SCHEMBL1503398

SCHEMBL1503398

Cc1c(N)ccc2c1sc1c(C)c(N)ccc12

nearest known ligand 0.42

Predicted protein targets (top 20)

geneUniProtsupporting neighboursconfidence
CYP3A4 P08684 3/20 0.42
TSHR P16473 2/20 0.42
PIK3CA P42336 1/20 0.42
ALDH1A1 P00352 4/20 0.37
KDM4E B2RXH2 2/20 0.37
HPGD P15428 2/20 0.37
HSD17B10 Q99714 2/20 0.37
GLA P06280 1/20 0.37
GAA P10253 1/20 0.37
TDP1 Q9NUW8 2/20 0.33
TP53 P04637 1/20 0.33
THRB P10828 1/20 0.33
ALOX15 P16050 1/20 0.33
SMN1; SMN2 Q16637 1/20 0.33
ESR1 P03372 1/20 0.33
ESR2 Q92731 1/20 0.33
IDO1 P14902 1/20 0.31
EP300 Q09472 1/20 0.30
KAT8 Q9H7Z6 1/20 0.30
NPC1 O15118 1/20 0.30

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
SCHEMBL24385161 0.82 MAPT (0.47) CYP3A4TSHRPIK3CAALDH1A1KDM4E
SCHEMBL30884006 0.79 ALDH1A1 (0.37) CYP3A4TSHRPIK3CAALDH1A1KDM4E
SCHEMBL9448729 0.79 ALDH1A1 (0.36) CYP3A4TSHRPIK3CAALDH1A1KDM4E
SCHEMBL11976506 0.74 CYP1A2 (0.37) CYP3A4TSHRALDH1A1KDM4EHPGD
SCHEMBL3882651 0.74 MEN1 (0.32) MAPT
SCHEMBL33944 0.71 CYP3A4 (0.62) CYP3A4TSHRPIK3CAALDH1A1KDM4E
SCHEMBL4164226 0.70 MEN1 (0.32) TSHRGAAALOX15USP2MAPT
SCHEMBL4916133 0.70
SCHEMBL4927772 0.70 MAPT (0.37) ALDH1A1KDM4ESMN1; SMN2NPC1MAPT
SCHEMBL3875160 0.70 HDAC3 (0.34) CYP3A4TSHRHSD17B10GAAALOX15

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

PatentTitleAssigneePublishedPriorityFilingCountryStatus
US-20260131280-A1 GAS SEPARATION MEMBRANE UNIT, GAS SEPARATION SYSTEM, AND METHOD FOR PRODUCING ENRICHED GAS UBE CORP (JP) 2026-05-14 US disclosed
EP-4721843-A1 GAS SEPARATION MEMBRANE UNIT, GAS SEPARATION SYSTEM, AND METHOD FOR PRODUCING ENRICHED GAS UBE Corporation (JP) 2026-04-08 EP disclosed
EP-4691603-A1 GAS SEPARATION SYSTEM AND METHOD FOR PRODUCING METHANE ENRICHED GAS UBE Corporation (JP) 2026-02-11 EP disclosed
US-20260008003-A1 GAS SEPARATION SYSTEM AND METHOD FOR PRODUCING METHANE-ENRICHED GAS UBE CORP (JP) 2026-01-08 US disclosed
US-20220029177-A1 POWER GENERATION SYSTEM TORAY INDUSTRIES, INC. (JP) 2022-01-27 US disclosed
US-20220029185-A1 POWER GENERATION SYSTEM TORAY INDUSTRIES, INC. (JP) 2022-01-27 US disclosed
US-20220029178-A1 POWER GENERATION SYSTEM TORAY INDUSTRIES, INC. (JP) 2022-01-27 US disclosed
US-10765992-B2 Gas separation membrane module and method for gas separation UBE INDUSTRIES, LTD. (JP) 2020-09-08 US disclosed
US-10369515-B2 Gas separation membrane module and method for gas separation UBE INDUSTRIES, LTD. (JP) 2019-08-06 US disclosed
US-20190201839-A1 GAS SEPARATION MEMBRANE MODULE AND METHOD FOR GAS SEPARATION UBE CORPORATION (JP) 2019-07-04 US disclosed
US-7771518-B2 Asymmetric hollow fiber gas separation membrane and gas separation method UBE INDUSTRIES, LTD. (JP) 2010-08-10 US disclosed
US-20080134885-A1 Good gas permeation performance and a practical mechanical strength; made of a soluble aromatic polyimide UBE INDUSTRIES, LTD. (JP) 2008-06-12 US disclosed
US-7339009-B2 Cross-linked polyimide and method of making them GENERAL ELECTRIC COMPANY (US) 2008-03-04 US disclosed
US-20080017029-A1 Asymmetric hollow-fiber gas separation membrane, gas separation method and gas separation membrane module UBE INDUSTRIES, LTD. (JP) 2008-01-24 US disclosed
US-20060135732-A1 Cross-linked polyimide and method of making them GENERAL ELECTRIC COMPANY 2006-06-22 US disclosed
EP-0361377-B1 Pervaporation method of separating liquid organic compound mixture through aromatic imide polymer asymmetric membrane UBE INDUSTRIES (JP) 1995-06-28 EP disclosed
US-4997462-A Pervaporation method of selectively separating water from an organic material aqueous solution through aromatic imide polymer asymmetric membrane UBE INDUSTRIES, LTD. (JP) 1991-03-05 US disclosed
EP-0391699-A1 Pervaporation method of selectively separating water from an organic material aqueous solution through aromatic imide polymer asymmetric membrane UBE INDUSTRIES, LTD. (JP) 1990-10-10 EP disclosed
US-4959151-A Pervaporation method of separating liquid organic compound mixture through aromatic imide polymer asymmetric membrane UBE INDUSTRIES (JP) 1990-09-25 US disclosed
EP-0361377-A2 Pervaporation method of separating liquid organic compound mixture through aromatic imide polymer asymmetric membrane UBE INDUSTRIES, LTD. (JP) 1990-04-04 EP 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 (2 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-20260131280-A1 GAS SEPARATION MEMBRANE UNIT, GAS SEPARATION SYSTEM, AND METHOD FOR PRODUCING ENRICHED GAS SCO2, SLC2A4, STOML2 CYP3A4 1207/4885TSHR 1927/4885PIK3CA 1244/4885
US-20260008003-A1 GAS SEPARATION SYSTEM AND METHOD FOR PRODUCING METHANE-ENRICHED GAS SCO2, MT-CO2, SLC2A4 CYP3A4 435/4885TSHR 1731/4885PIK3CA 1926/4885

“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.