Rapid, high-throughput isolation of tumor specific small extracellular vesicles using radial flow microfluidic chip with IEDDA chemistry (ExoOnco ChipEpCAM−TCO)

Reliable isolation and quantitation of extracellular vesicles (EVs), which function as natural bioactive nanocarriers in biological processes, are essential to uncovering their underlying mechanisms and applications. To meet these requirements, we present here a peptide-engineered biomimetic nanoplatform featuring cell-membrane camouflage. This biomimetic nanoplatform utilizes specific peptide ligands to facilitate the "capture-release" isolation of EVs while enhancing performance by harnessing the antifouling and fluidity advantages afforded by the camouflage of red blood cell membranes. Furthermore, this nanoplatform streamlines the electrochemical quantitation of EVs via a nondestructive labeling and delabeling process, showing accuracy comparable to that of widely used nanoparticle tracking analysis. Validating with EVs from breast cancer cells and human embryonic stem cells, this nanoplatform is also proved to effectively maintain the biological activities of the isolated EVs, thereby enabling precise regulation of cell migration and antiapoptotic response. As such, this biomimetic nanoplatform stands as a highly effective solution for isolating and quantitatively assessing EVs from diverse sources, thus propelling the potential applications of EVs in biomedical and clinical research.

Extracellular vesicles (EVs) are small membranous vesicles secreted by cells into their surrounding extracellular environment. Similar to mammalian EVs, plant EVs have emerged as essential mediators of intercellular communication in plants that facilitate the transfer of biological material between cells. They also play essential roles in diverse physiological processes including stress responses, developmental regulation, and defense mechanisms against pathogens. In addition, plant EVs have demonstrated promising health benefits as well as potential therapeutic effects in mammalian health. Despite the plethora of potential applications using plant EVs, their isolation and characterization remains challenging. In contrast to mammalian EVs, which benefit from more standardized isolation protocols, methods for isolating plant EVs can vary depending on the starting material used, resulting in diverse levels of purity and composition. Additionally, the field suffers from the lack of plant EV markers. Nevertheless, three main EV subclasses have been described from leaf apoplasts: tetraspanin 8 positive (TET8), penetration-1-positive (PEN1), and EXPO vesicles derived from exocyst-positive organelles (EXPO). Here, we present an optimized protocol for the isolation and enrichment of small EVs (sEVs; <200 nm) from the apoplastic fluid from Nicotiana benthamiana leaves by ultracentrifugation. We analyze the preparation through transmitted electron microscopy (TEM), nanoparticle tracking analysis (NTA), and western blotting. We believe this method will establish a basic protocol for the isolation of EVs from N. benthamiana leaves, and we discuss technical considerations to be evaluated by each researcher working towards improving their plant sEV preparations. © 2024 The Author(s). Current Protocols published by Wiley Periodicals LLC. Basic Protocol: Isolation and enrichment of small extracellular vesicles (sEVs) from the apoplastic fluid of Nicotiana benthamiana leaves.

Extracellular vesicles (EVs) are small, membranous particles that have recently emerged as one the most important mediators of intercellular communication. They can contain a variety of proteins, lipids, and nucleic acids and thus are responsible for modulation of multiple biological processes, including immune response and regulation of immune cells. Immunomodulatory activity of different EVs can be reliably assessed using EVs isolated from cell culture conditioned medium and added to in vitro or ex vivo cultures of immune cells. This article describes protocols for isolation of EVs from cell culture supernatants by differential ultracentrifugation and density gradient centrifugation. It also provides tools and protocols that enable characterization and validation of isolated particles, as well as analysis of interactions between EVs of interest and different subpopulations of human immune cells. © 2020 Wiley Periodicals LLC. Basic Protocol 1: Isolation of extracellular vesicles by differential ultracentrifugation Basic Protocol 2: Isolation of extracellular vesicles by density gradient centrifugation Support Protocol 1: Imaging of extracellular vesicles using transmission electron microscopy Support Protocol 2: Detection of extracellular vesicle protein markers by Western blotting Support Protocol 3: Measurement and counting of extracellular vesicles by nanoparticle tracking analysis Basic Protocol 3: Analysis of extracellular vesicle uptake or association by different subpopulations of lymphocytes in vitro.

