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Chemical Sugars

1–50 of 2,390 results.
  Chemical Phenotype Co-Mentioned Terms Interaction Organisms Anatomy Inference Network References
1. 6,6'-bis(2,3-dimethoxybenzoyl)-alpha,alpha-trehalose cell migration 6,6'-bis(2,3-dimethoxybenzoyl)-alpha,alpha-trehalose analog results in decreased cell migration 1: Mus musculus Skin | Cell Line, Tumor
2 genes: GSK3B | VEGFA
1
2. baicalein-7-O-diglucoside response to endoplasmic reticulum stress baicalein-7-O-diglucoside results in increased response to endoplasmic reticulum stress 1: Homo sapiens B-Lymphocytes | Cell Line, Tumor
2 genes: DDIT3 | HSPA5
1
3. baicalein-7-O-diglucoside positive regulation of p38MAPK cascade baicalein-7-O-diglucoside results in increased positive regulation of p38MAPK cascade 1: Homo sapiens B-Lymphocytes | Cell Line, Tumor   1
4. baicalein-7-O-diglucoside positive regulation of apoptotic process baicalein-7-O-diglucoside results in increased positive regulation of apoptotic process 1: Homo sapiens B-Lymphocytes | Cell Line, Tumor
2 genes: ATF6 | DDIT3
1
5. baicalein-7-O-diglucoside positive regulation of cell proliferation baicalein-7-O-diglucoside results in decreased positive regulation of cell proliferation 1: Homo sapiens Cell Line, Tumor   1
6. baicalein-7-O-diglucoside positive regulation of p38MAPK cascade SB 203580 SB 203580 inhibits the reaction [baicalein-7-O-diglucoside results in increased positive regulation of p38MAPK cascade] 1: Homo sapiens B-Lymphocytes | Cell Line, Tumor   1
7. baicalein-7-O-diglucoside positive regulation of apoptotic process SB 203580 SB 203580 inhibits the reaction [baicalein-7-O-diglucoside results in increased positive regulation of apoptotic process] 1: Homo sapiens B-Lymphocytes | Cell Line, Tumor
2 genes: ATF6 | DDIT3
1
8. beta-D-glucosylisophosphoramide mustard cell proliferation beta-D-glucosylisophosphoramide mustard results in decreased cell proliferation 1: Homo sapiens Pancreas | Cell Line, Tumor   1
9. beta-D-glucosylisophosphoramide mustard apoptotic process beta-D-glucosylisophosphoramide mustard results in increased apoptotic process 1: Homo sapiens Pancreas | Cell Line, Tumor   1
10. beta-D-glucosylisophosphoramide mustard apoptotic DNA fragmentation beta-D-glucosylisophosphoramide mustard results in increased apoptotic DNA fragmentation 1: Homo sapiens Pancreas | Cell Line, Tumor   1
11. Blood Glucose cell death Blood Glucose results in increased cell death 1: Rattus norvegicus CA1 Region, Hippocampal 1 gene: HMOX1 1
12. Blood Glucose cell death Blood Glucose results in increased cell death 1: Rattus norvegicus CA3 Region, Hippocampal 1 gene: HMOX1 1
13. Blood Glucose cell death Blood Glucose results in increased cell death 1: Rattus norvegicus Dentate Gyrus 1 gene: HMOX1 1
14. Blood Glucose protein nitrosylation Blood Glucose results in increased protein nitrosylation 1: Mus musculus Embryo, Mammalian | Tissues   1
15. Blood Glucose protein nitrosylation SOD1 SOD1 protein inhibits the reaction [Blood Glucose results in increased protein nitrosylation] 1: Homo sapiens Embryo, Mammalian | Tissues   1
16. Blood Glucose glucose homeostasis Arsenic | Lead [[Arsenic co-treated with Lead] results in decreased glucose homeostasis] which results in increased abundance of Blood Glucose 1: Rattus norvegicus Blood
6 genes: AKT2 | IL6 | INS | LEPR | MTNR1B | PPARG
1
