List of Studies ( Metabolite:Ala-Ala-Ala)
| Study_id | Analysis_id | Study_title | Source | Species | Disease | Institute | Units(range) |
|---|---|---|---|---|---|---|---|
| ST001788 | AN002899 | β-Adrenergic regulation of metabolism in macrophages (part-IV) | Macrophages | Human | Monash University | Intensity | |
| ST000403 | AN000642 | Metabolomics-based elucidation of active metabolic pathways in erythrocytes and HSC-derived reticulocytes | Cells | Human | Monash Institute of Pharmaceutical Sciences, Monash University | Peak height | |
| ST002832 | AN004625 | Resource competition predicts assembly of in vitro gut bacterial communities- HILIC | Bacterial cells | Bacteroides fragilis | Stanford University | Peak height | |
| ST002832 | AN004625 | Resource competition predicts assembly of in vitro gut bacterial communities- HILIC | Bacterial cells | Bacteroides thetaiotaomicron | Stanford University | Peak height | |
| ST002832 | AN004625 | Resource competition predicts assembly of in vitro gut bacterial communities- HILIC | Bacterial cells | Bacteroides uniformis | Stanford University | Peak height | |
| ST002832 | AN004625 | Resource competition predicts assembly of in vitro gut bacterial communities- HILIC | Bacterial cells | Blautia producta | Stanford University | Peak height | |
| ST002832 | AN004625 | Resource competition predicts assembly of in vitro gut bacterial communities- HILIC | Bacterial cells | Clostridium clostridioforme | Stanford University | Peak height | |
| ST002832 | AN004625 | Resource competition predicts assembly of in vitro gut bacterial communities- HILIC | Bacterial cells | Clostridium hathewayi | Stanford University | Peak height | |
| ST002832 | AN004625 | Resource competition predicts assembly of in vitro gut bacterial communities- HILIC | Bacterial cells | Clostridium hylemonae | Stanford University | Peak height | |
| ST002832 | AN004625 | Resource competition predicts assembly of in vitro gut bacterial communities- HILIC | Bacterial cells | Clostridium scindens | Stanford University | Peak height | |
| ST002832 | AN004625 | Resource competition predicts assembly of in vitro gut bacterial communities- HILIC | Bacterial cells | Clostridium symbiosum | Stanford University | Peak height | |
| ST002832 | AN004625 | Resource competition predicts assembly of in vitro gut bacterial communities- HILIC | Bacterial cells | Enterococcus faecalis | Stanford University | Peak height | |
| ST002832 | AN004625 | Resource competition predicts assembly of in vitro gut bacterial communities- HILIC | Bacterial cells | Enterococcus faecium | Stanford University | Peak height | |
| ST002832 | AN004625 | Resource competition predicts assembly of in vitro gut bacterial communities- HILIC | Bacterial cells | Enterococcus hirae | Stanford University | Peak height | |
| ST002832 | AN004625 | Resource competition predicts assembly of in vitro gut bacterial communities- HILIC | Bacterial cells | Escherichia fergusonii | Stanford University | Peak height | |
| ST002832 | AN004625 | Resource competition predicts assembly of in vitro gut bacterial communities- HILIC | Bacterial cells | Flavonifractor plautii | Stanford University | Peak height | |
| ST002832 | AN004625 | Resource competition predicts assembly of in vitro gut bacterial communities- HILIC | Bacterial cells | Parabacteroides distasonis | Stanford University | Peak height | |
| ST002407 | AN003924 | Spatial, temporal, and inter-subject variation of the metabolome along the human upper intestinal tract | Intestine | Human | UC Davis | Peak Height | |
| ST001205 | AN002006 | Peroxide antimalarial treatment of K13-mutant and -wildtype P. falciparum parasites | Cultured cells | Human | Malaria | Monash University | Peak intensity |
| ST001205 | AN002006 | Peroxide antimalarial treatment of K13-mutant and -wildtype P. falciparum parasites | Cultured cells | Plasmodium falciparum | Malaria | Monash University | Peak intensity |
| ST001547 | AN002576 | β-Adrenergic regulation of metabolism in macrophages | Macrophages | Human | Monash University | Peak intensity | |
| ST001548 | AN002578 | β-Adrenergic regulation of metabolism in macrophages (part-II) | Macrophages | Human | Monash University | Peak intensity | |
| ST001549 | AN002580 | β-Adrenergic regulation of metabolism in macrophages (part-III) | Macrophages | Human | Monash University | Peak intensity | |
| ST002106 | AN003445 | Genetic and chemical validation of Plasmodium falciparum aminopeptidase PfA-M17 as a drug target in the hemoglobin digestion pathway (Part 1) | Blood | Plasmodium falciparum | Malaria | Monash University | relative intensity |
| ST002107 | AN003446 | Genetic and chemical validation of Plasmodium falciparum aminopeptidase PfA-M17 as a drug target in the hemoglobin digestion pathway (Part 2) | Blood | Plasmodium falciparum | Malaria | Monash University | relative intensity |
| ST002108 | AN003448 | Genetic and chemical validation of Plasmodium falciparum aminopeptidase PfA-M17 as a drug target in the hemoglobin digestion pathway (Part 3) | Blood | Plasmodium falciparum | Malaria | Monash University | relative intensity |
| ST002309 | AN003772 | Targeting malaria parasites with novel derivatives of azithromycin | Blood | Plasmodium falciparum | Malaria | Monash University | relative intensity |
| ST001304 | AN002172 | Multi-omics analysis delineates the distinct functions of sub-cellular acetyl-CoA pools in Toxoplasma gondii | Fibroblast cells | Toxoplasma gondii | Parasitic infection | Monash University | Signal Intensity |
| ST001315 | AN002190 | Retargeting azithromycin-like compounds as antimalarials with dual modality | Blood | Plasmodium falciparum | Malaria | Monash University | Signal Intensity |