Extracellular vesicles (EVs) are a heterogeneous group of nanoparticles possessing a lipid bilayer membrane that plays a significant role in intercellular communication by transferring their cargoes, consisting of peptides, proteins, fatty acids, DNA, and RNA, to receiver cells. Isolation of EVs is cumbersome and time-consuming due to their nano size and the co-isolation of small molecules along with EVs. This is why current protocols for the isolation of EVs are unable to provide high purity. So far, studies have focused on EVs derived from cell supernatants or body fluids but are associated with a number of limitations. Cell lines with a high passage number cannot be considered as representative of the original cell type, and EVs isolated from those can present distinct properties and characteristics. Additionally, cultured cells only have a single cell type and do not possess any cellular interactions with other types of cells, which normally exist in the tissue microenvironment. Therefore, studies involving the direct EVs isolation from whole tissues can provide a better understanding of intercellular communication in vivo. This underscores the critical need to standardize and optimize protocols for isolating and characterizing EVs from tissues. We have developed a differential centrifugation-based technique to isolate and characterize EVs from whole adipose tissue, which can be potentially applied to other types of tissues. This may help us to better understand the role of EVs in the tissue microenvironment in both diseased and normal conditions. Key features • Isolation of tissue-derived extracellular vesicles from ex vivo culture of visceral adipose tissue or any whole tissue. • Microscopic visualization of extracellular vesicles' morphology without dehydration steps, with minimum effect on their shape. • Flow cytometry approach to characterize the extracellular vesicles using specific protein markers, as an alternative to the time-consuming western blot.

Nano-scale extracellular vesicles are lipid-bilayer delimited particles that are naturally secreted by all cells and have emerged as valuable biomarkers for a wide range of diseases. Efficient isolation of small extracellular vesicles while maintaining yield and purity is crucial to harvest their potential in diagnostic, prognostic, and therapeutic applications. Most conventional methods of isolation suffer from significant shortcomings, including low purity or yield, long duration, need for large sample volumes, specialized equipment, trained personnel, and high costs. To address some of these challenges, our group has reported a novel insulator-based dielectrophoretic device for rapid isolation of small extracellular vesicles from biofluids and cell culture media based on their size and dielectric properties. In this study, we report a comprehensive characterization of small extracellular vesicles isolated from cancer-patients’ biofluids at a twofold enrichment using the device. The three-fold characterization that was performed using conventional flow cytometry, advanced imaging flow cytometry, and microRNA sequencing indicated high yield and purity of the isolated small extracellular vesicles. The device thus offers an efficient platform for rapid isolation while maintaining biomolecular integrity.

Author response: Improved isolation of extracellular vesicles by removal of both free proteins and lipoproteins

Extracellular vesicles (EVs) can be released from many different cell types and detected in most, if not all, body fluids. EVs can participate in cell-to-cell communication by shuttling bioactive molecules such as RNA or protein from one cell to another. Most studies of EVs have been performed in cell culture models or in EVs isolated from body fluids. There is emerging interest in the isolation of EVs from tissues to study their contribution to physiological processes and how they are altered in disease. The isolation of EVs with sufficient yield from tissues is technically challenging because of the need for tissue dissociation without cellular damage. This method describes a procedure for the isolation of EVs from mouse liver tissue. The method involves a two-step process starting with in situ collagenase digestion followed by differential ultra-centrifugation. Tissue perfusion using collagenase provides an advantage over mechanical cutting or homogenization of liver tissue due to its increased yield of obtained EVs. The use of this two-step process to isolate EVs from the liver will be useful for the study of tissue EVs.