17. Blood Glucose glucose homeostasis cypermethrin [cypermethrin affects glucose homeostasis] which results in increased abundance of Blood Glucose 1: Oreochromis niloticus Serum
6 genes: AKT2 | IL6 | INS | LEPR | MTNR1B | PPARG
1
18. Blood Glucose glucose homeostasis Copper Sulfate [Copper Sulfate affects glucose homeostasis] which results in increased abundance of Blood Glucose 1: Oreochromis niloticus Serum
6 genes: AKT2 | IL6 | INS | LEPR | MTNR1B | PPARG
1
19. Blood Glucose glucose homeostasis lead nitrate [lead nitrate affects glucose homeostasis] which results in increased abundance of Blood Glucose 1: Oreochromis niloticus Serum
6 genes: AKT2 | IL6 | INS | LEPR | MTNR1B | PPARG
1
20. Blood Glucose glucose homeostasis Dietary Fats [Dietary Fats results in decreased glucose homeostasis] which results in increased abundance of Blood Glucose 2: Mus musculus | Rattus norvegicus Serum
6 genes: AKT2 | IL6 | INS | LEPR | MTNR1B | PPARG
4
21. Blood Glucose glucose homeostasis cobaltiprotoporphyrin | Dietary Fats cobaltiprotoporphyrin inhibits the reaction [[Dietary Fats results in decreased glucose homeostasis] which results in increased abundance of Blood Glucose] 1: Rattus norvegicus Serum
6 genes: AKT2 | IL6 | INS | LEPR | MTNR1B | PPARG
1
22. Blood Glucose glucose homeostasis cobaltiprotoporphyrin | Dietary Fats | tin protoporphyrin IX tin protoporphyrin IX inhibits the reaction [cobaltiprotoporphyrin inhibits the reaction [[Dietary Fats results in decreased glucose homeostasis] which results in increased abundance of Blood Glucose]] 1: Rattus norvegicus Serum
6 genes: AKT2 | IL6 | INS | LEPR | MTNR1B | PPARG
1
23. Blood Glucose glucose homeostasis Panax notoginseng extract [Panax notoginseng extract results in increased glucose homeostasis] which results in decreased abundance of Blood Glucose 1: Mus musculus Blood
6 genes: AKT2 | IL6 | INS | LEPR | MTNR1B | PPARG
1
24. Blood Glucose glucose homeostasis ginsenoside Rb1 [ginsenoside Rb1 results in increased glucose homeostasis] which results in decreased abundance of Blood Glucose 1: Mus musculus Blood
6 genes: AKT2 | IL6 | INS | LEPR | MTNR1B | PPARG
1
25. Blood Glucose glucose homeostasis diethyl phthalate [diethyl phthalate results in decreased glucose homeostasis] which results in decreased abundance of Blood Glucose 1: Danio rerio Serum
6 genes: AKT2 | IL6 | INS | LEPR | MTNR1B | PPARG
1
26. Blood Glucose regulation of gluconeogenesis 3,4,5,3',4'-pentachlorobiphenyl [3,4,5,3',4'-pentachlorobiphenyl affects regulation of gluconeogenesis] which results in decreased abundance of Blood Glucose 1: Rattus norvegicus Liver 1 gene: NR3C1 1
27. Blood Glucose positive regulation of glucose import in response to insulin stimulus acipimox [acipimox results in decreased positive regulation of glucose import in response to insulin stimulus] which results in increased abundance of Blood Glucose 1: Homo sapiens Blood
3 genes: AKT2 | INS | RARRES2
1
28. Blood Glucose glucose homeostasis Choline | Methionine [[Choline deficiency co-treated with Methionine deficiency] affects glucose homeostasis] which results in decreased abundance of Blood Glucose 1: Mus musculus Serum
6 genes: AKT2 | IL6 | INS | LEPR | MTNR1B | PPARG
1
29. Blood Glucose glucose homeostasis Choline | Methionine Methionine inhibits the reaction [[[Choline deficiency co-treated with Methionine deficiency] affects glucose homeostasis] which results in decreased abundance of Blood Glucose] 1: Mus musculus Serum
