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Chemical Glucose

1–50 of 1,528 results.
  Chemical Phenotype Co-Mentioned Terms Interaction Organisms Anatomy Inference Network References
1. beta-D-glucosylisophosphoramide mustard apoptotic process beta-D-glucosylisophosphoramide mustard results in increased apoptotic process 1: Homo sapiens Pancreas | Cell Line, Tumor   1
2. beta-D-glucosylisophosphoramide mustard cell proliferation beta-D-glucosylisophosphoramide mustard results in decreased cell proliferation 1: Homo sapiens Pancreas | Cell Line, Tumor   1
3. 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
4. Blood Glucose positive regulation of apoptotic process Oxygen | resveratrol resveratrol inhibits the reaction [[[Oxygen deficiency co-treated with Blood Glucose deficiency] co-treated with [Oxygen co-treated with Blood Glucose]] results in increased positive regulation of apoptotic process] 1: Rattus norvegicus Hepatocytes
27 genes: CASP1 | CASP3 | CASP8 | CASP9 | DDIT3 | DNM1L | GSK3B | HMGB1 | HMOX1 | IL18 | IL1B | IL6 | JAK2 | MAPK8 | MAPK9 | MMP2 | MMP9 | NOS2 | PARK2 | PPARG | PTGS2 | RELA | SIRT1 | SOD1 | SQSTM1 | TLR4 | TNF 		1
5. Blood Glucose positive regulation of release of sequestered calcium ion into cytosol Oxygen [Oxygen deficiency co-treated with Blood Glucose deficiency] results in increased positive regulation of release of sequestered calcium ion into cytosol 1: Rattus norvegicus Mitochondria, Liver   1
6. Blood Glucose protein oxidation Oxygen | RSVA405 RSVA405 inhibits the reaction [[Oxygen deficiency co-treated with Blood Glucose deficiency] results in increased protein oxidation] 1: Rattus norvegicus Kidney   1
7. Blood Glucose lipid oxidation genipin | Oxygen genipin inhibits the reaction [[Blood Glucose deficiency co-treated with Oxygen deficiency] results in increased lipid oxidation] 1: Mus musculus Liver   1
8. Blood Glucose lipid oxidation Malondialdehyde | Oxygen [[Blood Glucose deficiency co-treated with Oxygen deficiency] results in increased lipid oxidation] which results in increased abundance of Malondialdehyde 1: Rattus norvegicus Kidney   1
9. Blood Glucose positive regulation of prostaglandin biosynthetic process Dinoprostone | Indomethacin | Oxygen [Oxygen deficiency co-treated with Blood Glucose deficiency] promotes the reaction [[Indomethacin results in decreased positive regulation of prostaglandin biosynthetic process] which results in decreased chemical synthesis of Dinoprostone] 1: Rattus norvegicus Stomach
3 genes: MAPK9 | PPARG | PTGS2 		1
10. Blood Glucose protein lipidation involved in autophagosome assembly genipin | Oxygen genipin inhibits the reaction [[Blood Glucose deficiency co-treated with Oxygen deficiency] results in increased protein lipidation involved in autophagosome assembly] 1: Mus musculus Liver   1
11. Blood Glucose lipid oxidation Oxygen | Thiobarbituric Acid Reactive Substances [[Oxygen deficiency co-treated with Blood Glucose deficiency] results in increased lipid oxidation] which results in increased abundance of Thiobarbituric Acid Reactive Substances 1: Rattus norvegicus Kidney   1
12. Blood Glucose glutathione metabolic process genipin | Oxygen genipin inhibits the reaction [[Blood Glucose deficiency co-treated with Oxygen deficiency] affects glutathione metabolic process] 1: Mus musculus Liver
3 genes: GSR | SOD1 | SOD2 		1
13. 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
14. Blood Glucose positive regulation of release of sequestered calcium ion into cytosol Oxygen | sodium bisulfide sodium bisulfide inhibits the reaction [[Oxygen deficiency co-treated with Blood Glucose deficiency] results in increased positive regulation of release of sequestered calcium ion into cytosol] 1: Rattus norvegicus Mitochondria, Liver   1
15. Blood Glucose positive regulation of prostaglandin biosynthetic process Oxygen | rofecoxib [[Oxygen deficiency co-treated with Blood Glucose deficiency] co-treated with rofecoxib] results in decreased positive regulation of prostaglandin biosynthetic process 1: Rattus norvegicus Stomach
3 genes: MAPK9 | PPARG | PTGS2 		1
16. Blood Glucose mitochondrial genome maintenance Oxygen [Blood Glucose deficiency co-treated with Oxygen deficiency] results in decreased mitochondrial genome maintenance 1: Rattus norvegicus Corpus Striatum   1
