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1. Label-free ferrohydrodynamic separation of exosome-like nanoparticles

   https://doi.org/10.1039/d0lc00609b  

   Liu, Yang; Zhao, Wujun; Cheng, Rui; Logun, Meghan; Zayas-Viera, Maria del; Karumbaiah, Lohitash; Mao, Leidong (August 2020, Lab on a Chip)

   null (Ed.)

   Isolation of exosomes from biological samples provides a minimally-invasive alternative for basic understanding, diagnosis, and prognosis of metastatic cancers. The biology and clinical values of exosomes are under intensive investigation, yet most studies are limited by technical challenges in recovering these exosomes with heterogeneous sizes and cargos from biological samples. We report a novel method based on “particle ferrohydrodynamics” and its associated microfluidic device, termed as the FerroChip, which can separate exosome-like nanoparticles from microliters of cell culture media and human serum in a label-free, continuous-flow and size-dependent manner, and achieves a high recovery rate (94.3%) and a high purity (87.9%). Separated exosome-like nanoparticles had diameters, morphology, and protein expressions that were consistent with other reports. This method, upon further molecular characterization, could potentially facilitate basic understanding of exosomes and its clinical application in blood liquid biopsy. 

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2. Isolation of bovine milk–derived extracellular vesicles via a capillary-channeled polymer (C-CP) fiber stationary phase

   https://doi.org/10.1007/s00216-025-05824-0  

   Mata, Carolina; Pimentel, Jerisa_M; Huang, Kun; Stamatikos, Alexis; Marcus, R_Kenneth (March 2025, Analytical and Bioanalytical Chemistry)

   Abstract Extracellular vesicles (EVs) are released by all cell types into the extracellular environment. A subset of EVs, known as exosomes, range in size from 30 to 200 nm and are of biochemical interest due to their function as vehicles of intercellular communication. Their ability to transport proteinaceous species and genetic material at the cellular level makes them prime candidates as vectors in gene therapies. Focusing on biotherapeutics, bovine milk–derived extracellular vesicles (MDEVs) hold particular promise as an alternative to other exosome sources for therapeutics delivery. Bovine milk poses unique challenges due to the complex colloidal matrix, composed predominantly of fats and proteins like casein, which form micelles that exhibit exosome-like characteristics, specifically size and density. When faced with complex matrices like milk, conventional size/density-based isolation methods including ultracentrifugation and size exclusion chromatography struggle to provide high purity yields on practical time and cost scales. When paired with a stepwise hydrophobic interaction chromatography (HIC) gradient, polyester (PET) capillary-channeled polymer (C-CP) fibers in column and spin-down tips formats have been used effectively to isolate exosomes from highly diverse sources. Here, PET C-CP fiber columns are demonstrated to isolate MDEVs from pre-treated raw milk, yielding concentrations of 1.5 × 10¹⁰particles mL⁻¹with purities of ~2 × 10¹⁰EVs µg⁻¹protein in less than 20 min. The efficacy of the isolation process is verified by a suite of characterization methods. Implementing PET C-CP fiber columns for MDEV isolation addresses the challenges associated with conventional isolation methods, holding promise for scale-up towards therapeutic applications. 

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3. Towards nanovesicle-based disease diagnostics: a rapid single-step exosome assay within one hour through in situ immunomagnetic extraction and nanophotonic label-free detection

   https://doi.org/10.1039/D1LC00446H  

   Zhang, Qinming; Loghry, Hannah J.; Qian, Jingjing; Kimber, Michael J.; Dong, Liang; Lu, Meng (September 2021, Lab on a Chip)

   Exosomes have been considered as high-quality biomarkers for disease diagnosis, as they are secreted by cells into extracellular environments as nanovesicles with rich and unique molecular information, and can be isolated and enriched from clinical samples. However, most existing exosome assays, to date, require time-consuming isolation and purification procedures; the detection specificity and sensitivity are also in need of improvement for the realization of exosome-based disease diagnostics. This paper reports a unique exosome assay technology that enables completing both magnetic nanoparticle (MNP)-based exosome extraction and high-sensitivity photonic crystal (PC)-based label-free exosome detection in a single miniature vessel within one hour, while providing an improved sensitivity and selectivity. High specificity of the assay to membrane antigens is realized by functionalizing both the MNPs and the PC with specific antibodies. A low limit of detection on the order of 10 7 exosome particles per milliliter (volume) is achieved because the conjugated MNP–exosome nanocomplexes offer a larger index change on the PC surface, compared to the exosomes alone without using MNPs. Briefly, the single-step exosome assay involves (i) forming specific MNP–exosome nanocomplexes to enrich exosomes from complex samples directly on the PC surface at the bottom of the vessel, with a >500 enrichment factor, and (ii) subsequently, performing in situ quantification of the nanocomplexes using the PC biosensor. The present exosome assay method is validated in analyzing multiple membrane proteins of exosomes derived from murine macrophage cells with high selectivity and sensitivity, while requiring only about one hour. This assay technology will provide great potential for exosome-based disease diagnostics. 

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4. In-line coupling of capillary-channeled polymer fiber columns with optical absorbance and multi-angle light scattering detection for the isolation and characterization of exosomes

   https://doi.org/10.1007/s00216-024-05283-z  

   Wysor, Sarah_K; Marcus, R_Kenneth (April 2024, Analytical and Bioanalytical Chemistry)

   Abstract Extracellular vesicles (EVs) have garnered much interest due to their fundamental role in intracellular communication and their potential utility in clinical diagnostics and as biotherapeutic vectors. Of particular relevance is the subset of EVs referred to as exosomes, ranging in size from 30 to 150 nm, which contain incredible amounts of information about their cell of origin, which can be used to track the progress of disease. As a complementary action, exosomes can be engineered with therapeutic cargo to selectively target diseases. At present, the lack of highly efficient methods of isolation/purification of exosomes from diverse biofluids, plants, and cell cultures is a major bottleneck in the fundamental biochemistry, clinical analysis, and therapeutic applications. Equally impactful, the lack of effective in-line means of detection/characterization of isolate populations, including concentration and sizing, is limiting in the applications. The method presented here couples hydrophobic interaction chromatography (HIC) performed on polyester capillary-channeled polymer (C-CP) fiber columns followed by in-line optical absorbance and multi-angle light scattering (MALS) detection for the isolation and characterization of EVs, in this case present in the supernatant of Chinese hamster ovary (CHO) cell cultures. Excellent correlation was observed between the determined particle concentrations for the two detection methods. C-CP fiber columns provide a low-cost platform (< $5 per column) for the isolation of exosomes in a 15-min workflow, with complementary absorbance and MALS detection providing very high-quality particle concentration and sizing information. 

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5. Isolation of Urinary Extracellular Vesicles (EVs) via Hydrophobic Interaction Chromatography Using a Nylon‐6 Capillary‐Channeled Polymer (C‐CP) Fiber Column

   https://doi.org/10.1002/jssc.70093  

   Pons, William_F; Marcus, R_Kenneth (February 2025, Journal of Separation Science)

   ABSTRACT Exosomes, a subset of extracellular vesicles (EVs) ranging in size from 30 to 150 nm, 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 × 10⁸particles mL⁻¹, a typical distribution of vesicle sizes in the eluate (60–100 nm), 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 (< 20 min) column separation to yield urinary EVs of the high purities required for downstream applications, including diagnostic testing and therapeutics. 

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