Known targets — ChEMBL curated mechanism
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
The experimentally established mechanism targets of Phosphoric Acid. The predicted profile below is derived independently by chemical similarity — agreement is a validation signal, a miss is honest.
Predicted protein targets (top 2)
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.
| Compound | similarity | top predicted | shared targets | |
|---|---|---|---|---|
| Phosphoric Acid SCHEMBL524759 | 1.00 | SLC34A1 (0.42) | SLC34A1LMNA | |
| Phosphoric Acid SCHEMBL3035545 | 1.00 | SLC34A1 (0.42) | SLC34A1LMNA | |
| Phosphoric Acid SCHEMBL6922656 | 1.00 | SLC34A1 (0.42) | SLC34A1LMNA | |
| Phosphoric Acid SCHEMBL29249632 | 1.00 | SLC34A1 (0.42) | SLC34A1LMNA | |
| Phosphoric Acid SCHEMBL1759265 | 1.00 | SLC34A1 (0.42) | SLC34A1LMNA | |
| Phosphoric Acid SCHEMBL28538221 | 1.00 | SLC34A1 (0.42) | SLC34A1LMNA | |
| Phosphoric Acid SCHEMBL2039064 | 1.00 | SLC34A1 (0.42) | SLC34A1LMNA | |
| Phosphoric Acid SCHEMBL28627992 | 1.00 | SLC34A1 (0.42) | SLC34A1LMNA | |
| Phosphoric Acid SCHEMBL10946730 | 0.94 | SLC34A1 (0.39) | SLC34A1LMNA | |
| Phosphoric Acid SCHEMBL1066888 | 0.94 | SLC34A1 (0.39) | SLC34A1LMNA |
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 30 patents — showing the first 20. claimed = in the patent's claims; disclosed = body only.
| Patent | Title | Assignee | Published | Priority | Filing | Country | Status |
|---|---|---|---|---|---|---|---|
| US-5866644-A | POLYESTER THERMOPLASTIC RESIN, A SUFFICIENT AMOUNT OF DARK PIGMENT FOR FORMING A DARK BACKGROUND COLORATION, A MICA MATERIAL FOR ABSORBING SAID LASER RADIATION, AND AN EFFECTIVE AMOUNT OF A HYDRATED METAL PHOSPHATE | GENERAL ELECTRIC COMPANY (US) | 1999-02-02 | — | — | US | claimed |
| CN-113272917-B | Method for producing gallium radionuclides | 奥斯陆大学 | 2024-05-31 | — | — | CN | disclosed |
| US-20230225953-A1 | REDUCTION OF UNDESIRABLE TASTE NOTES IN ORAL CARE PRODUCTS | FIRMENICH SA (CH) | 2023-07-20 | — | — | US | disclosed |
| EP-3847675-B1 | PROCESS FOR THE PRODUCTION OF GALLIUM RADIONUCLIDES | UNIV OSLO (NO) | 2023-06-07 | — | — | EP | disclosed |
| CN-110087617-B | Oral care compositions | 高露洁-棕榄公司 | 2022-06-17 | — | — | CN | disclosed |
| CN-113735088-B | Zinc-aluminum oxide modified charcoal-loaded phosphate composite material and preparation method and application thereof | 南开大学 | 2022-06-03 | — | — | CN | disclosed |
| US-11339098-B2 | Preparation method of nanometric size metal oxide additives that reduce the temperature of sinterized and/or increase productivity in the manufacture of ceramic parts, improving mechanical properties without affecting the gresification properties of ceramic bodies, tiles or coatings | NANOMATERIALS QUIMICOS AVANZADOS, S.A. DE C.V. (MX) | 2022-05-24 | — | — | US | disclosed |
| CN-113735088-A | Zinc-aluminum oxide modified charcoal-loaded phosphate composite material and preparation method and application thereof | 南开大学 | 2021-12-03 | — | — | CN | disclosed |
| US-20210327603-A1 | PROCESS FOR THE PRODUCTION OF GALLIUM RADIONUCLIDES | UNIVERSITETET I OSLO (NO) | 2021-10-21 | — | — | US | disclosed |
| CN-113272917-A | Method for producing gallium radionuclides | 奥斯陆大学 | 2021-08-17 | — | — | CN | disclosed |
| US-20070125644-A1 | Reduction of the loss of zinc by its reaction with oxygen in galvanized steel and batteries | BOARD OF REGENTS, THE UNIVERSITY OF TEXAS SYSTEM (US) | 2007-06-07 | — | — | US | disclosed |
| WO-2007035432-A2 | REDUCTION OF THE LOSS OF ZINC BY ITS REACTION WITH OXYGEN IN GALVANIZED STEEL AND BATTERIES | BOARD OF REGENTS, THE UNIVERSITY OF TEXAS SYSTEM (US) | 2007-03-29 | — | — | WO | disclosed |
| WO-2001014257-A9 | MICROBIOLOGICAL WATER FILTER | WATERVISIONS INT INC (US) | 2006-07-13 | — | — | WO | disclosed |
| US-20060030631-A1 | Laser markable polymers | SHAH BAKHTIAR A | 2006-02-09 | — | — | US | disclosed |
| US-6957743-B2 | Fluid water is passed through a purification material composed of apatite and absorption media in a fixed binder matrix. | WATERVISIONS INTERNATIONAL, INC. (US) | 2005-10-25 | — | — | US | disclosed |
| US-20030015467-A1 | Microbiological water filter | JOHNSTON ARTHUR W (US) | 2003-01-23 | — | — | US | disclosed |
| EP-1214273-A1 | MICROBIOLOGICAL WATER FILTER | Watervisions International, Inc. (US) | 2002-06-19 | — | — | EP | disclosed |
| WO-2001014257-A1 | MICROBIOLOGICAL WATER FILTER | WATERVISIONS INTERNATIONAL, INC. (US) | 2001-03-01 | — | — | WO | disclosed |
| US-6187192-B1 | WATER CONTAINING BACTERIA AND/OR VIRUSES IS PASSED THROUGH A PURIFICATION MATERIAL COMPOSED OF APATITE AND ABSORPTION MEDIA IN A FIXED BINDER MATRIX | WATERVISIONS INTERNATIONAL, INC. | 2001-02-13 | — | — | US | disclosed |
| US-6180016-B1 | MIXTURE OF APATITE IN BINDER | WATERVISIONS INTERNATIONAL, INC. | 2001-01-30 | — | — | US | disclosed |