17. Blood Glucose protein lipidation involved in autophagosome assembly Oxygen [Blood Glucose deficiency co-treated with Oxygen deficiency] results in increased protein lipidation involved in autophagosome assembly 1: Mus musculus Liver   1
18. Blood Glucose glucose homeostasis Alloxan | Pentoxifylline Pentoxifylline inhibits the reaction [[Alloxan results in decreased glucose homeostasis] which results in increased abundance of Blood Glucose] 1: Mus musculus Blood
6 genes: AKT2 | IL6 | INS | LEPR | MTNR1B | PPARG 		1
19. Blood Glucose urate metabolic process Oxygen [Oxygen deficiency co-treated with Blood Glucose deficiency] affects urate metabolic process 1: Rattus norvegicus Serum   1
20. Blood Glucose glutathione metabolic process Oxygen [Blood Glucose deficiency co-treated with Oxygen deficiency] affects glutathione metabolic process 1: Mus musculus Liver
3 genes: GSR | SOD1 | SOD2 		1
21. Blood Glucose positive regulation of vascular permeability Oxygen | Quercetin Quercetin inhibits the reaction [[Blood Glucose deficiency co-treated with Oxygen deficiency] results in increased positive regulation of vascular permeability] 1: Rattus norvegicus Pia Mater | Microvessels 1 gene: IL18 1
22. Blood Glucose positive regulation of leukocyte adhesion to vascular endothelial cell Oxygen [Blood Glucose deficiency co-treated with Oxygen deficiency] results in increased positive regulation of leukocyte adhesion to vascular endothelial cell 1: Rattus norvegicus Pia Mater | Microvessels 1 gene: TNF 1
23. Blood Glucose positive regulation of macrophage chemotaxis 1-(3,4-dihydroxyphenyl)-3-(2-methoxyphenyl)prop-2-en-1-one | Oxygen 1-(3,4-dihydroxyphenyl)-3-(2-methoxyphenyl)prop-2-en-1-one inhibits the reaction [[Oxygen deficiency co-treated with Blood Glucose deficiency] results in increased positive regulation of macrophage chemotaxis] 1: Rattus norvegicus Retina
2 genes: MAPK3 | RARRES2 		1
24. Blood Glucose glucose homeostasis Dietary Fats | manganese(III)-tetrakis(4-benzoic acid)porphyrin | tin mesoporphyrin tin mesoporphyrin promotes the reaction [manganese(III)-tetrakis(4-benzoic acid)porphyrin inhibits the reaction [[Dietary Fats results in decreased glucose homeostasis] which results in increased abundance of Blood Glucose]] 1: Mus musculus Blood
6 genes: AKT2 | IL6 | INS | LEPR | MTNR1B | PPARG 		1
25. Blood Glucose positive regulation of leukocyte adhesion to vascular endothelial cell Oxygen | Quercetin | tyrphostin 47 tyrphostin 47 inhibits the reaction [Quercetin inhibits the reaction [[Blood Glucose deficiency co-treated with Oxygen deficiency] results in increased positive regulation of leukocyte adhesion to vascular endothelial cell]] 1: Rattus norvegicus Pia Mater | Microvessels 1 gene: TNF 1
26. Blood Glucose creatinine catabolic process estradiol 3-benzoate | Oxygen estradiol 3-benzoate inhibits the reaction [[Oxygen deficiency co-treated with Blood Glucose deficiency] results in decreased creatinine catabolic process] 1: Rattus norvegicus Serum   1
27. Blood Glucose positive regulation of prostaglandin biosynthetic process Oxygen | resveratrol [Oxygen deficiency co-treated with Blood Glucose deficiency] promotes the reaction [resveratrol results in decreased positive regulation of prostaglandin biosynthetic process] 1: Rattus norvegicus Stomach
3 genes: MAPK9 | PPARG | PTGS2 		1
28. 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
29. Blood Glucose glucose homeostasis Dietary Fats [Dietary Fats results in decreased glucose homeostasis] which results in increased abundance of Blood Glucose 2: Mus musculus | Sus scrofa Blood
6 genes: AKT2 | IL6 | INS | LEPR | MTNR1B | PPARG 		4
30. 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
31. 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
3 genes: GSR | SOD1 | SOD2 		1
32. 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
33. Blood Glucose positive regulation of apoptotic DNA fragmentation Oxygen [Oxygen deficiency co-treated with Blood Glucose deficiency] results in increased positive regulation of apoptotic DNA fragmentation 1: Mus musculus Hippocampus   1
34. Blood Glucose creatinine homeostasis Creatinine | Oxygen [[Oxygen deficiency co-treated with Blood Glucose deficiency] results in decreased creatinine homeostasis] which results in increased abundance of Creatinine 1: Rattus norvegicus Serum   2
