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Chemical Dietary Carbohydrates

1–50 of 233 results.
  Chemical Phenotype Co-Mentioned Terms Interaction Organisms Anatomy Inference Network References
1. 2-Hydroxypropyl-beta-cyclodextrin regulation of ATP metabolic process Phenylpropanolamine 2-Hydroxypropyl-beta-cyclodextrin inhibits the reaction [Phenylpropanolamine affects regulation of ATP metabolic process] 1: Homo sapiens Neural Stem Cells | Cell Line, Tumor   1
2. 2-Hydroxypropyl-beta-cyclodextrin micturition 2-Hydroxypropyl-beta-cyclodextrin results in decreased micturition 1: Rattus norvegicus     1
3. 2-Hydroxypropyl-beta-cyclodextrin positive regulation of cholesterol efflux 2-Hydroxypropyl-beta-cyclodextrin results in increased positive regulation of cholesterol efflux 1: Homo sapiens Neural Stem Cells | Cell Line, Tumor
2 genes: ABCA1 | NR1H3
1
4. 2-Hydroxypropyl-beta-cyclodextrin positive regulation of necroptotic process Phenylpropanolamine 2-Hydroxypropyl-beta-cyclodextrin inhibits the reaction [Phenylpropanolamine results in increased positive regulation of necroptotic process] 1: Homo sapiens Neural Stem Cells | Cell Line, Tumor   1
5. 2-Hydroxypropyl-beta-cyclodextrin L-aspartate:2-oxoglutarate aminotransferase activity 2-Hydroxypropyl-beta-cyclodextrin results in increased L-aspartate:2-oxoglutarate aminotransferase activity 1: Rattus norvegicus Plasma   1
6. 2-Hydroxypropyl-beta-cyclodextrin glutamate dehydrogenase (NADP+) activity 2-Hydroxypropyl-beta-cyclodextrin results in increased glutamate dehydrogenase (NADP+) activity 1: Rattus norvegicus Plasma   1
7. 2-Hydroxypropyl-beta-cyclodextrin positive regulation of cholesterol efflux 24-hydroxycholesterol [2-Hydroxypropyl-beta-cyclodextrin results in increased positive regulation of cholesterol efflux] which results in increased secretion of 24-hydroxycholesterol 1: Homo sapiens Neural Stem Cells | Cell Line, Tumor
2 genes: ABCA1 | NR1H3
1
8. 2-Hydroxypropyl-beta-cyclodextrin cholesterol transport involved in cholesterol storage Phenylpropanolamine 2-Hydroxypropyl-beta-cyclodextrin inhibits the reaction [Phenylpropanolamine results in increased cholesterol transport involved in cholesterol storage] 1: Homo sapiens Neural Stem Cells | Cell Line, Tumor   1
9. 2-Hydroxypropyl-beta-cyclodextrin regulation of ATP metabolic process Adenosine Triphosphate | Phenylpropanolamine 2-Hydroxypropyl-beta-cyclodextrin inhibits the reaction [[Phenylpropanolamine affects regulation of ATP metabolic process] which results in decreased abundance of Adenosine Triphosphate] 1: Homo sapiens Neural Stem Cells | Cell Line, Tumor   1
10. beta-Cyclodextrins sensory perception of pain carvacrol beta-Cyclodextrins promotes the reaction [carvacrol results in decreased sensory perception of pain] 1: Mus musculus Foot   1
11. beta-Cyclodextrins response to toxic substance beta-Cyclodextrins affects response to toxic substance     2
12. betadex reactive oxygen species biosynthetic process Quercetin | tert-Butylhydroperoxide betadex affects the reaction [Quercetin inhibits the reaction [tert-Butylhydroperoxide results in increased reactive oxygen species biosynthetic process]] 1: Oryctolagus cuniculus Erythrocytes   1
13. betadex lipid catabolic process Quercetin | tert-Butylhydroperoxide betadex affects the reaction [Quercetin inhibits the reaction [tert-Butylhydroperoxide results in increased lipid catabolic process]] 1: Oryctolagus cuniculus Erythrocytes   1
14. betadex cholesterol biosynthetic process betadex results in decreased cholesterol biosynthetic process 1: Oryctolagus cuniculus Erythrocytes   1
15. betadex reactive oxygen species biosynthetic process Rutin | tert-Butylhydroperoxide betadex affects the reaction [Rutin inhibits the reaction [tert-Butylhydroperoxide results in increased reactive oxygen species biosynthetic process]] 1: Oryctolagus cuniculus Erythrocytes   1
16. betadex lipid catabolic process Rutin | tert-Butylhydroperoxide betadex affects the reaction [Rutin inhibits the reaction [tert-Butylhydroperoxide results in increased lipid catabolic process]] 1: Oryctolagus cuniculus Erythrocytes   1
