Extracellular vesicle characteristics in stored red blood cell concentrates are influenced by the method of detection

Transfusion and Apheresis Science

Volumn 56, Issue 2, 2017, Pages 254-260

  Almizraq, Ruqayyah J ^a   Seghatchian, Jerard ^b   Holovati, Jelena L ^a,c   Acker, Jason P ^a,c  

^a UNIVERSITY OF ALBERTA   (Canada)

^b International Consultancy in Blood Components Quality Safety Improvement   (United Kingdom)

^c CANADIAN BLOOD SERVICES   (Canada)

Author keywords

Blood bank; Erythrocyte; Exosomes; Microparticles; Transfusion medicine

Indexed keywords

BLOOD SAMPLING; ERYTHROCYTE CONCENTRATE; ERYTHROCYTE PRESERVATION; EXOSOME; FLOW CYTOMETRY; HUMAN; MEDICAL TECHNOLOGY; PHOTON CORRELATION SPECTROSCOPY; REVIEW; BLOOD STORAGE; CYTOLOGY; ERYTHROCYTE; MEMBRANE MICROPARTICLE; METABOLISM; TIME FACTOR;

BLOOD PRESERVATION; CELL-DERIVED MICROPARTICLES; ERYTHROCYTES; HUMANS; TIME FACTORS;

EID: 85016621554     PISSN: 14730502     EISSN: 18781683     Source Type: Journal    
DOI: 10.1016/j.transci.2017.03.007     Document Type: Review

References (44)

