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Exo-spin citations

Akerman, A.W., Blanding, W.M., Stroud, R.E., Nadeau, E.K., Mukherjee, R., Ruddy, J.M., Zile, M.R., Ikonomidis, J.S. and Jones, J.A. (2019). Elevated Wall Tension Leads to Reduced miR-133a in the Thoracic Aorta by Exosome Release. [online] Journal of the American Heart Association. Available at: https://pubmed.ncbi.nlm.nih.gov/30572760-elevated-wall-tension-leads-to-reduced-mir-133a-in-the-thoracic-aorta-by-exosome-release/ [Accessed 27 Feb. 2020].

Almanza, G., Rodvold, J.J., Tsui, B., Jepsen, K., Carter, H. and Zanetti, M. (2018). Extracellular Vesicles Produced in B Cells Deliver Tumor Suppressor miR-335 to Breast Cancer Cells Disrupting Oncogenic Programming in Vitro and in Vivo. [online] Scientific reports. Available at: https://pubmed.ncbi.nlm.nih.gov/30514916-extracellular-vesicles-produced-in-b-cells-deliver-tumor-suppressor-mir-335-to-breast-cancer-cells-disrupting-oncogenic-programming-in-vitro-and-in-vivo/ [Accessed 27 Feb. 2020].

Busatto, S., Vilanilam, G., Ticer, T., Lin, W.I., Dickson, D.W., Shapiro, S., Bergese, P. and Wolfram, J. (2018). Tangential Flow Filtration for Highly Efficient Concentration of Extracellular Vesicles From Large Volumes of Fluid. [online] Cells. Available at: https://pubmed.ncbi.nlm.nih.gov/30558352-tangential-flow-filtration-for-highly-efficient-concentration-of-extracellular-vesicles-from-large-volumes-of-fluid/ [Accessed 27 Feb. 2020].

Guo, D., Lui, G., Lai, S.I., Wilmott, J.S., Tikoo, S., Jackett, L.A., Quek, C., Brown, D.I., Sharp, D.M., Kwan, R., Chacon, D., Wong, J.H., Beck, D., van Geldermalsen, M., Holst, J., Thompson, J.F., Mann, G.J., Scolyer, R.A., Stow, J.L., Weninger, W., Haass, N.K. and Beaumont, K.A. (2019). RAB27A Promotes Melanoma Cell Invasion and Metastasis via Regulation of Pro-Invasive Exosomes. [online] International journal of cancer. Available at: https://pubmed.ncbi.nlm.nih.gov/30556600-rab27a-promotes-melanoma-cell-invasion-and-metastasis-via-regulation-of-pro-invasive-exosomes/ [Accessed 27 Feb. 2020].

Hu, J., Wang, S., Xiong, Z., Cheng, Z., Yang, Z., Lin, J., Wang, T., Feng, X., Gao, E., Wang, H. and Sun, D. (2018a). Exosomal Mst1 transfer from cardiac microvascular endothelial cells to cardiomyocytes deteriorates diabetic cardiomyopathy. Biochimica et Biophysica Acta (BBA) - Molecular Basis of Disease, [online] 1864(11), pp.3639–3649. Available at: https://www.sciencedirect.com/science/article/pii/S0925443918303193.[Accessed 27 Feb. 2020].

Hu, W., Ru, Z., Xiao, W., Xiong, Z., Wang, C., Yuan, C., Zhang, X. and Yang, H. (2018b). Adipose Tissue Browning in Cancer-Associated Cachexia Can Be Attenuated by Inhibition of Exosome Generation. [online] Biochemical and biophysical research communications. Available at: https://pubmed.ncbi.nlm.nih.gov/30340833-adipose-tissue-browning-in-cancer-associated-cachexia-can-be-attenuated-by-inhibition-of-exosome-generation/ [Accessed 27 Feb. 2020].

Kanlikilicer, P., Bayraktar, R., Denizli, M., Rashed, M.H., Ivan, C., Aslan, B., Mitra, R., Karagoz, K., Bayraktar, E., Zhang, X., Rodriguez-Aguayo, C., El-Arabey, A.A., Kahraman, N., Baydogan, S., Ozkayar, O., Gatza, M.I., Ozpolat, B., Calin, G.A., Sood, A.K. and Lopez-Berestein, G. (2018). Exosomal miRNA Confers Chemo Resistance via Targeting Cav1/p-gp/M2-type Macrophage Axis in Ovarian Cancer. [online] EBioMedicine. Available at: https://pubmed.ncbi.nlm.nih.gov/30487062-exosomal-mirna-confers-chemo-resistance-via-targeting-cav1p-gpm2-type-macrophage-axis-in-ovarian-cancer/ [Accessed 27 Feb. 2020].

Lainšček, D., Kadunc, L., Keber, M.M., Bratkovič, I.H., Romih, R. and Jerala, R. (2018). Delivery of an Artificial Transcription Regulator dCas9-VPR by Extracellular Vesicles for Therapeutic Gene Activation. [online] ACS synthetic biology. Available at: https://pubmed.ncbi.nlm.nih.gov/30513193-delivery-of-an-artificial-transcription-regulator-dcas9-vpr-by-extracellular-vesicles-for-therapeutic-gene-activation/ [Accessed 27 Feb. 2020].

