Extracellular Vesicles as Promising Carriers in Drug Delivery: Considerations from a Cell Biologist’s Perspective
Abstract
:Simple Summary
Abstract
1. Introduction
2. Therapeutic Potential of Stem Cell Derived-EVs
3. Can EVs Act as Drug Delivery Carriers?
3.1. First Aspect: EV Isolation and Purification
3.2. Second Aspect: EV Production Scale-up and Storage
3.3. Third Aspect: EV Cargo Loading
3.4. Fourth Aspect: EV Targeting
3.5. Fifth Aspect: EV Cargo Delivery
4. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Author | Year | Cell Origin | Keywords | Ref. |
---|---|---|---|---|
Martin-Rufino JD. | 2019 | Mesenchymal Stem Cell | Immunomodulation | 26 |
Balbi C. | 2017 | Human Amniotic Fluid Stem Cell | Cell proliferation | 20 |
Bian X. | 2019 | Mesenchymal Stem Cell | Angiogenesis | 27 |
Barile L. | 2014 | Cardiac progenitor cell | Cardiac regeneration | 28 |
Balbi C. | 2019 | Human Amniotic Fluid Stem Cell | Cardiac regeneration | 29 |
He J. | 2012 | Bone marrow stem cells | Renal injury | 30 |
Lo Sicco C. | 2017 | Mesenchymal Stem Cell | Inflammation | 17 |
Zhang B. | 2014 | Mesenchymal Stem Cell | Skin burn | 31 |
Fang S. | 2016 | Umbilical Cord-Derived Mesenchymal Stem Cell | Skin defect | 32 |
Du W. | 2017 | Mesenchymal Stem Cell | Ischemia | 33 |
Song Y. | 2017 | Mesenchymal Stem Cell | Sepsis | 34 |
Zhu J. | 2018 | Mesenchymal Stem Cell | Myocardial infarction | 35 |
Ma J. | 2017 | Human Umbilical Cord Mesenchymal Stem Cells | Myocardial infarction | 36 |
Feng Y. | 2014 | Mesenchymal Stem Cell | Myocardial infarction | 37 |
Ibrahim AG-E | 2014 | Cardiosphere derived cells | Cardiac regeneration | 38 |
Barile L. | 2018 | Cardiac progenitor cell | Cardioprotection | 44 |
Author | Year | Keywords | Ref | |
---|---|---|---|---|
1. Isolation and purification | De Jong O.G. | 2019 | EVs for Drug Delivery | 62 |
Antimisiaris S.G. | 2018 | EVs for Drug Delivery | 54 | |
Li P. | 2017 | EXO Isolation | 60 | |
Cocozza F. | 2020 | EVs Isolation | 63 | |
Witwer K.W. | 2017 | MISEV | 64 | |
Karimi N. | 2018 | EVs Purification | 65 | |
Liangsupree T. | 2021 | Isolation and Separation | 66 | |
Surman M. | 2019 | EVs for Drug Delivery | 67 | |
2. Scale-up and storage | Whitford W. | 2019 | EXO Manufacturing | 68 |
Panchalingam K.M. | 2015 | Scale-up | 69 | |
Andriolo G. | 2018 | GMP method | 21 | |
Chen Y.S. | 2020 | GMP EXO | 70 | |
Witwer K.W. | 2013 | Metodologic standardisation | 71 | |
Lorincz A.M. | 2014 | Storage | 72 | |
Börger V. | 2017 | Storage | 73 | |
Bosch S. | 2016 | Storage | 74 | |
Kaushik J.K. | 2003 | Storage | 75 | |
Crowe J.H. | 1988 | Storage | 76 | |
3. Cargo Loading | Van Eijndhoven M.A.J. | 202 | RNA drugs | 77 |
Margolis L. | 2019 | EVs as API carrier | 78 | |
Katzmann D.J. | 2001 | Ubiquitinated Proteins and ESCRT | 79 | |
Iavello A. | 2016 | miRNA and ESCRT | 80 | |
Andreu Z. | 2014 | Tetraspanin | 81 | |
Frankel E.B. | 2018 | ESCRT and APIs | 82 | |
Zhang Y. | 2010 | miRNA overexpression | 83 | |
Pan Q. | 2012 | RNAi overexpression | 84 | |
Olson S.D. | 2012 | RNAi overexpression | 85 | |
Cocozza F. | 2020 | Angiotensin-converting Enzyme 2 overexpression | 86 | |
Zhang Q. | 2021 | Angiotensin-converting Enzyme 2 overexpression | 87 | |
Sterzenbach U. | 2017 | Proteins tagging | 88 | |
Liu C. | 2019 | Proteins tagging | 89 | |
Manfredi F. | 2016 | Nef exosome-anchoring | 90 | |
Ma J. | 2016 | Co-incubation of EVs and APIs | 91 | |
Fu S. | 2020 | Co-incubation of EVs and APIs | 92 | |
Yong T. | 2014 | Nanoparticles | 93 | |
Illes B | 2017 | Nanoparticles | 94 | |
Tian Y. | 2014 | Active cargo loading | 95 | |
Fuhrmann G. | 2015 | Active cargo loading | 96 | |
Pomatto M.A.C. | 2019 | Active cargo loading | 97 | |
Kim M.S. | 2016 | Active cargo loading | 98 | |
Lamichhane T.N. | 2021 | Active cargo loading | 99 | |
Wang C. | 2017 | Active cargo loading | 100 | |
4. EV targeting | Matsumoto A. | 2017 | Macropahges | 101 |
Hoshino A. | 2015 | Tumor | 102 | |
Morelli A.E. | 2004 | Dendritic cells | 103 | |
Syn N.L. | 2017 | Cancer therapy | 104 | |
Gomari H. | 2018 | Cancer therapy | 105 | |
Sugahara K.N. | 2010 | Cancer drug | 107 | |
Mentkowski K.I. | 2019 | Cardiac therapy | 108 | |
Hung M.E. | 2015 | Cancer therapy | 109 | |
Ciullo A. | 2019 | Cardiac therapy | 110 | |
5. Cargo delivery | Raposo G. | 1996 | Ligand-Receptor | 3 |
Joshi B.S. | 2020 | Endocytosis | 111 | |
Prada I. | 2016 | Binding and Fusion | 112 | |
Dimitrov D.S. | 2004 | Virus entra | 113 | |
Rappa G. | 2017 | Late endosome | 114 | |
Pedrioli G. | Preprint | Autophagy patway | 115 |
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Pedrioli, G.; Piovesana, E.; Vacchi, E.; Balbi, C. Extracellular Vesicles as Promising Carriers in Drug Delivery: Considerations from a Cell Biologist’s Perspective. Biology 2021, 10, 376. https://doi.org/10.3390/biology10050376
Pedrioli G, Piovesana E, Vacchi E, Balbi C. Extracellular Vesicles as Promising Carriers in Drug Delivery: Considerations from a Cell Biologist’s Perspective. Biology. 2021; 10(5):376. https://doi.org/10.3390/biology10050376
Chicago/Turabian StylePedrioli, Giona, Ester Piovesana, Elena Vacchi, and Carolina Balbi. 2021. "Extracellular Vesicles as Promising Carriers in Drug Delivery: Considerations from a Cell Biologist’s Perspective" Biology 10, no. 5: 376. https://doi.org/10.3390/biology10050376
APA StylePedrioli, G., Piovesana, E., Vacchi, E., & Balbi, C. (2021). Extracellular Vesicles as Promising Carriers in Drug Delivery: Considerations from a Cell Biologist’s Perspective. Biology, 10(5), 376. https://doi.org/10.3390/biology10050376