35. 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
36. Blood Glucose glutathione metabolic process Ethanol | Glutathione | 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] which results in decreased abundance of Glutathione 1: Rattus norvegicus Liver
3 genes: GSR | SOD1 | SOD2 		1
37. Blood Glucose cellular response to light stimulus 1-(3,4-dihydroxyphenyl)-3-(2-methoxyphenyl)prop-2-en-1-one | Oxygen 1-(3,4-dihydroxyphenyl)-3-(2-methoxyphenyl)prop-2-en-1-one inhibits the reaction [[Oxygen deficiency co-treated with Blood Glucose deficiency] results in decreased cellular response to light stimulus] 1: Mus musculus Retina   1
38. Blood Glucose positive regulation of apoptotic process Oxygen | RSVA405 RSVA405 inhibits the reaction [[Oxygen deficiency co-treated with Blood Glucose deficiency] results in increased positive regulation of apoptotic process] 1: Rattus norvegicus Kidney
27 genes: CASP1 | CASP3 | CASP8 | CASP9 | DDIT3 | DNM1L | GSK3B | HMGB1 | HMOX1 | IL18 | IL1B | IL6 | JAK2 | MAPK8 | MAPK9 | MMP2 | MMP9 | NOS2 | PARK2 | PPARG | PTGS2 | RELA | SIRT1 | SOD1 | SQSTM1 | TLR4 | TNF 		1
39. Blood Glucose lipid oxidation Ethanol | Malondialdehyde | Oxygen | zinc protoporphyrin zinc protoporphyrin promotes 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
40. Blood Glucose positive regulation of p38MAPK cascade 2,2-bis(4-glycidyloxyphenyl)propane | Oxygen | ursolic acid 2,2-bis(4-glycidyloxyphenyl)propane inhibits the reaction [ursolic acid inhibits the reaction [[Oxygen deficiency co-treated with Blood Glucose deficiency] results in increased positive regulation of p38MAPK cascade]] 1: Rattus norvegicus Cerebral Cortex 1 gene: IL1B 1
41. Blood Glucose lipid oxidation Ethanol | Oxygen | zinc protoporphyrin zinc protoporphyrin promotes 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
42. Blood Glucose glucose homeostasis geraniol Blood Glucose promotes the reaction [[geraniol results in increased glucose homeostasis] which results in decreased abundance of Blood Glucose] 1: Mus musculus Plasma
6 genes: AKT2 | IL6 | INS | LEPR | MTNR1B | PPARG 		1
43. Blood Glucose positive regulation of vascular permeability Glyburide | Oxygen | Quercetin Glyburide inhibits the reaction [Quercetin inhibits the reaction [[Blood Glucose deficiency co-treated with Oxygen deficiency] results in increased positive regulation of vascular permeability]] 1: Rattus norvegicus Pia Mater | Microvessels 1 gene: IL18 1
44. Blood Glucose glucose homeostasis Fructose [Fructose 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
45. Blood Glucose regulation of carbohydrate metabolic process cyanoginosin LR [cyanoginosin LR affects regulation of carbohydrate metabolic process] which results in increased abundance of Blood Glucose 1: Mus musculus Serum 1 gene: GCG 1
46. Blood Glucose positive regulation of necrotic cell death Oxygen | sodium bisulfide sodium bisulfide inhibits the reaction [[Oxygen deficiency co-treated with Blood Glucose deficiency] results in increased positive regulation of necrotic cell death] 1: Rattus norvegicus Hepatocytes   1
47. Blood Glucose positive regulation of microglial cell activation Oxygen [Oxygen deficiency co-treated with Blood Glucose deficiency] results in increased positive regulation of microglial cell activation 1: Rattus norvegicus CA1 Region, Hippocampal 1 gene: ITGAM 1
48. Blood Glucose positive regulation of neuron apoptotic process Oxygen [Oxygen deficiency co-treated with Blood Glucose deficiency] results in increased positive regulation of neuron apoptotic process 1: Mus musculus Hippocampus
9 genes: CASP3 | CASP9 | DDIT3 | GSK3B | IL18 | IL1B | MAPK8 | NR3C1 | TNF 		1
49. Blood Glucose glucose homeostasis Dietary Fats [Dietary Fats results in decreased glucose homeostasis] which results in increased abundance of Blood Glucose 1: Rattus norvegicus Plasma
6 genes: AKT2 | IL6 | INS | LEPR | MTNR1B | PPARG 		1
50. Blood Glucose positive regulation of superoxide anion generation Oxygen [Oxygen deficiency co-treated with Blood Glucose deficiency] results in increased positive regulation of superoxide anion generation 1: Rattus norvegicus Kidney
3 genes: IL18 | ITGAM | SOD1 		1
1–50 of 1,528 results.
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