Extracellular vesicles (EVs) are a heterogeneous population of membrane vesicles released by cells in vitro and in vivo. Their omnipresence and significant role as carriers of biological information make them intriguing study objects, requiring reliable and repetitive protocols for their isolation. However, realizing their full potential is difficult as there are still many technical obstacles related to their research (like proper acquisition). This study presents a protocol for the isolation of small EVs (according to the MISEV 2018 nomenclature) from the culture supernatant of tumor cell lines based on differential centrifugation. The protocol includes guidelines on how to avoid contamination with endotoxins during the isolation of EVs and how to properly evaluate them. Endotoxin contamination of EVs can significantly hinder subsequent experiments or even mask their true biological effects. On the other hand, the overlooked presence of endotoxins may lead to incorrect conclusions. This is of particular importance when referring to cells of the immune system, including monocytes, because monocytes constitute a population that is especially sensitive to endotoxin residues. Therefore, it is highly recommended to screen EVs for endotoxin contamination, especially when working with endotoxin-sensitive cells such as monocytes, macrophages, myeloid-derived suppressor cells, or dendritic cells.

Although the isolation and counting of small extracellular vesicles (sEVs) are essential steps in sEV research, an integrated method with scalability and efficiency has not been developed. Here, we present a scalable and ready-to-use extracellular vesicle (EV) isolation and counting system (EVics) that simultaneously allows isolation and counting in one system. This novel system consists of (i) EVi, a simultaneous tandem tangential flow filtration (TFF)-based EV isolation component by applying two different pore-size TFF filters, and (ii) EVc, an EV counting component using light scattering that captures a large field-of-view (FOV). EVi efficiently isolated 50-200nm-size sEVs from 15µL to 2L samples, outperforming the current state-of-the-art devices in purity and speed. EVc with a large FOV efficiently counted isolated sEVs. EVics enabled early observations of sEV secretion in various cell lines and reduced the cost of evaluating the inhibitory effect of sEV inhibitors by 20-fold. Using EVics, sEVs concentrations and sEV PD-L1 were monitored in a 23-day cancer mouse model, and 160 clinical samples were prepared and successfully applied to diagnosis. These results demonstrate that EVics could become an innovative system for novel findings in basic and applied studies in sEV research.

The market offers a wide range of extracellular vesicles (EVs) isolation products, but their lack of standardization is a concern. Therefore, it is important to carefully assess the quality of the EVs obtained using these products to patent the ideal method. In this study, we compared the EXOCIB kit with the ultracentrifuge method, which is considered the gold standard for small EV isolation. After overnight fasting, small plasma EVs were extracted from four individuals using both the ultracentrifuge and the EXOCIB kit methods. The pooled EVs were then compared for the presence of the cluster of differentiation 63 (CD63) protein using the western blot analysis, and their size and zeta potential were performed by Dynamic Light Scattering (DLS). In addition, the size and morphology of small EVs were determined by using the Transmission Electron Microscopy (TEM) technique. An average hydrodynamic size of 135.7 nm and a zeta potential of -6.33 Mv at 25°C was found for small EVs isolated by the ultracentrifuge, whereas the kit method resulted in small EVs with a hydrodynamic size of 102.8 nm and a zeta potential of -0.907. Notably, the size of the particles in the kit samples was smaller compared to those obtained through the ultracentrifuge (P < 0.001). The western blot method confirmed the expression of CD63 in both methods, so the ultracentrifuge yielded small EVs with a higher level of purity compared to the kit-based approach (P = 0.036). The DLS findings revealed the existence of vesicles within the appropriate size range for small EVs like exosomes in both isolation techniques. The results of the western blot analysis, in conjunction with DLS, displayed that the ultracentrifuge method extracted small EVs with a greater degree of purity than the kit-based approach.

