Known targets — ChEMBL curated mechanism
ABCC9ABL1ACEACHEACVR1ADORA1ADORA2AADORA2BADORA3ADRA1AADRA1BADRA1DADRA2AADRA2BADRA2CADRB1ADRB2ADRB3AGTR1ALOX5ATP4AATP4BBCRBTKCACNA1ACACNA1BCACNA1CCACNA1DCACNA1ECACNA1FCACNA1GCACNA1HCACNA1ICACNA1SCACNA2D1CACNA2D2CACNA2D3CACNA2D4CACNB1CACNB2CACNB3CACNB4CACNG1CACNG2CACNG3CACNG4CACNG5CACNG6CACNG7CACNG8CALCRLCFBCHRM1CHRM2CHRM3CHRM4CHRM5CHRNA1CHRNB1CHRNDCHRNECHRNGCRBNCUL4ACXCR1CXCR2DDB1DDCDHFRDPP4DRD2DRD3DRD4EGFRERBB2ERBB4ESR1ESR2FDPSFKBP1AFLT1FLT3FLT4GARTGHSRGRIA1GRIA2GRIA3GRIA4GRIK1GRIK2GRIK3GRIK4GRIK5GRIN2AGSK3AGSK3BHDAC1HDAC10HDAC11HDAC2HDAC3HDAC4HDAC5HDAC6HDAC7HDAC8HDAC9HRH1HTR1AHTR1BHTR1DHTR1EHTR1FHTR2AHTR2BHTR2CHTR3AHTR3BHTR3CHTR3DHTR3EHTR4HTR5AHTR6HTR7IDH1IDH2IMPA1ITGA2BITGB3JAK1JAK2JAK3KCNJ11KCNK3KCNK9KDRKITMEN1METMMP1MMP13MMP7MMP8NANOD2NS5bODC1OPG057OPRD1OPRK1OPRM1PPARP1PARP2PDE3APDE3BPDE4APDE4BPDE4CPDE4DPDGFRBPIK3CAPIK3CBPIK3CDPIK3CGPIK3R1PIK3R2PIK3R3PIK3R5PKLRPPARDPPATPTGS1PTGS2RBX1ROCK1ROCK2RRM1RRM2RRM2BSCN10ASCN11ASCN1ASCN2ASCN3ASCN4ASCN5ASCN7ASCN8ASCN9ASCNN1ASCNN1BSCNN1GSIGMAR1SLC10A2SLC5A2SLC6A2SLC6A3SLC6A4SLC9A3SYKTACR1THRATHRBTOP1TUBA1ATUBA1BTUBA1CTUBA3CTUBA3ETUBA4ATUBBTUBB1TUBB2ATUBB2BTUBB3TUBB4ATUBB4BTUBB6TUBB8TYK2TYMSVDRampCblablaT-3blaT-4blaT-5blaT-6blaUOE-1dacAdacBdacCfolAfolPftsIgyrAgyrBileSmecAmrcAmrcBmrdAparCparEpbp2pbp4pbpApbpFrplArplBrplCrplDrplErplFrplIrplJrplKrplLrplMrplNrplOrplPrplQrplRrplSrplTrplUrplVrplWrplXrplYrpmArpmBrpmCrpmDrpmErpmE2rpmFrpmGrpmG1rpmG2rpmG3rpmHrpmIrpmJrpsArpsBrpsCrpsDrpsErpsFrpsGrpsHrpsIrpsJrpsKrpsLrpsMrpsNrpsOrpsPrpsQrpsRrpsSrpsTrpsUthyAykgMykgO
The experimentally established mechanism targets of Water. The predicted profile below is derived independently by chemical similarity — agreement is a validation signal, a miss is honest.
Similar compounds — the chemically nearest patent molecules
Nearest neighbours by Morgan-fingerprint cosine across the patent-compound collection, with each neighbour's top predicted target and the predicted targets it shares with this molecule.
| Compound | similarity | top predicted | shared targets | |
|---|---|---|---|---|
| Water SCHEMBL15529555 | 1.00 | — | — | |
| Water SCHEMBL29691647 | 0.82 | — | — | |
| Water SCHEMBL7948300 | 0.82 | — | — | |
| Water SCHEMBL1068725 | 0.82 | — | — | |
| Water SCHEMBL7906069 | 0.82 | — | — | |
| Hydrochloric Acid SCHEMBL841521 | 0.82 | — | — | |
| Water SCHEMBL23461833 | 0.67 | — | — | |
| Water SCHEMBL23631871 | 0.67 | — | — | |
| Water SCHEMBL20562889 | 0.67 | — | — | |
| Water SCHEMBL25334174 | 0.67 | — | — |
Similarity is cosine over the 2,048-bit Morgan fingerprint (≈ Tanimoto). Identical fingerprints score 1.00.
