Studies involving sample source:Embryonic cells
| Study ID | Study Title | Species | Institute |
|---|---|---|---|
| ST001028 | Metabolic profiling of identified single cells in Xenopus laevis embryos | Frog | University of Maryland |
| ST001032 | Single-cell Profiling of Cationic and Anionic Metabolites in Live Frog (Xenopus) Embryos using Microprobe Capillary Electrophoresis Mass Spectrometry | Frog | University of Maryland |
| ST001898 | Evolution of diapause in the African killifish by remodeling ancient gene regulatory landscape | Red-striped killifish | Stanford University |
| ST001898 | Evolution of diapause in the African killifish by remodeling ancient gene regulatory landscape | Turquoise killifish | Stanford University |
| ST002778 | Cell Lineage-Guided Microanalytical Mass Spectrometry Reveals Increased Energy Metabolism and Reactive Oxygen Species in the Vertebrate Organizer | Frog | University of Maryland |
| ST002814 | Atlas of fetal metabolism during mid-to-late gestation and diabetic pregnancy | Mouse | University of California, Los Angeles |
| ST002878 | Atlas of fetal metabolism during mid-to-late gestation and diabetic pregnancy. Dynamic Labelling experiment. | Mouse | University of California, Los Angeles |
| ST003120 | Mannose is crucial for mesoderm specification and symmetry breaking in gastruloids. | Mouse | Dept of Genetics, University of Cambridge |
| ST003635 | Intracellular and supernatant metabolomes of ferroptotic Pfa1 cells using HPLC-MS/MS | Mouse | CECAD Research Center |
| ST003959 | Steady state levels of polar metabolites HEK293T, SDHBKO and UQCRC1KO compared to WT cells. | Human | University of Melbourne |
| ST003960 | Relative quantification of lactic acid secreted in media from cell lines treated with or without Antimycin A. | Human | University of Melbourne |
| ST003961 | Measuring carbon flux into TCA cycle using 13C5-glutamine tracer metabolomics | Human | University of Melbourne |
| ST003968 | Measuring TCA cycle directional fluxes using 13C6-glucose | Human | University of Melbourne |
| ST003976 | Glucose-activated JMJD1A drives visceral adipogenesis via α-ketoglutarate-dependent chromatin remodeling (Study part 6 of 1) | Mouse | Tohoku University |
| ST003977 | Glucose-activated JMJD1A drives visceral adipogenesis via α-ketoglutarate-dependent chromatin remodeling (Study part 6 of 2) | Mouse | Tohoku University |
| ST003978 | Glucose-activated JMJD1A drives visceral adipogenesis via α-ketoglutarate-dependent chromatin remodeling (Study part 6 of 3) | Mouse | Tohoku University |
| ST003979 | Glucose-activated JMJD1A drives visceral adipogenesis via α-ketoglutarate-dependent chromatin remodeling (Study part 6 of 4) | Mouse | Tohoku University |
| ST003985 | Glucose-activated JMJD1A drives visceral adipogenesis via α-ketoglutarate-dependent chromatin remodeling (Study part 6 of 5) | Mouse | Tohoku University |
| ST003987 | Glucose-activated JMJD1A drives visceral adipogenesis via α-ketoglutarate-dependent chromatin remodeling (Study part 6 of 6) | Mouse | Tohoku University |