Objective: Extracellular vesicles (EVs) are cell-secreted membrane vesicles enclosed by a lipid bilayer derived from endosomes or from the plasma membrane. Since they are released into body fluids, and their cargo includes tissue-specific and disease-related molecules, EVs represent a rich source for disease biomarkers. However, standard ultracentrifugation methods for EV isolation (UC-EV) are laborious, time-consuming, and require high inputs. Method: A recently described isolation method, which can be performed at small ‘miniprep’ scale, utilizes specific Heat Shock Protein (HSP)-binding peptides to aggregate HSP-decorated EVs (Ghosh et al. (2014), PLoS ONE 9:e110443). The authors showed comparable results for their method (abbreviated HSP-EV here) and UC-EV, but a detailed proteomic comparison was lacking. Therefore, we compared both methods using label-free proteomics of replicate EV isolations from HT-29 cancer cell-conditioned medium. Subsequently we applied this technique on secretomes of fresh human colorectal cancer (CRC) (n=17) and colon adenoma (n=4) tissue as well as patient-matched normal colon tissue. Results: Despite a 30-fold different input scale (UC-EV: 60 ml versus HSP-EV: 2 ml), both methods yielded comparable numbers of identified proteins (3115 versus 3085), with reproducible identifications (72.5% versus 75.5%) and spectral count-based quantification (average CV 31% versus 27%). EVs obtained by either method contained established EV markers and proteins linked to vesicle-related gene ontologies. In the EV fraction of the tissue secretomes 6390 proteins were identified, of which 471 proteins were significantly 5-fold more present in CRC samples than in normal tissue EVs. Gene ontology analysis revealed enrichment of nuclear proteins involved in DNA damage response, chromosome organization and RNA processing in the CRC EVs. Conclusions: The HSP-EV method provides an advantageous, simple and rapid approach for EV isolation from small amounts of biological samples, enabling high-throughput analysis in a biomarker discovery setting. Citation Format: Meike De Wit, Jaco Knol, Inge de Reus, Tim Tim Schelfhorst, Logan Bishop-Currey, Nicole van Grieken, Sander Piersma, Thang V. Pham, Remond J. Fijneman, Gerrit A. Meijer, Henk Verheul, Connie R. Jimenez. Peptide-mediated 'miniprep' isolation of extracellular vesicles is suitable for high-throughput proteomics; method evaluation and application in colon cancer [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2017; 2017 Apr 1-5; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2017;77(13 Suppl):Abstract nr 2208. doi:10.1158/1538-7445.AM2017-2208

Extracellular vesicles (EVs) are membrane structures enclosed by a lipid bilayer that are released into the extracellular space by all types of cells. EVs are involved in many physiological processes by transporting biologically active substances. Interest in EVs for diagnostic biomarker research and therapeutic drug delivery applications has increased in recent years. The realization of the full therapeutic potential of EVs is currently hampered by the lack of a suitable technology for the isolation and purification of EVs for downstream pharmaceutical applications. Anion Exchange Chromatography (AEX) is an established method in which specific charges on the AEX matrix can exploit charges on the surface of EVs and their interactions to provide a productive and scalable separation and purification method. The established AEX method using Eshmuno® Q, a strong tentacle anion exchange resin, was used to demonstrate the principal feasibility of AEX-based isolation and gain insight into isolated EV properties. Using several EV analysis techniques to provide a more detailed insight into EV populations during AEX isolation, we demonstrated that although the composition of CD9/63/81 remained constant for tetraspanin positive EVs, the size distribution and purity changed during elution. Higher salt concentrations eluted larger tetraspanin negative vesicles.

Exosomes, a subset of extracellular vesicles (EVs) ranging in size from 30 to 150nm, are of significant interest for biomedical applications such as diagnostic testing and therapeutics delivery. Biofluids, including urine, blood, and saliva, contain exosomes that carry biomarkers reflective of their host cells. However, isolation of EVs is often a challenge due to their size range, low density, and high hydrophobicity. Isolations can involve long separation times (ultracentrifugation) or result in impure eluates (size exclusion chromatography, polymer-based precipitation). As an alternative to these methods, this study evaluates the first use of nylon-6 capillary-channeled polymer (C-CP) fiber columns to separate EVs from human urine via a step-gradient hydrophobic interaction chromatography method. Different from previous efforts using polyester fiber columns for EV separations, nylon-6 shows potential for increased isolation efficiency, including somewhat higher column loading capacity and more gentle EV elution solvent strength. The efficacy of this approach to EV separation has been determined by scanning electron and transmission microscopy, nanoparticle flow cytometry (NanoFCM), and Bradford protein assays. Electron microscopy showed isolated vesicles of the expected morphology. Nanoparticle flow cytometry determined particle densities of eluates yielding up to 5×108 particles mL-1, a typical distribution of vesicle sizes in the eluate (60-100nm), and immunoconfirmation using fluorescent anti-CD81 antibodies. Bradford assays confirmed that protein concentrations in the EV eluate were significantly reduced (approx. sevenfold) from raw urine. Overall, this approach provides a low-cost and time-efficient (<20min) column separation to yield urinary EVs of the high purities required for downstream applications, including diagnostic testing and therapeutics.