Patent provenance — the patents this molecule appears in, and who filed them
Claimed or disclosed in 195 patents — showing the first 20. claimed = in the patent's claims; disclosed = body only.
| Patent | Title | Assignee | Published | Priority | Filing | Country | Status |
|---|---|---|---|---|---|---|---|
| CN-122068054-A | NC loaded Rh single atom and Dy2O3Catalyst, preparation method and application thereof | 中国科学技术大学 | 2026-05-19 | — | — | CN | claimed |
| US-20250246367-A1 | TREATMENT METHOD FOR ENHANCING COERCIVE FORCE OF NEODYMIUM IRON BORON MAGNET | CHINA JILIANG UNIVERSITY (CN) | 2025-07-31 | — | — | US | claimed |
| CN-119119088-B | Preparation method of optical/thermal dual-mode switchable single-molecule magnet material | 青岛大学 | 2025-06-24 | — | — | CN | claimed |
| CN-116496507-B | Dy-MOF fluorescent probe material and preparation method and application thereof | 常州大学 | 2025-03-14 | — | — | CN | claimed |
| CN-119601693-A | Rare earth doped Pt-based high-entropy intermetallic compound, preparation and application | 吉林大学 | 2025-03-11 | — | — | CN | claimed |
| CN-115466278-B | Magnetic/fluorescent difunctional dysprosium complex and preparation method thereof | 晋中学院 | 2025-01-03 | — | — | CN | claimed |
| CN-119119088-A | Preparation method of optical/thermal dual-mode switchable single-molecule magnet material | 青岛大学 | 2024-12-13 | — | — | CN | claimed |
| CN-115290718-B | Aptamer sensor based on Dy-MOF as coreactant accelerator | 山东理工大学 | 2024-11-29 | — | — | CN | claimed |
| CN-119020834-A | Heavy rare earth metal electroplating solution and preparation method and application thereof | 中国计量大学 | 2024-11-26 | — | — | CN | claimed |
| CN-118852252-A | Dysprosium-based single-molecule magnet capable of generating free radicals through X-ray excitation and synthesis method thereof | 南开大学 | 2024-10-29 | — | — | CN | claimed |
| CN-113480562-A | One-dimensional dysprosium chain magnetic complex with two-step relaxation, and preparation method and application thereof | 天津师范大学 | 2021-10-08 | — | — | CN | claimed |
| US-20210077525-A1 | METHOD FOR BONE TISSUE REGENERATION IN EXPERIMENTS | OOO FELIX (RU) | 2021-03-18 | — | — | US | claimed |
| CN-112480181-A | Dysprosium monomolecular magnet and synthesis method and application thereof | 江苏科技大学 | 2021-03-12 | — | — | CN | claimed |
| CN-112341481-A | Mononuclear dysprosium magnetic complex and preparation method and application thereof | 江苏科技大学 | 2021-02-09 | — | — | CN | claimed |
| US-20200316110-A1 | METHOD FOR BONE TISSUE REGENERATION IN EXPERIMENTS | OOO FELIX (RU) | 2020-10-08 | — | — | US | claimed |
| CN-111363428-A | Fingerprint-preventing and pollution-preventing environment-friendly coating and preparation method thereof | 苏州鼎奕通材料科技有限公司 | 2020-07-03 | — | — | CN | claimed |
| CN-107556341-B | Hexa-coordinate chirality dysprosium single ion magnet and its synthetic method with electromagnetic coupling effect | 南开大学 | 2019-03-26 | — | — | CN | claimed |
| CN-107556341-A | Hexa-coordinate chirality dysprosium single ion magnet and its synthetic method with electromagnetic coupling effect | 南开大学 | 2018-01-09 | — | — | CN | claimed |
| US-20150140119-A1 | METHOD FOR BONE TISSUE REGENERATION IN EXPERIMENTS | OOO "FELIX " (RU) | 2015-05-21 | — | — | US | claimed |
| US-4851205-A | LITHIUM, MAGNESIUM, CALCIUM, MANGANESE, YTTRIUM, OR LANTHANIDE METAL; UNIFORMITY, HIGH STRENGTH | NATIONAL INSTITUTE FOR RESEARCHES IN INORGANIC MATERIALS (JP) | 1989-07-25 | — | — | US | claimed |