17. Dietary Carbohydrates triglyceride homeostasis resveratrol resveratrol inhibits the reaction [Dietary Carbohydrates affects triglyceride homeostasis] 1: Rattus norvegicus Plasma
4 genes: LIPC | LPL | PPARG | SCARB1
1
18. Dietary Carbohydrates glucose homeostasis Dietary Carbohydrates affects glucose homeostasis 1: Rattus norvegicus Plasma
14 genes: ADIPOQ | CD36 | CNR1 | FABP5 | IGFBP5 | IL6 | INS | INSR | IRS1 | LEP | PCK1 | PPARG | PYGL | TCF7L2
1
19. Dietary Carbohydrates cholesterol homeostasis resveratrol resveratrol inhibits the reaction [Dietary Carbohydrates affects cholesterol homeostasis] 1: Rattus norvegicus Plasma
3 genes: LIPC | LPL | SCARB1
1
20. Dietary Carbohydrates glutathione peroxidase activity Dietary Fats | rosiglitazone | Streptozocin rosiglitazone affects the reaction [[Streptozocin co-treated with Dietary Carbohydrates co-treated with Dietary Fats] affects glutathione peroxidase activity] 1: Rattus norvegicus Liver 1 gene: PRDX6 1
21. Dietary Carbohydrates artery smooth muscle contraction EDN1 | resveratrol resveratrol inhibits the reaction [Dietary Carbohydrates promotes the reaction [EDN1 protein results in increased artery smooth muscle contraction]] 1: Rattus norvegicus Aorta, Thoracic 1 gene: EDN1 1
22. Dietary Carbohydrates vasodilation Dietary Fats | Nitroprusside | Quercetin Quercetin promotes the reaction [[Dietary Fats co-treated with Dietary Carbohydrates] inhibits the reaction [Nitroprusside results in increased vasodilation]] 1: Rattus norvegicus Aorta, Thoracic 1 gene: NOS3 1
23. Dietary Carbohydrates cholesterol biosynthetic process Dietary Fats [Dietary Carbohydrates co-treated with Dietary Fats] results in increased cholesterol biosynthetic process 1: Rattus norvegicus Plasma 1 gene: FDFT1 1
24. Dietary Carbohydrates urea homeostasis Dietary Fats | Quercetin Quercetin affects the reaction [[Dietary Carbohydrates co-treated with Dietary Fats] affects urea homeostasis] 1: Rattus norvegicus Plasma   1
25. Dietary Carbohydrates negative regulation of catalase activity sodium arsenite Dietary Carbohydrates inhibits the reaction [sodium arsenite affects negative regulation of catalase activity] 1: Rattus norvegicus Lung   1
26. Dietary Carbohydrates relaxation of vascular smooth muscle Acetylcholine | resveratrol resveratrol inhibits the reaction [Dietary Carbohydrates inhibits the reaction [Acetylcholine results in increased relaxation of vascular smooth muscle]] 1: Rattus norvegicus Aorta, Thoracic   1
27. Dietary Carbohydrates membrane lipid catabolic process sodium arsenite Dietary Carbohydrates inhibits the reaction [sodium arsenite results in increased membrane lipid catabolic process] 1: Rattus norvegicus Heart 1 gene: CYP1B1 1
28. Dietary Carbohydrates glutathione biosynthetic process Dietary Fats | rosiglitazone | Streptozocin rosiglitazone affects the reaction [[Streptozocin co-treated with Dietary Carbohydrates co-treated with Dietary Fats] affects glutathione biosynthetic process] 1: Rattus norvegicus Liver 1 gene: CNDP2 1
29. Dietary Carbohydrates lead ion transport Lead [Dietary Carbohydrates results in decreased lead ion transport] which results in decreased abundance of Lead 1: Homo sapiens Blood   1
30. Dietary Carbohydrates membrane lipid catabolic process sodium arsenite Dietary Carbohydrates inhibits the reaction [sodium arsenite results in increased membrane lipid catabolic process] 1: Rattus norvegicus Lung 1 gene: CYP1B1 1
31. Dietary Carbohydrates lactate dehydrogenase activity Dietary Fats | Quercetin Quercetin inhibits the reaction [[Dietary Carbohydrates co-treated with Dietary Fats] results in increased lactate dehydrogenase activity] 1: Rattus norvegicus Plasma 1 gene: LDHB 1
32. Dietary Carbohydrates negative regulation of catalase activity sodium arsenite Dietary Carbohydrates inhibits the reaction [sodium arsenite affects negative regulation of catalase activity] 1: Rattus norvegicus Kidney   1
33. Dietary Carbohydrates superoxide dismutase activity Dietary Fats | rosiglitazone | Streptozocin rosiglitazone affects the reaction [[Streptozocin co-treated with Dietary Carbohydrates co-treated with Dietary Fats] affects superoxide dismutase activity] 1: Rattus norvegicus Serum   1