Regular protocols for the isolation of fungal extracellular vesicles (EVs) are time-consuming, hard to reproduce, and produce low yields. In an attempt to improve the protocols used for EV isolation, we explored a model of vesicle production after growth of Cryptococcus gattii and Cryptococcus neoformans on solid media. Nanoparticle tracking analysis in combination with transmission electron microscopy revealed that C. gattii and C. neoformans produced EVs in solid media. The properties of cryptococcal vesicles varied according to the culture medium used and the EV-producing species. EV detection was reproduced with an acapsular mutant of C. neoformans, as well as with isolates of Candida albicans, Histoplasma capsulatum, and Saccharomyces cerevisiae Cryptococcal EVs produced in solid media were biologically active and contained regular vesicular components, including the major polysaccharide glucuronoxylomannan (GXM) and RNA. Since the protocol had higher yields and was much faster than the regular methods used for the isolation of fungal EVs, we asked if it would be applicable to address fundamental questions related to cryptococcal secretion. On the basis that polysaccharide export in Cryptococcus requires highly organized membrane traffic culminating with EV release, we analyzed the participation of a putative scramblase (Aim25; CNBG_3981) in EV-mediated GXM export and capsule formation in C. gattii EVs from a C. gattiiaim25Δ strain differed from those obtained from wild-type (WT) cells in physical-chemical properties and cargo. In a model of surface coating of an acapsular cryptococcal strain with vesicular GXM, EVs obtained from the aim25Δ mutant were more efficiently used as a source of capsular polysaccharides. Lack of the Aim25 scramblase resulted in disorganized membranes and increased capsular dimensions. These results associate the description of a novel protocol for the isolation of fungal EVs with the identification of a previously unknown regulator of polysaccharide release.IMPORTANCE Extracellular vesicles (EVs) are fundamental components of the physiology of cells from all kingdoms. In pathogenic fungi, they participate in important mechanisms of transfer of antifungal resistance and virulence, as well as in immune stimulation and prion transmission. However, studies on the functions of fungal EVs are still limited by the lack of efficient methods for isolation of these compartments. In this study, we developed an alternative protocol for isolation of fungal EVs and demonstrated an application of this new methodology in the study of the physiology of the fungal pathogen Cryptococcus gattii Our results describe a fast and reliable method for the study of fungal EVs and reveal the participation of scramblase, a phospholipid-translocating enzyme, in secretory processes of C. gattii.

We developed a novel asymmetric depth filtration (DF) approach to isolate extracellular vesicles (EVs) from biological fluids that outperforms ultracentrifugation and size‐exclusion chromatography in purity and yield of isolated EVs. By these metrics, a single‐step DF matches or exceeds the performance of multistep protocols with dedicated purification procedures in the isolation of plasma EVs. We demonstrate the selective transit and capture of biological nanoparticles in asymmetric pores by size and elasticity, low surface binding to the filtration medium, and the ability to cleanse EVs held by the filter before their recovery with the reversed flow all contribute to the achieved purity and yield of preparations. We further demonstrate the method's versatility by applying it to isolate EVs from different biofluids (plasma, urine, and cell culture growth medium). The DF workflow is simple, fast, and inexpensive. Only standard laboratory equipment is required for its implementation, making DF suitable for low‐resource and point‐of‐use locations. The method may be used for EV isolation from small biological samples in diagnostic and treatment guidance applications. It can also be scaled up to harvest therapeutic EVs from large volumes of cell culture medium.