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Chemical Haloperidol

1–50 of 76 results.
  Chemical Phenotype Co-Mentioned Terms Interaction Organisms Anatomy Inference Network References
1. Haloperidol glycosylation Dopamine Haloperidol inhibits the reaction [Dopamine results in increased glycosylation] 1: Rattus norvegicus Hippocampus   1
2. Haloperidol renal sodium excretion Haloperidol results in decreased renal sodium excretion 1: Rattus norvegicus Kidney   1
3. Haloperidol vasodilation Dopamine Haloperidol inhibits the reaction [Dopamine results in increased vasodilation] 1: Oryctolagus cuniculus Cardiovascular System
8 genes: ADORA2A | AGT | CALCA | DRD1 | GPX1 | SOD2 | TNF | VAMP2
1
4. Haloperidol positive regulation of urine volume Dexamethasone Haloperidol inhibits the reaction [Dexamethasone results in increased positive regulation of urine volume] 1: Rattus norvegicus Urine
7 genes: ADORA2A | DRD2 | EDN1 | GNAI2 | NPPB | OPRL1 | TFAP2B
1
5. Haloperidol renal sodium excretion Dexamethasone Haloperidol inhibits the reaction [Dexamethasone results in increased renal sodium excretion] 1: Rattus norvegicus Urine   1
6. Haloperidol apoptotic process Haloperidol results in increased apoptotic process 1: Rattus norvegicus Corpus Striatum | Neurons
60 genes: ADORA2A | AKT1 | AKT2 | ALDOC | APAF1 | ARG2 | AVP | BAX | BCL2 | BCL2L1 | BIRC7 | CASP3 | CASP7 | CCK | CDK5 | CHAC1 | CIDEB | CRYAA | CSNK2A1 | CST3 | DEDD1 | DIABLOA | DPF1 | EGLN3 | EPO | ERBB4 | GAPDH | GJA1 | GPX1 | ING4 | IRF1B | JADE1 | KCNIP3 | KMT2A | MAPK1 | MAPK14 | MAPK3 | MYDGF | NFKB1 | NGFR | NR4A1 | PDE1B | PIM2 | POU4F2 | PPP2CA | PPP2R1A | PRKCB | PRKCBB | PRKCE | PSMD10 | RALB | RBM5 | RNF41 | RTN4 | S100A9 | SGK1 | STK17A | TFAP2B | TNF | TP53
1
7. Haloperidol apoptotic process Haloperidol results in increased apoptotic process 1: Rattus norvegicus Substantia Nigra | Neurons
60 genes: ADORA2A | AKT1 | AKT2 | ALDOC | APAF1 | ARG2 | AVP | BAX | BCL2 | BCL2L1 | BIRC7 | CASP3 | CASP7 | CCK | CDK5 | CHAC1 | CIDEB | CRYAA | CSNK2A1 | CST3 | DEDD1 | DIABLOA | DPF1 | EGLN3 | EPO | ERBB4 | GAPDH | GJA1 | GPX1 | ING4 | IRF1B | JADE1 | KCNIP3 | KMT2A | MAPK1 | MAPK14 | MAPK3 | MYDGF | NFKB1 | NGFR | NR4A1 | PDE1B | PIM2 | POU4F2 | PPP2CA | PPP2R1A | PRKCB | PRKCBB | PRKCE | PSMD10 | RALB | RBM5 | RNF41 | RTN4 | S100A9 | SGK1 | STK17A | TFAP2B | TNF | TP53
1
8. Haloperidol apoptotic process Haloperidol results in increased apoptotic process 1: Rattus norvegicus PC12 Cells
60 genes: ADORA2A | AKT1 | AKT2 | ALDOC | APAF1 | ARG2 | AVP | BAX | BCL2 | BCL2L1 | BIRC7 | CASP3 | CASP7 | CCK | CDK5 | CHAC1 | CIDEB | CRYAA | CSNK2A1 | CST3 | DEDD1 | DIABLOA | DPF1 | EGLN3 | EPO | ERBB4 | GAPDH | GJA1 | GPX1 | ING4 | IRF1B | JADE1 | KCNIP3 | KMT2A | MAPK1 | MAPK14 | MAPK3 | MYDGF | NFKB1 | NGFR | NR4A1 | PDE1B | PIM2 | POU4F2 | PPP2CA | PPP2R1A | PRKCB | PRKCBB | PRKCE | PSMD10 | RALB | RBM5 | RNF41 | RTN4 | S100A9 | SGK1 | STK17A | TFAP2B | TNF | TP53
1
9. Haloperidol apoptotic process BCL2L1 BCL2L1 protein promotes the reaction [Haloperidol results in increased apoptotic process] 1: Rattus norvegicus PC12 Cells
