Improved circulating microparticle analysis in acid-citrate dextrose (ACD) anticoagulant tube

György, Bence; Pálóczi, Krisztina; Kovacs, A; Barabás, Eszter; Bekő, Gabriella; Várnai, Katalin; Pállinger, Éva; Szabó-Taylor, Katalin; Szabó, Tamás; Kiss, Attila; Falus, András; Buzás, Edit I.

doi:10.1016/j.thromres.2013.11.010

Cited by 108 publications

(111 citation statements)

References 31 publications

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“…Storage of red cell concentrates lead to an exponential increase in red cell microvesicles, with a 20-fold increase from 6 to 50 days of storage (17). Vigorous agitation for 1 2 2 h lead to 200 2 900% increases in platelet and/or annexin V1 microvesicles (11,14). Transportation of sample tubes horizontally lead to higher platelet microvesicle counts than transportation of sample tubes in a vertical position.…”

Section: Sample Transportation and Processingmentioning

confidence: 99%

“…This has been accomplished using electron microscopy by observing the lipid membrane structure of the microvesicles or using lipid binding dyes such as annexin V, lactadherin, and PKH67. An alternate approach is to use a less specific method to count microvesicles and then to treat the sample with a detergent that disrupts membranes followed by repeat measurement to show what fraction of the count was due to lipid vesicles (11,35). One difficulty with use of detergents is they generate a large number of small membrane fragments.…”

Section: Interference and Assay Optimizationmentioning

confidence: 99%

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Measurement of microvesicle levels in human blood using flow cytometry

Chandler

2016

Cytometry Part B Clinical

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Microvesicles are fragments of cells released when the cells are activated, injured, or apoptotic. Analysis of microvesicle levels in blood has the potential to shed new light on the pathophysiology of many diseases. Flow cytometry is currently the only method that can simultaneously separate true lipid microvesicles from other microparticles in blood, determine the cell of origin and other microvesicle characteristics, and handle large numbers of clinical samples with a reasonable effort, but expanded use of flow cytometric measurement of microvesicle levels as a clinical and research tool requires improved, standardized assays. The goal of this review is to aid investigators in applying current best practices to microvesicle measurements. First pre-analytical factors are evaluated and data summarized for anticoagulant effects, sample transport and centrifugation. Next flow cytometer optimization is reviewed including interference from background in buffers and reagents, accurate microvesicle counting, swarm interference, and other types of coincidence errors, size calibration, and detection limits using light scattering, impedance and fluorescence. Finally current progress on method standardization is discussed and a summary of current best practices provided. V C 2016 Clinical Cytometry Society

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Section: Sample Transportation and Processingmentioning

confidence: 99%

Section: Interference and Assay Optimizationmentioning

confidence: 99%

Measurement of microvesicle levels in human blood using flow cytometry

Chandler

2016

Cytometry Part B Clinical

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“…Furthermore, an ongoing Phase II trial which assesses the efficacy of dendritic cell derived exosomes as autologous therapeutic vaccines in advanced non-small cell lung carcinoma (NSCLC) patients to stimulate their natural defences to prevent tumor progression [71]. The preclinical [72] and clinical data [72] …”

Section: Clinical Applications Of Other Membrane Vesicles In Cancermentioning

confidence: 99%

Microparticles in cancer: A review of recent developments and the potential for clinical application

Gong

Jaiswal

Dalla

et al. 2015

Seminars in Cell & Developmental Biology

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Once thought of as inert remnants of cellular processes, the significance of membrane vesicles is now expanding as their capacity to package and transfer bioactive molecules during intercellular communication is established. This ability to serve as vectors in the trafficking of cellular cargo is of mounting interest in the context of cancer, particularly in the dissemination of deleterious cancer traits from parent cells to recipient cells. Although microparticles (MPs) contribute to the pathogenesis of cancer, their unique characteristics can also be also exploited in the context of cancer treatment. The detection of MPs in body fluids has the potential to provide an effective means for the diagnosis, prognosis and surveillance of cancer patients. The use of such easily accessible systemic biomarkers that reflect the characteristics of the parent cells circumvents the need for invasive biopsy procedures. In addition, the autologous nature of MPs may allow them to be used as novel therapeutic drug carriers. Thus the modulation of MP vesiculation, the detection of MPs in disease monitoring, and the application of MPs as therapeutic delivery vehicles present prospective clinical interventions in the treatment of cancer. Revision Notes1. The authors overviewed the contribution of microparticles (MPs) to the pathogenesis of cancer and the potential for clinical application of MPs. In contrast to the title of the manuscript "Microparticles in Cancer: A Review of Recent Developments and the Potential for Clinical Application.", a large part of the content of this manuscript occupied the refer and discussed on the publications of the authors' group. The authors should discuss more generally on state-of-the-art for clinical application of MPs or some other extracellular vesicles (EVs). The authors have now included an extra section on Page 10 discussing the clinical applications of extracellular vesicles in cancer.2. The authors should refer to sufficient publications in general, especially in cancer-derived extracellular vesicles.Other references relevant to this study have now been added.3. The term "microparticles" mainly used in this manuscript is not well documented. Is there any specific differences between MPs and EVs? If so please describe those appropriately in the text. An explanation has now been added on Page 3 to describe the different membrane vesicles.4. The authors described "exosomes" in the text in the section 4. However, there is no mentioned the differ from MPs. This is a very confusing. An explanation of the different membrane vesicles has now been included on Page 3.5. The content of the figure is a very limited information. Modify the figure more generously including more other findings on tumor metastasis and drug resistance. Additional figures have now been included. Revision NotesAbbreviations: Matrix metalloproteinases, MMPs; mesenchymal stem cells, MSC; MPs, microparticles; miRNA, microRNA; microvesicles, MVs; MDR, multidrug resistance; non-small cell lung carcinoma, NSCLC; P-gp, P...

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“…Besides the purification protocol, also other parameters, among which the sample collection procedure (e.g. the type of anticoagulant during blood collection [250]), processing time and sample store conditions [65,86] can influence the outcome of biomarker identification studies [251]. In response to this unmet need, an ISEV position paper was issued describing guidelines on how to handle different biological fluid samples and emphasizing the importance of a comprehensive experimental description to enhance reproducibility [252].…”

Section: 3perspectivesmentioning

confidence: 99%

Therapeutic and diagnostic applications of extracellular vesicles

Stremersch

Smedt

Raemdonck

2016

Journal of Controlled Release

159

103

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During the past two decades, extracellular vesicles (EVs) have been identified as important mediators of intercellular communication, enabling the functional transfer of bioactive molecules from one cell to another. Consequently, it is becoming increasingly clear that these vesicles are involved in many (patho)physiological processes, providing opportunities for therapeutic applications. Moreover, it is known that the molecular composition of EVs reflects the physiological status of the producing cell and tissue, rationalizing their exploitation as biomarkers in various diseases. In this review the composition, biogenesis and diversity of EVs is discussed in a therapeutic and diagnostic context. We describe emerging therapeutic applications, including the use of EVs as drug delivery vehicles and as cell-free vaccines, and reflect on future challenges for clinical translation. Finally, we discuss the use of EVs as a biomarker source and highlight recent studies and clinical successes.

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Improved circulating microparticle analysis in acid-citrate dextrose (ACD) anticoagulant tube

Cited by 108 publications

References 31 publications

Measurement of microvesicle levels in human blood using flow cytometry

Measurement of microvesicle levels in human blood using flow cytometry

Microparticles in cancer: A review of recent developments and the potential for clinical application

Therapeutic and diagnostic applications of extracellular vesicles

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