1. [1] Rubin, O., Crettaz, D., Canellini, G., Tissot, J.D., Lion, N., Microparticles in stored red blood cells: an approach using flow cytometry and proteomic tools. Vox Sanguinis 95:4 (2008), 288–297.
2. [2] Kriebardis, A., Antonelou, M., Stamoulis, K., Papassideri, I., Cell-derived microparticles in stored blood products: innocent-bystanders or effective mediators of post-transfusion reactions?. Blood Transfus 10 (2012), S25–S38.
3. [3] Dumaswala, U.J., Dumaswala, R.U., Levin, D.S., Greenwalt, T.J., Improved red blood cell preservation correlates with decreased loss of bands 3, 4.1, acetylcholinestrase, and lipids in microvesicles. Blood 87:4 (1996), 1612–1616.
4. [4] Almizraq, R., Tchir, J.D.R., Holovati, J.L., Acker, J.P., Storage of red blood cells affects membrane composition, microvesiculation, and in vitro quality. Transfusion 53:10 (2013), 2258–2267.
5. [5] Greenwalt, T.J., Bryan, D.J., Dumaswala, U.J., Erythrocyte membrane vesiculation and changes in membrane composition during storage in citrate-phosphate-dextrose-adenine-1. Vox Sanguinis 47:4 (1984), 261–270.
6. [6] Momen-Heravi, F., Balaj, L., Alian, S., Tigges, J., Toxavidis, V., Ericsson, M., et al. Alternative methods for characterization of extracellular vesicles. Front Physiol, 3, 2012, 354.
7. [7] Kastelowitz, N., Yin, H., Exosomes and microvesicles: Identification and targeting by particle size and lipid chemical probes. ChemBioChem 15:7 (2014), 923–928.
8. [8] Tissot, J.-D., Canellini, G., Rubin, O., Angelillo-Scherrer, A., Delobel, J., Prudent, M., et al. Blood microvesicles: from proteomics to physiology. Transl Proteom 1:1 (2013), 38–52.
9. [9] Lee, Y., El Andaloussi, S., Wood, M.J., Exosomes and microvesicles: extracellular vesicles for genetic information transfer and gene therapy. Hum Mol Genet 21:R1 (2012), R125–R134.
10. [10] Varga, Z., Yuana, Y., Grootemaat, A.E., van der Pol, E., Gollwitzer, C., Krumrey, M., et al. Towards traceable size determination of extracellular vesicles. J Extracell Vesicles, 3, 2014, 23298.
11. [11] Headland, S.E., Jones, H.R., D'Sa, A.S.V., Perretti, M., Norling, L.V., Cutting-edge analysis of extracellular microparticles using ImageStream(X) imaging flow cytometry. Sci Rep, 4, 2014, 5237.
12. [12] Seghatchian, J., Amiral, J., Unresolved clinical aspects and safety hazards of blood derived- EV/MV in stored blood components: From personal memory lanes to newer perspectives on the roles of EV/MV in various biological phenomena. Transfus Apheresis Sci 55:1 (2016), 10–22.
13. [13] Burnouf, T., Chou, M.L., Goubran, H., Cognasse, F., Garraud, O., Seghatchian, J., An overview of the role of microparticles/microvesicles in blood components: are they clinically beneficial or harmful?. Transfus Apheresis Sci 53:2 (2015), 137–145.
14. [14] Fernandez-Messina, L., Gutierrez-Vazquez, C., Rivas-Garcia, E., Sanchez-Madrid, F., de la Fuente, H., Immunomodulatory role of microRNAs transferred by extracellular vesicles. Biol Cell 107:3 (2015), 61–77.
15. [15] Valadi, H., Ekstrom, K., Bossios, A., Sjostrand, M., Lee, J.J., Lotvall, J.O., Exosome-mediated transfer of mRNAs and microRNAs is a novel mechanism of genetic exchange between cells. Nat Cell Biol 9:6 (2007), 654–659.
16. [16] Jong-Kuen, L., Ji-Young, J., Yoon-Kyung, J., Chul-Woo, K., Extracellular vesicles as an emerging paradigm of cell-to-cell communication in stem cell biology. J Stem Cell Res Therapy 4:5 (2014), 1–5.
17. [17] Loyer, X., Vion, A.C., Tedgui, A., Boulanger, C.M., Microvesicles as cell–cell messengers in cardiovascular diseases. Circ Res 114:2 (2014), 345–353.
18. [18] Sluijter, J.P., Verhage, V., Deddens, J.C., van den Akker, F., Doevendans, P.A., Microvesicles and exosomes for intracardiac communication. Cardiovasc Res 102:2 (2014), 302–311.
19. [19] Turturici, G., Tinnirello, R., Sconzo, G., Geraci, F., Extracellular membrane vesicles as a mechanism of cell-to-cell communication: advantages and disadvantages. Am J Physiol Cell Physiol 306:7 (2014), C621–C633.
20. [20] Aatonen, M., Gronholm, M., Siljander, P.R.M., Platelet-derived microvesicles: multitalented participants in intercellular communication. Semin Thromb Hemost 38:1 (2012), 102–113.
21. [21] van der Pol, E., Boing, A.N., Harrison, P., Sturk, A., Nieuwland, R., Classification, Functions, and clinical relevance of extracellular vesicles. Pharmacol Rev 64:3 (2012), 676–705.
22. [22] Maas, S.L.N., De Vrij, J., Broekman, M.L.D., Quantification and size-profiling of extracellular vesicles using tunable resistive pulse sensing. Jove-J Vis Exp(92), 2014, e51623.
23. [23] Almizraq, R.J., Seghatchian, J., Acker, J.P., Extracellular vesicles in transfusion-related immunomodulation and the role of blood component manufacturing. Transfus Apheresis Sci 55 (2016), 281–291.