60 genes: ADORA2A | AKT1 | AKT2 | ALDOC | APAF1 | ARG2 | AVP | BAX | BCL2 | BCL2L1 | BIRC7 | CASP3 | CASP7 | CCK | CDK5 | CHAC1 | CIDEB | CRYAA | CSNK2A1 | CST3 | DEDD1 | DIABLOA | DPF1 | EGLN3 | EPO | ERBB4 | GAPDH | GJA1 | GPX1 | ING4 | IRF1B | JADE1 | KCNIP3 | KMT2A | MAPK1 | MAPK14 | MAPK3 | MYDGF | NFKB1 | NGFR | NR4A1 | PDE1B | PIM2 | POU4F2 | PPP2CA | PPP2R1A | PRKCB | PRKCBB | PRKCE | PSMD10 | RALB | RBM5 | RNF41 | RTN4 | S100A9 | SGK1 | STK17A | TFAP2B | TNF | TP53
1
10. Haloperidol apoptotic process 1,3-ditolylguanidine 1,3-ditolylguanidine inhibits the reaction [Haloperidol results in increased apoptotic process] 1: Rattus norvegicus PC12 Cells
60 genes: ADORA2A | AKT1 | AKT2 | ALDOC | APAF1 | ARG2 | AVP | BAX | BCL2 | BCL2L1 | BIRC7 | CASP3 | CASP7 | CCK | CDK5 | CHAC1 | CIDEB | CRYAA | CSNK2A1 | CST3 | DEDD1 | DIABLOA | DPF1 | EGLN3 | EPO | ERBB4 | GAPDH | GJA1 | GPX1 | ING4 | IRF1B | JADE1 | KCNIP3 | KMT2A | MAPK1 | MAPK14 | MAPK3 | MYDGF | NFKB1 | NGFR | NR4A1 | PDE1B | PIM2 | POU4F2 | PPP2CA | PPP2R1A | PRKCB | PRKCBB | PRKCE | PSMD10 | RALB | RBM5 | RNF41 | RTN4 | S100A9 | SGK1 | STK17A | TFAP2B | TNF | TP53
1
11. Haloperidol regulation of blood pressure Clonidine Haloperidol inhibits the reaction [Clonidine results in increased regulation of blood pressure] 1: Rattus norvegicus Cardiovascular System
15 genes: AGT | ATP1A1 | CALCA | EDN1 | ERAP1A | NPPA | NPPB | NPY | PTGS2A | RENBP | SGK1 | SOD1 | SOD2 | TAC1 | UTS2B
1
12. Haloperidol regulation of heart rate Tyramine Haloperidol inhibits the reaction [Tyramine results in increased regulation of heart rate] 1: Rattus norvegicus Cardiovascular System
7 genes: AGT | CACNA1G | CALCA | CALM2 | CASQ2 | DRD2 | PRKACA
1
13. Haloperidol cell death Haloperidol results in increased cell death Hippocampus | Neurons | Cells, Cultured
4 genes: AXIN2 | CACNA1A | FOSL2 | HTR2A
1
14. Haloperidol cell death Haloperidol results in increased cell death 1: Rattus norvegicus Neuroglia | Cell Line, Tumor
4 genes: AXIN2 | CACNA1A | FOSL2 | HTR2A
1
15. Haloperidol apoptotic DNA fragmentation Haloperidol results in increased apoptotic DNA fragmentation   1 gene: CASP3 1
16. Haloperidol apoptotic DNA fragmentation Vitamin E Vitamin E inhibits the reaction [Haloperidol results in increased apoptotic DNA fragmentation]   1 gene: CASP3 1
17. Haloperidol cell death Vitamin E Vitamin E inhibits the reaction [Haloperidol results in increased cell death]  
4 genes: AXIN2 | CACNA1A | FOSL2 | HTR2A
1
18. Haloperidol DNA methylation Haloperidol affects DNA methylation 1: Rattus norvegicus Leukocytes
5 genes: FOS | GNAS | HEMK1 | KMT2A | MTA2
1
19. Haloperidol DNA methylation Haloperidol results in decreased DNA methylation 1: Rattus norvegicus Brain
5 genes: FOS | GNAS | HEMK1 | KMT2A | MTA2
1
20. Haloperidol membrane lipid catabolic process Haloperidol results in increased membrane lipid catabolic process 1: Rattus norvegicus     1
