Record Information |
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Version | 1.0 |
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Created at | 2022-09-10 11:33:44 UTC |
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Updated at | 2022-09-10 11:33:45 UTC |
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NP-MRD ID | NP0299627 |
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Secondary Accession Numbers | None |
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Natural Product Identification |
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Common Name | (6s,11ar)-11a-hydroxy-3,6,10-trimethyl-4h,6h,7h,8h,11h-cyclodeca[b]furan-2,5-dione |
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Description | Curdionolide A belongs to the class of organic compounds known as germacranolides and derivatives. These are sesquiterpene lactones with a structure based on the germacranolide skeleton, characterized by a gamma lactone fused to a 1,7-dimethylcyclodec-1-ene moiety. (6s,11ar)-11a-hydroxy-3,6,10-trimethyl-4h,6h,7h,8h,11h-cyclodeca[b]furan-2,5-dione is found in Curcuma aromatica. It was first documented in 2022 (PMID: 36116068). Based on a literature review a significant number of articles have been published on Curdionolide A (PMID: 36116067) (PMID: 36116066) (PMID: 36116065) (PMID: 36116064). |
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Structure | C[C@H]1CC\C=C(C)\C[C@@]2(O)OC(=O)C(C)=C2CC1=O InChI=1S/C15H20O4/c1-9-5-4-6-10(2)13(16)7-12-11(3)14(17)19-15(12,18)8-9/h5,10,18H,4,6-8H2,1-3H3/b9-5+/t10-,15+/m0/s1 |
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Synonyms | Not Available |
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Chemical Formula | C15H20O4 |
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Average Mass | 264.3210 Da |
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Monoisotopic Mass | 264.13616 Da |
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IUPAC Name | (6S,11aR)-11a-hydroxy-3,6,10-trimethyl-2H,4H,5H,6H,7H,8H,11H,11aH-cyclodeca[b]furan-2,5-dione |
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Traditional Name | (6S,11aR)-11a-hydroxy-3,6,10-trimethyl-4H,6H,7H,8H,11H-cyclodeca[b]furan-2,5-dione |
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CAS Registry Number | Not Available |
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SMILES | C[C@H]1CC\C=C(C)\C[C@@]2(O)OC(=O)C(C)=C2CC1=O |
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InChI Identifier | InChI=1S/C15H20O4/c1-9-5-4-6-10(2)13(16)7-12-11(3)14(17)19-15(12,18)8-9/h5,10,18H,4,6-8H2,1-3H3/b9-5+/t10-,15+/m0/s1 |
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InChI Key | SCOXWKWLFRIELY-CJXNBAGQSA-N |
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Experimental Spectra |
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| Not Available | Predicted Spectra |
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| Spectrum Type | Description | Depositor ID | Depositor Organization | Depositor | Deposition Date | View |
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1D NMR | 13C NMR Spectrum (1D, 25 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum | 1D NMR | 1H NMR Spectrum (1D, 100 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum | 1D NMR | 13C NMR Spectrum (1D, 252 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum | 1D NMR | 1H NMR Spectrum (1D, 1000 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum | 1D NMR | 13C NMR Spectrum (1D, 50 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum | 1D NMR | 1H NMR Spectrum (1D, 200 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum | 1D NMR | 13C NMR Spectrum (1D, 75 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum | 1D NMR | 1H NMR Spectrum (1D, 300 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum | 1D NMR | 13C NMR Spectrum (1D, 101 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum | 1D NMR | 1H NMR Spectrum (1D, 400 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum | 1D NMR | 13C NMR Spectrum (1D, 126 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum | 1D NMR | 1H NMR Spectrum (1D, 500 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum | 1D NMR | 13C NMR Spectrum (1D, 151 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum | 1D NMR | 1H NMR Spectrum (1D, 600 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum | 1D NMR | 13C NMR Spectrum (1D, 176 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum | 1D NMR | 1H NMR Spectrum (1D, 700 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum | 1D NMR | 13C NMR Spectrum (1D, 201 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum | 1D NMR | 1H NMR Spectrum (1D, 800 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum | 1D NMR | 13C NMR Spectrum (1D, 226 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum | 1D NMR | 1H NMR Spectrum (1D, 900 MHz, H2O, predicted) | Wishart Lab | Wishart Lab | David Wishart | 2021-06-20 | View Spectrum |
| Chemical Shift Submissions |
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| Not Available | Species |
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Species of Origin | |
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Chemical Taxonomy |
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Description | Belongs to the class of organic compounds known as germacranolides and derivatives. These are sesquiterpene lactones with a structure based on the germacranolide skeleton, characterized by a gamma lactone fused to a 1,7-dimethylcyclodec-1-ene moiety. |
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Kingdom | Organic compounds |
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Super Class | Lipids and lipid-like molecules |
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Class | Prenol lipids |
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Sub Class | Terpene lactones |
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Direct Parent | Germacranolides and derivatives |
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Alternative Parents | |
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Substituents | - Germacranolide
- Germacrane sesquiterpenoid
- Sesquiterpenoid
- 2-furanone
- Dihydrofuran
- Enoate ester
- Alpha,beta-unsaturated carboxylic ester
- Cyclic ketone
- Lactone
- Ketone
- Hemiacetal
- Carboxylic acid ester
- Oxacycle
- Monocarboxylic acid or derivatives
- Carboxylic acid derivative
- Organoheterocyclic compound
- Organooxygen compound
- Hydrocarbon derivative
- Organic oxide
- Organic oxygen compound
- Carbonyl group
- Aliphatic heteropolycyclic compound
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Molecular Framework | Aliphatic heteropolycyclic compounds |
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External Descriptors | Not Available |
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Physical Properties |
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State | Not Available |
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Experimental Properties | Property | Value | Reference |
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Melting Point | Not Available | Not Available | Boiling Point | Not Available | Not Available | Water Solubility | Not Available | Not Available | LogP | Not Available | Not Available |
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Predicted Properties | |
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General References | - Anraku T: Anoxia/reoxygenation enhances spontaneous contractile activity via TRPA1 channel and COX2 activation in isolated rat whole bladder. Neurourol Urodyn. 2022 Sep 18. doi: 10.1002/nau.25045. [PubMed:36116068 ]
- DeLong JP, Cressler CE: Stochasticity directs adaptive evolution toward nonequilibrium evolutionary attractors. Ecology. 2022 Sep 18:e3873. doi: 10.1002/ecy.3873. [PubMed:36116067 ]
- Liu H, Shu F, Xu H, Ji C, Wang Y, Lou X, Luo P, Xiao S, Xia Z, Lv K: Ablative fractional carbon dioxide laser improves quality of life in patients with extensive burn scars: A nested case-control study. Lasers Surg Med. 2022 Sep 18. doi: 10.1002/lsm.23603. [PubMed:36116066 ]
- Forcillo J, Robert-Halabi M, Soulez G, Potvin J: Transcatheter occlusion of a left ventricular outflow tract pseudoaneurysm using a "plug and coil" strategy. J Card Surg. 2022 Sep 18. doi: 10.1111/jocs.16963. [PubMed:36116065 ]
- Onur R, Bayrak O, Coskun B, Tahra A, Ocakoglu G, Buyuran G, Mega E, Gungor Ugurlucan F, Ozturk GB: Clinical preferences and treatment attitudes among urologists, gynecologists, and geriatricians: An independent online questionnaire survey for comparison of treatment choices in the management of overactive bladder. Neurourol Urodyn. 2022 Sep 18. doi: 10.1002/nau.25050. [PubMed:36116064 ]
- LOTUS database [Link]
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