SCHEMBL3762952

SCHEMBL3762952

CCCCn1cc[n+](C(C)(C)C)c1

nearest known ligand 0.58

Predicted protein targets (top 15)

geneUniProtsupporting neighboursconfidence
MEN1 O00255 2/20 0.49
HSP90AA1 P07900 2/20 0.49
KMT2A Q03164 2/20 0.49
SMN1; SMN2 Q16637 2/20 0.49
APAF1 O14727 1/20 0.49
NPC1 O15118 1/20 0.49
PLA2G1B P04054 1/20 0.49
MAPT P10636 1/20 0.49
MAPK1 P28482 1/20 0.49
HTT P42858 1/20 0.49
RAB9A P51151 1/20 0.49
NPSR1 Q6W5P4 1/20 0.49
ATG4B Q9Y4P1 1/20 0.49
FDPS P14324 16/20 0.41
PON1 P27169 1/20 0.35

Click a target to see other patent compounds predicted against it — the reverse direction, in place.

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.

Compoundsimilaritytop predictedshared targets
SCHEMBL17131176 0.94 MEN1 (0.56) MEN1HSP90AA1KMT2ASMN1; SMN2APAF1
SCHEMBL21834833 0.93 MEN1 (0.59) MEN1HSP90AA1KMT2ASMN1; SMN2APAF1
SCHEMBL28548845 0.93 MEN1 (0.59) MEN1HSP90AA1KMT2ASMN1; SMN2APAF1
SCHEMBL21834765 0.93 MEN1 (0.59) MEN1HSP90AA1KMT2ASMN1; SMN2APAF1
SCHEMBL28547528 0.93 MEN1 (0.59) MEN1HSP90AA1KMT2ASMN1; SMN2APAF1
SCHEMBL17131174 0.93 MEN1 (0.59) MEN1HSP90AA1KMT2ASMN1; SMN2APAF1
SCHEMBL21834817 0.93 MEN1 (0.59) MEN1HSP90AA1KMT2ASMN1; SMN2APAF1
SCHEMBL3767086 0.88 MEN1 (0.39) MEN1HSP90AA1KMT2ASMN1; SMN2APAF1
Formic Acid SCHEMBL28564597 0.84 MEN1 (0.50) MEN1HSP90AA1KMT2ASMN1; SMN2APAF1
SCHEMBL372627 0.83 MEN1 (0.47) MEN1HSP90AA1KMT2ASMN1; SMN2APAF1

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 34 patents — showing the first 20. claimed = in the patent's claims; disclosed = body only.

PatentTitleAssigneePublishedPriorityFilingCountryStatus
US-20240219836-A1 Conductive Polymer Composition, Coated Product, And Patterning Process SHIN-ETSU CHEMICAL CO., LTD. (JP) 2024-07-04 US disclosed
US-11996557-B2 Direct regeneration of lithium ion cathodes by ionothermal relithiation UT-BATTELLE, LLC (US) 2024-05-28 US disclosed
US-20230378459-A1 SECONDARY BATTERY, ELECTRONIC DEVICE, AND VEHICLE SEMICONDUCTOR ENERGY LABORATORY CO., LTD. (JP) 2023-11-23 US disclosed
US-11795583-B2 Plasticized melt spinning process using ionic liquids for production of polyacrylonitrile fibers UT-BATTELLE, LLC (US) 2023-10-24 US disclosed
US-20230327207-A1 Storage Battery, Battery Control Unit, and Electronic Device SEMICONDUCTOR ENERGY LAB (JP) 2023-10-12 US disclosed
US-20230231199-A1 SECONDARY BATTERY AND VEHICLE INCLUDING SECONDARY BATTERY SEMICONDUCTOR ENERGY LABORATORY CO., LTD. (JP) 2023-07-20 US disclosed
US-20220376240-A1 DIRECT REGENERATION OF LITHIUM ION CATHODES BY IONOTHERMAL RELITHIATION U. S. DEPARTMENT OF ENERGY 2022-11-24 US disclosed
US-20220235493-A1 PLASTICIZED MELT SPINNING PROCESS USING IONIC LIQUIDS FOR PRODUCTION OF POLYACRYLONITRILE FIBERS UNIVERSITY OF TENNESSEE RESEARCH FOUNDATION 2022-07-28 US disclosed
US-11251433-B2 Nitrogen-sulfur-carbon nanocomposites and their application as cathode materials in lithium-sulfur batteries UT-BATTELLE, LLC (US) 2022-02-15 US disclosed
US-11186893-B2 Rare earth amide compositions UT-BATTELLE, LLC (US) 2021-11-30 US disclosed
US-20150279577-A1 POWER STORAGE DEVICE AND ELECTRONIC DEVICE SEMICONDUCTOR ENERGY LABORATORY CO., LTD. (JP) 2015-10-01 US disclosed
US-8865094-B2 Methods for separating medical isotopes using ionic liquids UT-BATTELLE, LLC (US) 2014-10-21 US disclosed
US-20140141328-A1 NITROGEN-SULFUR-CARBON NANOCOMPOSITES AND THEIR APPLICATION AS CATHODE MATERIALS IN LITHIUM-SULFUR BATTERIES UT-BATTELLE, LLC (US) 2014-05-22 US disclosed
US-20140113202-A1 ELECTROLYTE COMPOSITIONS FOR LITHIUM ION BATTERIES UT-BATTELLE, LLC (US) 2014-04-24 US disclosed
US-20140072485-A1 METHODS FOR SEPARATING MEDICAL ISOTOPES USING IONIC LIQUIDS UT-BATTELLE, LLC (US) 2014-03-13 US disclosed
US-8585886-B2 Method for synthesis of titanium dioxide nanotubes using ionic liquids UT-BATTELLE, LLC (US) 2013-11-19 US disclosed
US-20130280151-A1 IONIC LIQUID-FUNCTIONALIZED MESOPOROUS SORBENTS AND THEIR USE IN THE CAPTURE OF POLLUTING GASES U.S. DEPARTMENT OF ENERGY 2013-10-24 US disclosed
US-20120175266-A1 METHOD FOR SYNTHESIS OF TITANIUM DIOXIDE NANOTUBES USING IONIC LIQUIDS UT-BATTELLE, LLC (US) 2012-07-12 US disclosed
US-20100311615-A1 METHOD FOR SYNTHESIS OF TITANIUM DIOXIDE NANOTUBES USING IONIC LIQUIDS UT-BATTELLE, LLC (US) 2010-12-09 US disclosed
US-20060186419-A1 Light-emitting device KABUSHIKI KAISHA TOSHIBA (JP) 2006-08-24 US disclosed

Patent text — is the patent's own abstract consistent with the prediction?

For each of this compound's patents that has machine-readable text (1 of them — usually the abstract, not the full specification), we ask MedCPT which protein the text reads most about, and where the chemistry-predicted target lands among 4885 human targets. A high rank means the patent's own wording is consistent with the prediction — a weak, independent signal, not proof of activity.

PatentTitleText reads most aboutPredicted target · text-rank
US-20230378459-A1 SECONDARY BATTERY, ELECTRONIC DEVICE, AND VEHICLE VDAC3, VDAC2, SCO2 MEN1 2332/4885HSP90AA1 2985/4885KMT2A 1910/4885

“Text reads most about” is the patent abstract's nearest protein in MedCPT space (background-debiased). Only ~1.4% of patents have machine-readable text, so most compounds won't have this panel.