21. Haloperidol membrane lipid catabolic process Melatonin Melatonin inhibits the reaction [Haloperidol results in increased membrane lipid catabolic process] 1: Rattus norvegicus     1
22. Haloperidol membrane lipid catabolic process Haloperidol results in increased membrane lipid catabolic process 1: Rattus norvegicus Brain   2
23. Haloperidol membrane lipid catabolic process Quercetin Quercetin inhibits the reaction [Haloperidol results in increased membrane lipid catabolic process] 1: Rattus norvegicus Brain   1
24. Haloperidol membrane lipid catabolic process Haloperidol results in increased membrane lipid catabolic process 1: Rattus norvegicus Prosencephalon   2
25. Haloperidol membrane lipid catabolic process Quercetin Quercetin inhibits the reaction [Haloperidol results in increased membrane lipid catabolic process] 1: Rattus norvegicus Prosencephalon   1
26. Haloperidol membrane lipid catabolic process Tacrolimus Tacrolimus inhibits the reaction [Haloperidol results in increased membrane lipid catabolic process] 1: Rattus norvegicus Brain   1
27. Haloperidol apoptotic process Haloperidol results in increased apoptotic process 1: Rattus norvegicus Cerebral Cortex | Neurons | Cells, Cultured
60 genes: ADORA2A | AKT1 | AKT2 | ALDOC | APAF1 | ARG2 | AVP | BAX | BCL2 | BCL2L1 | BIRC7 | CASP3 | CASP7 | CCK | CDK5 | CHAC1 | CIDEB | CRYAA | CSNK2A1 | CST3 | DEDD1 | DIABLOA | DPF1 | EGLN3 | EPO | ERBB4 | GAPDH | GJA1 | GPX1 | ING4 | IRF1B | JADE1 | KCNIP3 | KMT2A | MAPK1 | MAPK14 | MAPK3 | MYDGF | NFKB1 | NGFR | NR4A1 | PDE1B | PIM2 | POU4F2 | PPP2CA | PPP2R1A | PRKCB | PRKCBB | PRKCE | PSMD10 | RALB | RBM5 | RNF41 | RTN4 | S100A9 | SGK1 | STK17A | TFAP2B | TNF | TP53
1
28. Haloperidol apoptotic process Bromocriptine Bromocriptine inhibits the reaction [Haloperidol results in increased apoptotic process] 1: Rattus norvegicus Cerebral Cortex | Neurons | Cells, Cultured
60 genes: ADORA2A | AKT1 | AKT2 | ALDOC | APAF1 | ARG2 | AVP | BAX | BCL2 | BCL2L1 | BIRC7 | CASP3 | CASP7 | CCK | CDK5 | CHAC1 | CIDEB | CRYAA | CSNK2A1 | CST3 | DEDD1 | DIABLOA | DPF1 | EGLN3 | EPO | ERBB4 | GAPDH | GJA1 | GPX1 | ING4 | IRF1B | JADE1 | KCNIP3 | KMT2A | MAPK1 | MAPK14 | MAPK3 | MYDGF | NFKB1 | NGFR | NR4A1 | PDE1B | PIM2 | POU4F2 | PPP2CA | PPP2R1A | PRKCB | PRKCBB | PRKCE | PSMD10 | RALB | RBM5 | RNF41 | RTN4 | S100A9 | SGK1 | STK17A | TFAP2B | TNF | TP53
1
29. Haloperidol apoptotic process Ketanserin Ketanserin inhibits the reaction [Haloperidol results in increased apoptotic process] 1: Rattus norvegicus Cerebral Cortex | Neurons | Cells, Cultured
60 genes: ADORA2A | AKT1 | AKT2 | ALDOC | APAF1 | ARG2 | AVP | BAX | BCL2 | BCL2L1 | BIRC7 | CASP3 | CASP7 | CCK | CDK5 | CHAC1 | CIDEB | CRYAA | CSNK2A1 | CST3 | DEDD1 | DIABLOA | DPF1 | EGLN3 | EPO | ERBB4 | GAPDH | GJA1 | GPX1 | ING4 | IRF1B | JADE1 | KCNIP3 | KMT2A | MAPK1 | MAPK14 | MAPK3 | MYDGF | NFKB1 | NGFR | NR4A1 | PDE1B | PIM2 | POU4F2 | PPP2CA | PPP2R1A | PRKCB | PRKCBB | PRKCE | PSMD10 | RALB | RBM5 | RNF41 | RTN4 | S100A9 | SGK1 | STK17A | TFAP2B | TNF | TP53
1
30. Haloperidol apoptotic process BDNF BDNF protein inhibits the reaction [Haloperidol results in increased apoptotic process] 1: Rattus norvegicus Cerebral Cortex | Neurons | Cells, Cultured