6 genes: AKT2 | IL6 | INS | LEPR | MTNR1B | PPARG
1
30. Blood Glucose glucose homeostasis Methionine [Methionine deficiency affects glucose homeostasis] which results in decreased abundance of Blood Glucose 1: Mus musculus Serum
6 genes: AKT2 | IL6 | INS | LEPR | MTNR1B | PPARG
1
31. Blood Glucose positive regulation of insulin secretion involved in cellular response to glucose stimulus Blood Glucose results in increased positive regulation of insulin secretion involved in cellular response to glucose stimulus 1: Rattus norvegicus Pancreas
4 genes: GCG | LEPR | PRKN | SIRT1
1
32. Blood Glucose positive regulation of insulin secretion involved in cellular response to glucose stimulus Serotonin Serotonin inhibits the reaction [Blood Glucose results in increased positive regulation of insulin secretion involved in cellular response to glucose stimulus] 1: Rattus norvegicus Pancreas
4 genes: GCG | LEPR | PRKN | SIRT1
1
33. Blood Glucose positive regulation of insulin secretion involved in cellular response to glucose stimulus sarpogrelate | Serotonin sarpogrelate inhibits the reaction [Serotonin inhibits the reaction [Blood Glucose results in increased positive regulation of insulin secretion involved in cellular response to glucose stimulus]] 1: Rattus norvegicus Pancreas
4 genes: GCG | LEPR | PRKN | SIRT1
1
34. Blood Glucose lipid oxidation Ethanol | Oxygen Ethanol promotes the reaction [[[Oxygen deficiency co-treated with Blood Glucose deficiency] co-treated with [Oxygen co-treated with Blood Glucose]] results in increased lipid oxidation] 1: Rattus norvegicus Liver   1
35. Blood Glucose lipid oxidation Ethanol | Malondialdehyde | Oxygen Ethanol promotes the reaction [[[[Oxygen deficiency co-treated with Blood Glucose deficiency] co-treated with [Oxygen co-treated with Blood Glucose]] results in increased lipid oxidation] which results in increased abundance of Malondialdehyde] 1: Rattus norvegicus Liver   1
36. Blood Glucose lipid oxidation Oxygen [[Oxygen deficiency co-treated with Blood Glucose deficiency] co-treated with [Oxygen co-treated with Blood Glucose]] results in increased lipid oxidation 1: Rattus norvegicus Liver   1
37. Blood Glucose lipid oxidation Malondialdehyde | Oxygen [[[Oxygen deficiency co-treated with Blood Glucose deficiency] co-treated with [Oxygen co-treated with Blood Glucose]] results in increased lipid oxidation] which results in increased abundance of Malondialdehyde 1: Rattus norvegicus Liver   1
38. Blood Glucose glutathione metabolic process Ethanol | Oxygen Ethanol promotes the reaction [[[Oxygen deficiency co-treated with Blood Glucose deficiency] co-treated with [Oxygen co-treated with Blood Glucose]] affects glutathione metabolic process] 1: Rattus norvegicus Liver
4 genes: GSR | SLC7A11 | SOD1 | SOD2
1
39. Blood Glucose glutathione metabolic process Ethanol | Glutathione | Oxygen Ethanol promotes the reaction [[[[Oxygen deficiency co-treated with Blood Glucose deficiency] co-treated with [Oxygen co-treated with Blood Glucose]] affects glutathione metabolic process] which results in decreased abundance of Glutathione] 1: Rattus norvegicus Liver
4 genes: GSR | SLC7A11 | SOD1 | SOD2
1
40. Blood Glucose glutathione metabolic process Oxygen [[Oxygen deficiency co-treated with Blood Glucose deficiency] co-treated with [Oxygen co-treated with Blood Glucose]] affects glutathione metabolic process 1: Rattus norvegicus Liver