24. [24] Yuana, Y., Koning, R.I., Kuil, M.E., Rensen, P.C., Koster, A.J., Bertina, R.M., et al. Cryo-electron microscopy of extracellular vesicles in fresh plasma. J Extracell Vesicles, 2, 2013, 21494.
25. [25] Momen-Heravi, F., Balaj, L., Alian, S., Mantel, P.Y., Halleck, A.E., Trachtenberg, A.J., et al. Current methods for the isolation of extracellular vesicles. Biol Chem 394:10 (2013), 1253–1262.
26. [26] Van Der Pol, E., Coumans, F., Varga, Z., Krumrey, M., Nieuwland, R., Innovation in detection of microparticles and exosomes. J Thromb Haemost 11 (2013), 36–45.
27. [27] Franquesa, M., Hoogduijn, M.J., Ripoll, E., Luk, F., Salih, M., Betjes, M.G., et al. Update on controls for isolation and quantification methodology of extracellular vesicles derived from adipose tissue mesenchymal stem cells. Front Immunol, 5, 2014, 525.
28. [28] Raposo, G., Nijman, H.W., Stoorvogel, W., Liejendekker, R., Harding, C.V., Melief, C.J., et al. B lymphocytes secrete antigen-presenting vesicles. J Exp Med 183:3 (1996), 1161–1172.
29. [29] Danesh, A., Inglis, H.C., Jackman, R.P., Wu, S.Q., Deng, X.T., Muench, M.O., et al. Exosomes from red blood cell units bind to monocytes and induce proinflammatory cytokines, boosting T-cell responses in vitro. Blood 123:5 (2014), 687–696.
30. [30] Maas, S.L., de Vrij, J., van der Vlist, E.J., Geragousian, B., van Bloois, L., Mastrobattista, E., et al. Possibilities and limitations of current technologies for quantification of biological extracellular vesicles and synthetic mimics. J Control Release 200 (2015), 87–96.
31. [31] Matijevic, N., Wang, Y.W., Cotton, B.A., Hartwell, E., Barbeau, J.M., Wade, C.E., et al. Better hemostatic profiles of never-frozen liquid plasma compared with thawed fresh frozen plasma. J Trauma Acute Care Surg 74:1 (2013), 84–90.
32. [33] Hansen, A.L., Kurach, J.D., Turner, T.R., Jenkins, C., Busch, M.P., Norris, P.J., et al. The effect of processing method on the in vitro characteristics of red blood cell products. Vox Sanguinis, 2015.
33. [34] Levin, E., Culibrk, B., Gyöngyössy-Issa, M.I.C., Weiss, S., Scammell, K., LeFresne, W., et al. Implementation of buffy coat platelet component production: comparison to platelet-rich plasma platelet production. Transfusion 48:11 (2008), 2331–2337.
34. [35] Hansen, A., Yi, Q.-L., Acker, J.P., Quality of red blood cells washed using the ACP 215 cell processor: assessment of optimal pre- and postwash storage times and conditions. Transfusion 53:8 (2013), 1772–1779.
35. [36] Acker, J.P., Hansen, A.L., Kurach, J.D.R., Turner, T.R., Croteau, I., Jenkins, C., A quality monitoring program for red blood cell components: in vitro quality indicators before and after implementation of semiautomated processing. Transfusion 54:10 (2014), 2534–2543.
36. [37] Bicalho, B., Pereira, A.S., Acker, J.P., Buffy coat (top/bottom)- and whole-blood filtration (top/top)-produced red cell concentrates differ in size of extracellular vesicles. Vox Sanguinis 109:3 (2015), 214–220.
37. [38] van der Meel, R., Fens, M.H.A.M., Vader, P., van Solinge, W.W., Eniola-Adefeso, O., Schiffelers, R.M., Extracellular vesicles as drug delivery systems: lessons from the liposome field. J Control Release 195 (2014), 72–85.
38. [39] Zocco, D., Ferruzzi, P., Cappello, F., Kuo, W.P., Fais, S., Extracellular vesicles as shuttles of tumor biomarkers and anti-tumor drugs. Front Oncol, 4, 2014, 267.
39. [40] Johnsen, K.B., Gudbergsson, J.M., Skov, M.N., Pilgaard, L., Moos, T., Duroux, M., A comprehensive overview of exosomes as drug delivery vehicles – endogenous nanocarriers for targeted cancer therapy. BBA-Rev Cancer 1846:1 (2014), 75–87.
40. [41] van Dommelen, S.M., Vader, P., Lakhal, S., Kooijmans, S.A.A., van Solinge, W.W., Wood, M.J.A., et al. Microvesicles and exosomes: opportunities for cell-derived membrane vesicles in drug delivery. J Control Release 161:2 (2012), 635–644.
41. [42] Connor, D.E., Exner, T., Ma, D.D.F., Joseph, J.E., The majority of circulating platelet-derived microparticles fail to bind annexin V, lack phospholipid-dependent procoagulant activity and demonstrate greater expression of glycoprotein Ib. Thromb Haemost 103:5 (2010), 1044–1052.
42. [43] Chandler, W.L., Yeung, W., Tait, J.F., A new microparticle size calibration standard for use in measuring smaller microparticles using a new flow cytometer. J Thromb Haemost 9:6 (2011), 1216–1224.
43. [44] Lawrie, A.S., Albanyan, A., Cardigan, R.A., Mackie, I.J., Harrison, P., Microparticle sizing by dynamic light scattering in fresh-frozen plasma. Vox Sanguinis 96:3 (2009), 206–212.
44. [45] Dragovic, R.A., Gardiner, C., Brooks, A.S., Tannetta, D.S., Ferguson, D.J.P., Hole, P., et al. Sizing and phenotyping of cellular vesicles using nanoparticle tracking analysis. Nanomed Nanotechnol 7:6 (2011), 780–788.