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Details	EV-TRACK ID	Experiment nr.	Species	Sample type	Separation protocol	First author	Year	EV-METRIC
	EV190084	1/2	Homo sapiens	Dental pulp stromal cells	(d)(U)C Filtration	Greet Merckx	2020	78%
Study summary Full title Angiogenic Effects of Human Dental Pulp and Bone Marrow-Derived Mesenchymal Stromal Cells and Their Extracellular Vesicles All authors Greet Merckx, Baharak Hosseinkhani, Sören Kuypers, Sarah Deville, Joy Irobi, Inge Nelissen, Luc Michiels, Ivo Lambrichts, Annelies Bronckaers Journal Cells Abstract Blood vessel formation or angiogenesis is a key process for successful tooth regeneration. Bone marr (show more...)Blood vessel formation or angiogenesis is a key process for successful tooth regeneration. Bone marrow-derived mesenchymal stromal cells (BM-MSCs) possess paracrine proangiogenic properties, which are, at least partially, induced by their extracellular vesicles (EVs). However, the isolation of BM-MSCs is associated with several drawbacks, which could be overcome by MSC-like cells of the teeth, called dental pulp stromal cells (DPSCs). This study aims to compare the angiogenic content and functions of DPSC and BM-MSC EVs and conditioned medium (CM). The angiogenic protein profile of DPSC- and BM-MSC-derived EVs, CM and EV-depleted CM was screened by an antibody array and confirmed by ELISA. Functional angiogenic effects were tested in transwell migration and chicken chorioallantoic membrane assays. All secretion fractions contained several pro- and anti-angiogenic proteins and induced in vitro endothelial cell motility. This chemotactic potential was higher for (EV-depleted) CM, compared to EVs with a stronger effect for BM-MSCs. Finally, BM-MSC CM, but not DPSC CM, nor EVs, increased in ovo angiogenesis. In conclusion, we showed that DPSCs are less potent in relation to endothelial cell chemotaxis and in ovo neovascularization, compared to BM-MSCs, which emphasizes the importance of choice of cell type and secretion fraction for stem cell-based regenerative therapies in inducing angiogenesis. (hide) EV-METRIC 78% (97th 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 Control condition Focus vesicles extracellular vesicle 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: CD9/ CD63/ ANXA2/ CD81 non-EV: Bax Proteomics no Show all info Study aim Function/Identification of content (omics approaches) Sample Species Homo sapiens Sample Type Cell culture supernatant EV-producing cells Dental pulp stromal cells EV-harvesting Medium Serum free medium Cell viability (%) 95 Separation Method (Differential) (ultra)centrifugation dUC: centrifugation steps Below or equal to 800 g Between 100,000 g and 150,000 g Pelleting performed Yes Pelleting: time(min) 180 Pelleting: rotor type Type 70 Ti Pelleting: speed (g) 100000 Filtration steps 0.22µm or 0.2µm Characterization: Protein analysis Protein Concentration Method BCA Western Blot Detected EV-associated proteins CD9/ CD63/ ANXA2/ CD81 Not detected contaminants Bax Characterization: Lipid analysis No EM EM-type Transmission-EM Image type Close-up, Wide-field

	EV190084	2/2	Homo sapiens	Bone marrow derived mesenchymal stromal cells	(d)(U)C Filtration	Greet Merckx	2020	78%
Study summary Full title Angiogenic Effects of Human Dental Pulp and Bone Marrow-Derived Mesenchymal Stromal Cells and Their Extracellular Vesicles All authors Greet Merckx, Baharak Hosseinkhani, Sören Kuypers, Sarah Deville, Joy Irobi, Inge Nelissen, Luc Michiels, Ivo Lambrichts, Annelies Bronckaers Journal Cells Abstract Blood vessel formation or angiogenesis is a key process for successful tooth regeneration. Bone marr (show more...)Blood vessel formation or angiogenesis is a key process for successful tooth regeneration. Bone marrow-derived mesenchymal stromal cells (BM-MSCs) possess paracrine proangiogenic properties, which are, at least partially, induced by their extracellular vesicles (EVs). However, the isolation of BM-MSCs is associated with several drawbacks, which could be overcome by MSC-like cells of the teeth, called dental pulp stromal cells (DPSCs). This study aims to compare the angiogenic content and functions of DPSC and BM-MSC EVs and conditioned medium (CM). The angiogenic protein profile of DPSC- and BM-MSC-derived EVs, CM and EV-depleted CM was screened by an antibody array and confirmed by ELISA. Functional angiogenic effects were tested in transwell migration and chicken chorioallantoic membrane assays. All secretion fractions contained several pro- and anti-angiogenic proteins and induced in vitro endothelial cell motility. This chemotactic potential was higher for (EV-depleted) CM, compared to EVs with a stronger effect for BM-MSCs. Finally, BM-MSC CM, but not DPSC CM, nor EVs, increased in ovo angiogenesis. In conclusion, we showed that DPSCs are less potent in relation to endothelial cell chemotaxis and in ovo neovascularization, compared to BM-MSCs, which emphasizes the importance of choice of cell type and secretion fraction for stem cell-based regenerative therapies in inducing angiogenesis. (hide) EV-METRIC 78% (97th 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 Control condition Focus vesicles extracellular vesicle 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: CD9/ CD63/ ANXA2/ CD81 non-EV: Bax Proteomics no Show all info Study aim Function/Identification of content (omics approaches) Sample Species Homo sapiens Sample Type Cell culture supernatant EV-producing cells Bone marrow derived mesenchymal stromal cells EV-harvesting Medium Serum free medium Cell viability (%) 95 Separation Method (Differential) (ultra)centrifugation dUC: centrifugation steps Below or equal to 800 g Between 100,000 g and 150,000 g Pelleting performed Yes Pelleting: time(min) 180 Pelleting: rotor type Type 70 Ti Pelleting: speed (g) 100000 Filtration steps 0.22µm or 0.2µm Characterization: Protein analysis Protein Concentration Method BCA Western Blot Detected EV-associated proteins CD9/ CD63/ ANXA2/ CD81 Not detected contaminants Bax Characterization: Lipid analysis No EM EM-type Transmission-EM Image type Close-up, Wide-field

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EV-TRACK ID	EV190084
species	Homo sapiens
sample type	Cell culture
cell type	Dental pulp stromal cells	Bone marrow derived mesenchymal stromal cells
condition	Control condition	Control condition
separation protocol	(d)(U)C Filtration	(d)(U)C Filtration
Exp. nr.	1	2
EV-METRIC %	78	78