4 genes: GSR | SLC7A11 | SOD1 | SOD2
1
41. Blood Glucose glutathione metabolic process Glutathione | Oxygen [[[Oxygen deficiency co-treated with Blood Glucose deficiency] co-treated with [Oxygen co-treated with Blood Glucose]] affects glutathione metabolic process] which results in decreased abundance of Glutathione 1: Rattus norvegicus Liver
4 genes: GSR | SLC7A11 | SOD1 | SOD2
1
42. Blood Glucose lipid oxidation Hemin | Oxygen [[[Oxygen deficiency co-treated with Blood Glucose deficiency] co-treated with [Oxygen co-treated with Blood Glucose]] co-treated with Hemin] results in increased lipid oxidation 1: Rattus norvegicus Liver   1
43. Blood Glucose lipid oxidation Hemin | Malondialdehyde | Oxygen [[[[Oxygen deficiency co-treated with Blood Glucose deficiency] co-treated with [Oxygen co-treated with Blood Glucose]] co-treated with Hemin] results in increased lipid oxidation] which results in increased abundance of Malondialdehyde 1: Rattus norvegicus Liver   1
44. Blood Glucose lipid oxidation Ethanol | Hemin | Oxygen Hemin inhibits the reaction [[[[Oxygen deficiency co-treated with Blood Glucose deficiency] co-treated with [Oxygen co-treated with Blood Glucose]] co-treated with Ethanol] results in increased lipid oxidation] 1: Rattus norvegicus Liver   1
45. Blood Glucose lipid oxidation Ethanol | Hemin | Malondialdehyde | Oxygen Hemin inhibits the reaction [[[[[Oxygen deficiency co-treated with Blood Glucose deficiency] co-treated with [Oxygen co-treated with Blood Glucose]] co-treated with Ethanol] results in increased lipid oxidation] which results in increased abundance of Malondialdehyde] 1: Rattus norvegicus Liver   1
46. Blood Glucose glutathione metabolic process Ethanol | Hemin | Oxygen Hemin inhibits the reaction [[[[Oxygen deficiency co-treated with Blood Glucose deficiency] co-treated with [Oxygen co-treated with Blood Glucose]] co-treated with Ethanol] affects glutathione metabolic process] 1: Rattus norvegicus Liver
4 genes: GSR | SLC7A11 | SOD1 | SOD2
1
47. Blood Glucose glutathione metabolic process Ethanol | Glutathione | Hemin | Oxygen Hemin inhibits the reaction [[[[[Oxygen deficiency co-treated with Blood Glucose deficiency] co-treated with [Oxygen co-treated with Blood Glucose]] co-treated with Ethanol] affects glutathione metabolic process] which results in decreased abundance of Glutathione] 1: Rattus norvegicus Liver
4 genes: GSR | SLC7A11 | SOD1 | SOD2
1
48. Blood Glucose lipid oxidation Ethanol | Oxygen [[[Oxygen deficiency co-treated with Blood Glucose deficiency] co-treated with [Oxygen co-treated with Blood Glucose]] co-treated with Ethanol] results in increased lipid oxidation 1: Rattus norvegicus Liver   1
49. Blood Glucose lipid oxidation Ethanol | Malondialdehyde | Oxygen [[[[Oxygen deficiency co-treated with Blood Glucose deficiency] co-treated with [Oxygen co-treated with Blood Glucose]] co-treated with Ethanol] results in increased lipid oxidation] which results in increased abundance of Malondialdehyde 1: Rattus norvegicus Liver   1
50. Blood Glucose glutathione metabolic process Ethanol | Oxygen [[[Oxygen deficiency co-treated with Blood Glucose deficiency] co-treated with [Oxygen co-treated with Blood Glucose]] co-treated with Ethanol] affects glutathione metabolic process 1: Rattus norvegicus Liver
4 genes: GSR | SLC7A11 | SOD1 | SOD2
1
1–50 of 2,390 results.