34. Dietary Carbohydrates inflammatory response Dietary Fats [Dietary Fats co-treated with Dietary Carbohydrates] results in increased inflammatory response 1: Mus musculus Adipocytes
15 genes: BLNK | CD14 | CXCL8 | IL10 | IL1B | IL1RN | IL6 | NCF1 | NFE2L2 | NOS2 | PPARG | PRKCQ | SGK1 | TNF | TNFRSF1A
1
35. Dietary Carbohydrates response to insulin resveratrol resveratrol inhibits the reaction [Dietary Carbohydrates results in decreased response to insulin] 1: Rattus norvegicus Aorta, Thoracic
11 genes: ACACA | CAT | IL10 | IL6 | INSR | IRS1 | LEP | PCK1 | PRKCQ | SOCS3 | SREBF1
1
36. Dietary Carbohydrates lipid homeostasis Amino Acids, Peptides, and Proteins [Dietary Carbohydrates deficiency co-treated with Amino Acids, Peptides, and Proteins] results in decreased lipid homeostasis 1: Mus musculus Plasma
2 genes: ACACA | PPARG
1
37. Dietary Carbohydrates glutathione peroxidase activity Berberine | Dietary Fats | Streptozocin Berberine affects the reaction [[Streptozocin co-treated with Dietary Carbohydrates co-treated with Dietary Fats] affects glutathione peroxidase activity] 1: Rattus norvegicus Serum 1 gene: PRDX6 1
38. Dietary Carbohydrates superoxide dismutase activity Dietary Fats | rosiglitazone | Streptozocin rosiglitazone affects the reaction [[Streptozocin co-treated with Dietary Carbohydrates co-treated with Dietary Fats] affects superoxide dismutase activity] 1: Rattus norvegicus Liver   1
39. Dietary Carbohydrates negative regulation of glutathione peroxidase activity sodium arsenite Dietary Carbohydrates inhibits the reaction [sodium arsenite affects negative regulation of glutathione peroxidase activity] 1: Rattus norvegicus Heart   1
40. Dietary Carbohydrates divalent metal ion transport Mercury [Dietary Carbohydrates results in decreased divalent metal ion transport] which results in decreased abundance of Mercury 1: Homo sapiens Blood   1
41. Dietary Carbohydrates leukocyte migration involved in inflammatory response Dietary Fats | Quercetin Quercetin inhibits the reaction [[Dietary Carbohydrates co-treated with Dietary Fats] results in increased leukocyte migration involved in inflammatory response] 1: Rattus norvegicus Heart Ventricles   1
42. Dietary Carbohydrates superoxide dismutase activity Dietary Fats | Streptozocin [Streptozocin co-treated with Dietary Carbohydrates co-treated with Dietary Fats] affects superoxide dismutase activity 1: Rattus norvegicus Liver   1
43. Dietary Carbohydrates superoxide dismutase activity Dietary Fats | Streptozocin [Streptozocin co-treated with Dietary Carbohydrates co-treated with Dietary Fats] affects superoxide dismutase activity 1: Rattus norvegicus Serum   1
44. Dietary Carbohydrates alkaline phosphatase activity Dietary Fats [Dietary Carbohydrates co-treated with Dietary Fats] results in increased alkaline phosphatase activity 1: Rattus norvegicus Plasma   1
45. Dietary Carbohydrates vasodilation Dietary Fats | Nitroprusside [Dietary Fats co-treated with Dietary Carbohydrates] inhibits the reaction [Nitroprusside results in increased vasodilation] 1: Rattus norvegicus Aorta, Thoracic 1 gene: NOS3 1
46. Dietary Carbohydrates artery smooth muscle contraction EDN1 Dietary Carbohydrates promotes the reaction [EDN1 protein results in increased artery smooth muscle contraction] 1: Rattus norvegicus Aorta, Thoracic 1 gene: EDN1 1
47. Dietary Carbohydrates urea homeostasis Dietary Fats [Dietary Carbohydrates co-treated with Dietary Fats] affects urea homeostasis 1: Rattus norvegicus Plasma   1
48. Dietary Carbohydrates cholesterol homeostasis Dietary Carbohydrates affects cholesterol homeostasis 1: Rattus norvegicus Plasma
3 genes: LIPC | LPL | SCARB1
1
49. Dietary Carbohydrates lipid homeostasis Amino Acids, Peptides, and Proteins | Cholesterol [[Dietary Carbohydrates deficiency co-treated with Amino Acids, Peptides, and Proteins] results in decreased lipid homeostasis] which results in increased abundance of Cholesterol 1: Mus musculus Plasma
2 genes: ACACA | PPARG
1
50. Dietary Carbohydrates divalent metal ion transport Dietary Carbohydrates results in decreased divalent metal ion transport 1: Homo sapiens Blood   1
1–50 of 233 results.