Lee, H., Park, H., Noh, G.J. and Lee, E.S. (2018). pH-responsive hyaluronate-anchored extracellular vesicles to promote tumor-targeted drug delivery. Carbohydrate Polymers, [online] 202, pp.323–333. Available at: https://www.sciencedirect.com/science/article/pii/S0144861718310609 [Accessed 20 Feb. 2020].

Li, B., Li, L., Zhang, Q., Zhang, H. and Xiu, R. (2019). Effects of Tumor Necrosis Factor-α-Induced Exosomes on the Endothelial Cellular Behavior, Metabolism and Bioenergetics. [online] Microcirculation (New York, N.Y. : 1994). Available at: https://pubmed.ncbi.nlm.nih.gov/30431204-effects-of-tumor-necrosis-factor-induced-exosomes-on-the-endothelial-cellular-behavior-metabolism-and-bioenergetics/ [Accessed 27 Feb. 2020].

Mao, Q., Nguyen, P.D., Shanti, R.M., Shi, S., Shakoori, P., Zhang, Q. and Le, A.D. (2019). Gingiva-Derived Mesenchymal Stem Cell-Extracellular Vesicles Activate Schwann Cell Repair Phenotype and Promote Nerve Regeneration. [online] Tissue engineering. Part A. Available at: https://pubmed.ncbi.nlm.nih.gov/30311853-gingiva-derived-mesenchymal-stem-cell-extracellular-vesicles-activate-schwann-cell-repair-phenotype-and-promote-nerve-regeneration/ [Accessed 27 Feb. 2020].

Mrowczynski, O.D., Madhankumar, A.B., Sundstrom, J.M., Zhao, Y., Kawasawa, Y.I., Slagle-Webb, B., Mau, C., Payne, R.A., Rizk, E.B., Zacharia, B.E. and Connor, J.R. (2018). Exosomes Impact Survival to Radiation Exposure in Cell Line Models of Nervous System Cancer. [online] Oncotarget. Available at: https://pubmed.ncbi.nlm.nih.gov/30546829-exosomes-impact-survival-to-radiation-exposure-in-cell-line-models-of-nervous-system-cancer/ [Accessed 27 Feb. 2020].

Peng, Q., Zhang, J. and Zhou, G. (2019). Circulating exosomes regulate T-cell-mediated inflammatory response in oral lichen planus. Journal of Oral Pathology & Medicine: Official Publication of the International Association of Oral Pathologists and the American Academy of Oral Pathology, [online] 48(2), pp.143–150. Available at: https://www.ncbi.nlm.nih.gov/pubmed/30447107.[Accessed 27 Feb. 2020].

Raffo-Romero, A., Arab, T., Al-Amri, I.S., Le Marrec-Croq, F., Van Camp, C., Lemaire, Q., Salzet, M., Vizioli, J., Sautiere, P.E. and Lefebvre, C. (2018). Medicinal Leech CNS as a Model for Exosome Studies in the Crosstalk Between Microglia and Neurons. [online] International journal of molecular sciences. Available at: https://pubmed.ncbi.nlm.nih.gov/30572617-medicinal-leech-cns-as-a-model-for-exosome-studies-in-the-crosstalk-between-microglia-and-neurons/ [Accessed 27 Feb. 2020].

Shtam, T., Naryzhny, S., Samsonov, R., Karasik, D., Mizgirev, I., Kopylov, A., Petrenko, E., Zabrodskaya, Y., Kamyshinsky, R., Nikitin, D., Sorokin, M., Buzdin, A., Gil-Henn, H. and Malek, A. (2018). Plasma exosomes stimulate breast cancer metastasis through surface interactions and activation of FAK signaling. Breast Cancer Research and Treatment, 174(1), pp.129–141. Available at: https://pubmed.ncbi.nlm.nih.gov/30484103-plasma-exosomes-stimulate-breast-cancer-metastasis-through-surface-interactions-and-activation-of-fak-signaling/ [Accessed 27 Feb. 2020].

Soares Martins, T., Catita, J., Martins Rosa, I., A. B. da Cruz e Silva, O. and Henriques, A.G. (2018). Exosome isolation from distinct biofluids using precipitation and column-based approaches. PLOS ONE, 13(6), p.e0198820. Available at: https://pubmed.ncbi.nlm.nih.gov/29889903-exosome-isolation-from-distinct-biofluids-using-precipitation-and-column-based-approaches/ [Accessed 27 Feb. 2020].

Sun, H., Li, D., Yuan, M., Li, Q., Li, N. and Wang, G. (2019a). Eutopic Stromal Cells of Endometriosis Promote Neuroangiogenesis via Exosome Pathway†. [online] Biology of reproduction. Available at: https://pubmed.ncbi.nlm.nih.gov/30295741-eutopic-stromal-cells-of-endometriosis-promote-neuroangiogenesis-via-exosome-pathway/ [Accessed 27 Feb. 2020].

Sun, H., Li, D., Yuan, M., Li, Q., Zhen, Q., Li, N. and Wang, G. (2019b). Macrophages Alternatively Activated by Endometriosis-Exosomes Contribute to the Development of Lesions in Mice. [online] Molecular human reproduction. Available at: https://pubmed.ncbi.nlm.nih.gov/30428082-macrophages-alternatively-activated-by-endometriosis-exosomes-contribute-to-the-development-of-lesions-in-mice/ [Accessed 27 Feb. 2020].