60 genes: ADORA2A | AKT1 | AKT2 | ALDOC | APAF1 | ARG2 | AVP | BAX | BCL2 | BCL2L1 | BIRC7 | CASP3 | CASP7 | CCK | CDK5 | CHAC1 | CIDEB | CRYAA | CSNK2A1 | CST3 | DEDD1 | DIABLOA | DPF1 | EGLN3 | EPO | ERBB4 | GAPDH | GJA1 | GPX1 | ING4 | IRF1B | JADE1 | KCNIP3 | KMT2A | MAPK1 | MAPK14 | MAPK3 | MYDGF | NFKB1 | NGFR | NR4A1 | PDE1B | PIM2 | POU4F2 | PPP2CA | PPP2R1A | PRKCB | PRKCBB | PRKCE | PSMD10 | RALB | RBM5 | RNF41 | RTN4 | S100A9 | SGK1 | STK17A | TFAP2B | TNF | TP53
1
31. Haloperidol regulation of membrane potential Serotonin Haloperidol inhibits the reaction [Serotonin affects regulation of membrane potential] 1: Rattus norvegicus Olfactory Pathways | Interneurons
15 genes: CACNA1A | CACNA1G | CNIH2 | DLD | GPR39 | GRIK2 | GRIK5 | GRIN1 | GRIN2A | GRIN2C | KCNA1 | KCNH2 | NEDD4 | RIMS1 | WWP2
1
32. Haloperidol inhibitory postsynaptic potential Serotonin Haloperidol inhibits the reaction [Serotonin results in increased inhibitory postsynaptic potential] 1: Rattus norvegicus Olfactory Pathways | Pyramidal Cells
5 genes: ADORA2A | BDNF | DRD4 | GABRB3 | GRIK2
1
33. Haloperidol apoptotic process Haloperidol results in increased apoptotic process 1: Rattus norvegicus Cerebral Cortex
60 genes: ADORA2A | AKT1 | AKT2 | ALDOC | APAF1 | ARG2 | AVP | BAX | BCL2 | BCL2L1 | BIRC7 | CASP3 | CASP7 | CCK | CDK5 | CHAC1 | CIDEB | CRYAA | CSNK2A1 | CST3 | DEDD1 | DIABLOA | DPF1 | EGLN3 | EPO | ERBB4 | GAPDH | GJA1 | GPX1 | ING4 | IRF1B | JADE1 | KCNIP3 | KMT2A | MAPK1 | MAPK14 | MAPK3 | MYDGF | NFKB1 | NGFR | NR4A1 | PDE1B | PIM2 | POU4F2 | PPP2CA | PPP2R1A | PRKCB | PRKCBB | PRKCE | PSMD10 | RALB | RBM5 | RNF41 | RTN4 | S100A9 | SGK1 | STK17A | TFAP2B | TNF | TP53
1
34. Haloperidol apoptotic process INS INS protein inhibits the reaction [Haloperidol results in increased apoptotic process] Cerebral Cortex
60 genes: ADORA2A | AKT1 | AKT2 | ALDOC | APAF1 | ARG2 | AVP | BAX | BCL2 | BCL2L1 | BIRC7 | CASP3 | CASP7 | CCK | CDK5 | CHAC1 | CIDEB | CRYAA | CSNK2A1 | CST3 | DEDD1 | DIABLOA | DPF1 | EGLN3 | EPO | ERBB4 | GAPDH | GJA1 | GPX1 | ING4 | IRF1B | JADE1 | KCNIP3 | KMT2A | MAPK1 | MAPK14 | MAPK3 | MYDGF | NFKB1 | NGFR | NR4A1 | PDE1B | PIM2 | POU4F2 | PPP2CA | PPP2R1A | PRKCB | PRKCBB | PRKCE | PSMD10 | RALB | RBM5 | RNF41 | RTN4 | S100A9 | SGK1 | STK17A | TFAP2B | TNF | TP53
1
35. Haloperidol excitatory postsynaptic potential Haloperidol affects excitatory postsynaptic potential 1: Rattus norvegicus Prefrontal Cortex | Pyramidal Cells
16 genes: ADORA2A | AKT1 | BDNF | CDK5 | DRD2 | GRIK2 | GRIK5 | GRIN1 | GRIN2A | GRIN2B | GRIN2C | GRIN2D | GSK3A | GSK3B | OPRM1 | PPP3CA
1
36. Haloperidol membrane lipid catabolic process U 74500A U 74500A inhibits the reaction [Haloperidol results in increased membrane lipid catabolic process] 1: Rattus norvegicus Cerebral Cortex   1
37. Haloperidol membrane lipid catabolic process U 74500A U 74500A inhibits the reaction [Haloperidol results in increased membrane lipid catabolic process] 1: Rattus norvegicus Corpus Striatum   1
