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Details	EV-TRACK ID	Experiment nr.	Species	Sample type	Separation protocol	First author	Year	EV-METRIC
	EV140147	1/3	Homo sapiens	Urine	(d)(U)C	Cheng L	2014	44%
Study summary Full title Characterization and deep sequencing analysis of exosomal and non-exosomal miRNA in human urine All authors Cheng L, Sun X, Scicluna BJ, Coleman BM, Hill AF Journal Kidney Int Abstract Micro RNAs (miRNAs) have been shown to circulate in biological fluids and are enclosed in vesicles s (show more...)Micro RNAs (miRNAs) have been shown to circulate in biological fluids and are enclosed in vesicles such as exosomes; they are present in urine and represent a noninvasive methodology to detect biomarkers for diagnostic testing. The low abundance of RNA in urine creates difficulties in its isolation, of which exosomal miRNA is a small fraction, making downstream RNA assays challenging. Here, we investigate methods to maximize exosomal isolation and RNA yield for next-generation deep sequencing. Upon characterizing exosomal proteins and total RNA content in urine, several commercially available kits were tested for their RNA extraction efficiency. We subsequently used the methods with the highest miRNA content to profile baseline miRNA expression using next-generation deep sequencing. Comparisons of miRNA profiles were also made with exosomes isolated by differential ultracentrifugation methodology and a commercially available column-based protocol. Overall, miRNAs were found to be significantly enriched and intact in urine-derived exosomes compared with cell-free urine. The presence of other noncoding RNAs such as small nuclear and small nucleolar RNA in the exosomes, in addition to coding sequences related to kidney and bladder conditions, was also detected. Our study extensively characterizes the RNA content of exosomes isolated from urine, providing the potential to identify miRNA biomarkers in human urine. (hide) EV-METRIC 44% (81st percentile of all experiments on the same sample type) Reported Not reported Not applicable EV-enriched proteins Protein analysis: analysis of three or more EV-enriched proteins non EV-enriched protein Protein analysis: assessment of a non-EV-enriched protein qualitative and quantitative analysis Particle analysis: implementation of both qualitative and quantitative methods. For the quantitative method, the reporting of measured EV concentration is expected. electron microscopy images Particle analysis: inclusion of a widefield and close-up electron microscopy image density gradient Separation method: density gradient, at least as validation of results attributed to EVs EV density Separation method: reporting of obtained EV density ultracentrifugation specifics Separation method: reporting of g-forces, duration and rotor type of ultracentrifugation steps antibody specifics Protein analysis: antibody clone/reference number and dilution lysate preparation Protein analysis: lysis buffer composition Study data Sample type Urine Sample origin NAY Focus vesicles exosomes Separation protocol Separation protocol Gives a short, non-chronological overview of the different steps of the separation protocol. dUC = (Differential) (ultra)centrifugation DG = density gradient UF = ultrafiltration SEC = size-exclusion chromatography IAF = immuno-affinity capture (d)(U)C Adj. k-factor 78.45 (pelleting) Protein markers EV: TSG101/ CD63/ Flotillin non-EV: Cell organelle protein Proteomics no Show all info Study aim Omics Sample Species Homo sapiens Sample Type Urine Separation Method (Differential) (ultra)centrifugation dUC: centrifugation steps Below or equal to 800 g Between 10,000 g and 50,000 g Equal to or above 150,000 g Pelleting performed Yes Pelleting: time(min) 65 Pelleting: rotor type 70Ti Pelleting: adjusted k-factor 78.45 Characterization: Protein analysis Western Blot Detected EV-associated proteins CD63/ TSG101/ Flotillin Detected contaminants Cell organelle protein ELISA Detected EV-associated proteins Flotillin Characterization: Particle analysis TRPS EM EM-type transmission EM Image type Wide-field

