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You searched for: EV210161 (EV-TRACK ID)

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Experiment number
  • If needed, multiple experiments were identified in a single publication based on differing sample types, separation protocols and/or vesicle types of interest.
Species
  • Species of origin of the EVs.
Separation protocol
  • Gives a short, non-chronological overview of the different steps of the separation protocol.
    • (d)(U)C = (differential) (ultra)centrifugation
    • DG = density gradient
    • UF = ultrafiltration
    • SEC = size-exclusion chromatography
    • IAF = immuno-affinity capture
Details EV-TRACK ID Experiment nr. Species Sample type separation protocol First author Year EV-METRIC
EV210161 1/1 Homo sapiens Cell culture supernatant (d)(U)C
Filtration
Fu, Yuxuan 2021 44%

Study summary

Full title
All authors
Yuxuan Fu, Sidong Xiong
Journal
J Control Release
Abstract
The worldwide spread of COVID-19 highlights the urgent need for an efficient approach to rapidly dev (show more...)The worldwide spread of COVID-19 highlights the urgent need for an efficient approach to rapidly develop therapeutics and prophylactics against SARS-CoV-2. Extracellular vesicle(EVs) are recognized and endocytosed by tissue cells via specific interactions between surface membrane proteins, where after they deliver their molecular cargo. This provides the potential to modify membrane proteins at EV surfaces as a promising means for specific tissue targeting and drug delivery. In this study, we describe a VSVG viral pseudotyping-based approach to load EV membranes with the receptor-binding domain (RBD) of the viral spike protein, the key domain in SARS-CoV-2 attachment, fusion and cellular entry. The RBD-tagged EVs can specifically recognize ACE2 receptor on the surface of target cells, which is required for the RBD-tagged EVs cellular uptake and targeting. Further, using the hACE2 transgenic mouse model, we show the RBD-tagged EVs accumulate specifically in the target tissues that highly express ACE2. Finally, we demonstrate that the RBD-tagged EVs that encapsulate siRNAs against SARS-CoV-2 pseudovirus can specifically target lung tissues and suppress the pseudovirus infection in vivo. Together, our work presents a safe and effective engineered EV system for in vivo targeted delivery of potential antiviral agents into specific tissues which as a therapeutic potential against SARS-CoV-2 infection. (hide)
EV-METRIC
44% (75th percentile of all experiments on the same sample type)
 Reported
 Not reported
 Not applicable
EV-enriched proteins
Protein analysis: analysis of three or more EV-enriched proteins
non EV-enriched protein
Protein analysis: assessment of a non-EV-enriched protein
qualitative and quantitative analysis
Particle analysis: implementation of both qualitative and quantitative methods
electron microscopy images
Particle analysis: inclusion of a widefield and close-up electron microscopy image
density gradient
Separation method: density gradient, at least as validation of results attributed to EVs
EV density
Separation method: reporting of obtained EV density
ultracentrifugation specifics
Separation method: reporting of g-forces, duration and rotor type of ultracentrifugation steps
antibody specifics
Protein analysis: antibody clone/reference number and dilution
lysate preparation
Protein analysis: lysis buffer composition
Study data
Sample type
Cell culture supernatant
Cell Name
HEK-293T
Sample origin
Control condition
Focus vesicles
extracellular vesicle
Separation protocol
Separation protocol
  • Gives a short, non-chronological overview of the
    different steps of the separation protocol.
    • (d)(U)C = (differential) (ultra)centrifugation
    • DG = density gradient
    • UF = ultrafiltration
    • SEC = size-exclusion chromatography
    • IAF = immuno-affinity capture
(d)(U)C
Filtration
Protein markers
EV: Alix/ CD9
non-EV: GM130/ Calreticulin
Proteomics
no
Show all info
Study aim
New methodological development/Technical analysis comparing/optimizing EV-related methods
Sample
Species
Homo sapiens
Sample Type
Cell culture supernatant
Sample Condition
Control condition
EV-producing cells
HEK-293T
EV-harvesting Medium
EV-depleted medium
Preparation of EDS
Commercial EDS
Separation Method
Differential ultracentrifugation
centrifugation steps
Between 10,000 g and 50,000 g
Between 100,000 g and 150,000 g
Obtain an EV pellet :
Yes
Pelleting: time(min)
70
Pelleting: rotor type
Type 70 Ti
Pelleting: speed (g)
100000
Wash: volume per pellet (ml)
50
Wash: time (min)
70
Wash: Rotor Type
Type 70 Ti
Wash: speed (g)
100000
Filtration steps
0.22µm or 0.2µm
Characterization: Protein analysis
Protein Concentration Method
BCA
Western Blot
Detected EV-associated proteins
CD9/ Alix
Not detected contaminants
Calreticulin/ GM130
Flow cytometry
Hardware adjustments
Characterization: Particle analysis
NTA
Report type
Size range/distribution
Reported size (nm)
128,1
EV concentration
Yes
Particle yield
Yes, as number of particles per milliliter of starting sample 360000000
1 - 1 of 1
  • CM = Commercial method
  • dUC = differential ultracentrifugation
  • DG = density gradient
  • UF = ultrafiltration
  • SEC = size-exclusion chromatography
EV-TRACK ID
EV210161
species
Homo sapiens
sample type
Cell culture
cell type
HEK-293T
condition
Control condition
separation protocol
(d)(U)C
Filtration
Exp. nr.
1
EV-METRIC %
44