021

Advanced Therapeutics

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Sepsis is a deadly condition lacking a specific treatment despite decades of research. This has prompted the exploration of new approaches, with extracellular vesicles (EVs) emerging as a focal area. EVs are nanosized, cell-derived particles that transport bioactive components (i.e., proteins, DNA, and RNA) between cells, enabling both normal physiological functions and disease progression depending on context. In particular, EVs have been identified as critical mediators of sepsis pathophysiology. However, EVs are also thought to constitute the biologically active component of cell-based therapies and have demonstrated anti-inflammatory, anti-apoptotic, and immunomodulatory effects in sepsis models. The dual nature of EVs in sepsis is explored here, discussing their endogenous roles and highlighting their therapeutic properties and potential. Related to the latter component, prior studies involving EVs from mesenchymal stem/stromal cells (MSCs) and other sources are discussed and emerging producer cells that could play important roles in future EV-based sepsis therapies are identified. Further, how methodologies could impact therapeutic development toward sepsis treatment to enhance and control EV potency is described.

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Low level electricity increases the secretion of extracellular vesicles from cultured cells

Cited by 42 publications

References 42 publications

Mastering the Tools: Natural versus Artificial Vesicles in Nanomedicine

Mastering the Tools: Natural versus Artificial Vesicles in Nanomedicine

Extracellular Vesicles as Drug Vectors for Precise Cancer Treatment

Therapeutic Potential of Extracellular Vesicles for Sepsis Treatment

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