	EV140147	3/3	Homo sapiens	NAY	(d)(U)C Filtration	Cheng L	2014	22%
Study summary Full title Characterization and deep sequencing analysis of exosomal and non-exosomal miRNA in human urine All authors Cheng L, Sun X, Scicluna BJ, Coleman BM, Hill AF Journal Kidney Int Abstract Micro RNAs (miRNAs) have been shown to circulate in biological fluids and are enclosed in vesicles s (show more...)Micro RNAs (miRNAs) have been shown to circulate in biological fluids and are enclosed in vesicles such as exosomes; they are present in urine and represent a noninvasive methodology to detect biomarkers for diagnostic testing. The low abundance of RNA in urine creates difficulties in its isolation, of which exosomal miRNA is a small fraction, making downstream RNA assays challenging. Here, we investigate methods to maximize exosomal isolation and RNA yield for next-generation deep sequencing. Upon characterizing exosomal proteins and total RNA content in urine, several commercially available kits were tested for their RNA extraction efficiency. We subsequently used the methods with the highest miRNA content to profile baseline miRNA expression using next-generation deep sequencing. Comparisons of miRNA profiles were also made with exosomes isolated by differential ultracentrifugation methodology and a commercially available column-based protocol. Overall, miRNAs were found to be significantly enriched and intact in urine-derived exosomes compared with cell-free urine. The presence of other noncoding RNAs such as small nuclear and small nucleolar RNA in the exosomes, in addition to coding sequences related to kidney and bladder conditions, was also detected. Our study extensively characterizes the RNA content of exosomes isolated from urine, providing the potential to identify miRNA biomarkers in human urine. (hide) EV-METRIC 22% (58th percentile of all experiments on the same sample type) Reported Not reported Not applicable EV-enriched proteins Protein analysis: analysis of three or more EV-enriched proteins non EV-enriched protein Protein analysis: assessment of a non-EV-enriched protein qualitative and quantitative analysis Particle analysis: implementation of both qualitative and quantitative methods. For the quantitative method, the reporting of measured EV concentration is expected. electron microscopy images Particle analysis: inclusion of a widefield and close-up electron microscopy image density gradient Separation method: density gradient, at least as validation of results attributed to EVs EV density Separation method: reporting of obtained EV density ultracentrifugation specifics Separation method: reporting of g-forces, duration and rotor type of ultracentrifugation steps antibody specifics Protein analysis: antibody clone/reference number and dilution lysate preparation Protein analysis: lysis buffer composition Study data Sample type Cell culture supernatant Sample origin NAY Focus vesicles exosomes Separation protocol Separation protocol Gives a short, non-chronological overview of the different steps of the separation protocol. dUC = (Differential) (ultra)centrifugation DG = density gradient UF = ultrafiltration SEC = size-exclusion chromatography IAF = immuno-affinity capture (d)(U)C Filtration Protein markers EV: TSG101/ CD63/ Flotillin non-EV: Cell organelle protein Proteomics no Show all info Study aim Omics Sample Species Homo sapiens Sample Type Cell culture supernatant Separation Method (Differential) (ultra)centrifugation dUC: centrifugation steps Between 800 g and 10,000 g Between 10,000 g and 50,000 g Between 100,000 g and 150,000 g Pelleting performed Yes Pelleting: time(min) 60 Filtration steps 0.22µm or 0.2µm Characterization: Protein analysis Western Blot Detected EV-associated proteins CD63/ TSG101/ Flotillin Detected contaminants Cell organelle protein ELISA Detected EV-associated proteins Flotillin Characterization: Particle analysis None

	EV140147	2/3	Homo sapiens	Urine	Norgen Urine Exosome Isolation Kit	Cheng L	2014	0%
Study summary Full title Characterization and deep sequencing analysis of exosomal and non-exosomal miRNA in human urine All authors Cheng L, Sun X, Scicluna BJ, Coleman BM, Hill AF Journal Kidney Int Abstract Micro RNAs (miRNAs) have been shown to circulate in biological fluids and are enclosed in vesicles s (show more...)Micro RNAs (miRNAs) have been shown to circulate in biological fluids and are enclosed in vesicles such as exosomes; they are present in urine and represent a noninvasive methodology to detect biomarkers for diagnostic testing. The low abundance of RNA in urine creates difficulties in its isolation, of which exosomal miRNA is a small fraction, making downstream RNA assays challenging. Here, we investigate methods to maximize exosomal isolation and RNA yield for next-generation deep sequencing. Upon characterizing exosomal proteins and total RNA content in urine, several commercially available kits were tested for their RNA extraction efficiency. We subsequently used the methods with the highest miRNA content to profile baseline miRNA expression using next-generation deep sequencing. Comparisons of miRNA profiles were also made with exosomes isolated by differential ultracentrifugation methodology and a commercially available column-based protocol. Overall, miRNAs were found to be significantly enriched and intact in urine-derived exosomes compared with cell-free urine. The presence of other noncoding RNAs such as small nuclear and small nucleolar RNA in the exosomes, in addition to coding sequences related to kidney and bladder conditions, was also detected. Our study extensively characterizes the RNA content of exosomes isolated from urine, providing the potential to identify miRNA biomarkers in human urine. (hide) EV-METRIC 0% (median: 22% of all experiments on the same sample type) Reported Not reported Not applicable EV-enriched proteins Protein analysis: analysis of three or more EV-enriched proteins non EV-enriched protein Protein analysis: assessment of a non-EV-enriched protein qualitative and quantitative analysis Particle analysis: implementation of both qualitative and quantitative methods. For the quantitative method, the reporting of measured EV concentration is expected. electron microscopy images Particle analysis: inclusion of a widefield and close-up electron microscopy image density gradient Separation method: density gradient, at least as validation of results attributed to EVs EV density Separation method: reporting of obtained EV density ultracentrifugation specifics Separation method: reporting of g-forces, duration and rotor type of ultracentrifugation steps antibody specifics Protein analysis: antibody clone/reference number and dilution lysate preparation Protein analysis: lysis buffer composition Study data Sample type Urine Sample origin NAY Focus vesicles exosomes Separation protocol Separation protocol Gives a short, non-chronological overview of the different steps of the separation protocol. dUC = (Differential) (ultra)centrifugation DG = density gradient UF = ultrafiltration SEC = size-exclusion chromatography IAF = immuno-affinity capture Norgen Urine Exosome Isolation Kit Protein markers EV: non-EV: Proteomics no Show all info Study aim Omics Sample Species Homo sapiens Sample Type Urine Separation Method Commercial kit Norgen Urine Exosome Isolation Kit Other Name other separation method Norgen Urine Exosome Isolation Kit Characterization: Particle analysis None

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EV-TRACK ID	EV140147
species	Homo sapiens
sample type	Urine	Cell culture	Urine
cell type	NA	NAY	NA
condition	NAY	NAY	NAY
separation protocol	(d)(U)C	(d)(U)C Filtration	Norgen Urine Exosome Isolation Kit
Exp. nr.	1	3	2
EV-METRIC %	44	22	0