38. Haloperidol membrane lipid catabolic process Haloperidol results in increased membrane lipid catabolic process 1: Rattus norvegicus Cerebral Cortex   1
39. Haloperidol membrane lipid catabolic process Haloperidol results in increased membrane lipid catabolic process 1: Rattus norvegicus Corpus Striatum   2
40. Haloperidol membrane lipid catabolic process Haloperidol results in increased membrane lipid catabolic process 1: Homo sapiens Serum   1
41. Haloperidol response to oxidative stress Haloperidol results in increased response to oxidative stress 1: Homo sapiens Serum
20 genes: ABCC1 | AKT1 | BCL2 | BCL2L1 | CAT | CST3 | GATM | GPX1 | GPX4A | HAO1 | MAP2K1 | NFKB1 | PARK7 | PTGS2A | SELENOP | SOD1 | SOD2 | SOD3 | TOR1A | TP53
1
42. Haloperidol excitatory postsynaptic potential Haloperidol affects excitatory postsynaptic potential 1: Rattus norvegicus Hippocampus
16 genes: ADORA2A | AKT1 | BDNF | CDK5 | DRD2 | GRIK2 | GRIK5 | GRIN1 | GRIN2A | GRIN2B | GRIN2C | GRIN2D | GSK3A | GSK3B | OPRM1 | PPP3CA
1
43. Haloperidol vasodilation Dopamine Haloperidol inhibits the reaction [Dopamine results in increased vasodilation] 1: Canis lupus familiaris Pancreas
8 genes: ADORA2A | AGT | CALCA | DRD1 | GPX1 | SOD2 | TNF | VAMP2
1
44. Haloperidol vasoconstriction Haloperidol results in increased vasoconstriction 1: Rattus norvegicus Basilar Artery
6 genes: AGT | AVP | EDN1 | HTR1D | KEL | SLC6A4
1
45. Haloperidol regulation of blood pressure Apomorphine Haloperidol inhibits the reaction [Apomorphine results in decreased regulation of blood pressure] 1: Canis lupus familiaris Cardiovascular System
15 genes: AGT | ATP1A1 | CALCA | EDN1 | ERAP1A | NPPA | NPPB | NPY | PTGS2A | RENBP | SGK1 | SOD1 | SOD2 | TAC1 | UTS2B
1
46. Haloperidol regulation of heart rate Apomorphine Haloperidol inhibits the reaction [Apomorphine results in increased regulation of heart rate] 1: Canis lupus familiaris Cardiovascular System
7 genes: AGT | CACNA1G | CALCA | CALM2 | CASQ2 | DRD2 | PRKACA
1
47. Haloperidol membrane lipid catabolic process Carvedilol Carvedilol inhibits the reaction [Haloperidol results in increased membrane lipid catabolic process] 1: Rattus norvegicus Prosencephalon   1
48. Haloperidol membrane lipid catabolic process Zolpidem Zolpidem inhibits the reaction [Haloperidol results in increased membrane lipid catabolic process] 1: Rattus norvegicus Corpus Striatum   1
49. Haloperidol regulation of blood pressure N,N-di-n-propyldopamine Haloperidol inhibits the reaction [N,N-di-n-propyldopamine results in decreased regulation of blood pressure] 1: Rattus norvegicus Arteries
15 genes: AGT | ATP1A1 | CALCA | EDN1 | ERAP1A | NPPA | NPPB | NPY | PTGS2A | RENBP | SGK1 | SOD1 | SOD2 | TAC1 | UTS2B
1
50. Haloperidol response to oxidative stress Haloperidol results in increased response to oxidative stress 1: Homo sapiens Plasma
20 genes: ABCC1 | AKT1 | BCL2 | BCL2L1 | CAT | CST3 | GATM | GPX1 | GPX4A | HAO1 | MAP2K1 | NFKB1 | PARK7 | PTGS2A | SELENOP | SOD1 | SOD2 | SOD3 | TOR1A | TP53
1
1–50 of 76 results.