Details of Natural Product (NP) | NPcVar

General Information of Natural Product (ID: NP1041)
Natural Product Name		Stearic Acid
Synonyms		stearic acid; Octadecanoic acid; 57-11-4; Stearophanic acid; n-Octadecanoic acid; Cetylacetic acid; Pearl stearic; Stearex Beads; Octadecansaeure; Stearinsaeure; Vanicol; 1-Heptadecanecarboxylic acid; Century 1240; Industrene R; Glycon DP; Glycon TP; Hydrofol Acid 150; Humko Industrene R; Dar-chem 14; Formula 300; Hydrofol 1895; Hystrene 7018; Hystrene 9718; Glycon S-80; Glycon S-90; Hydrofol acid 1655; Hydrofol acid 1855; Tegostearic 254; Tegostearic 255; Tegostearic 272; Hystrene 80; octadecoic acid; Industrene 5016; Hystrene S-97; Hystrene T-70; Emersol 120; Emersol 132; Hystrene 4516; Hystrene 5016; Groco 54; Groco 55; Groco 55L; Groco 58; Groco 59; Glycon S-70; Industrene 8718; Industrene 9018; Kam 1000; Emersol 150; Steric acid; Neo-Fat 18-53; Neo-Fat 18-54; Neo-Fat 18-59; Neo-Fat 18; Acidum stearinicul; Caswell No. 801D; HY-Phi 1199; HY-Phi 1205; HY-Phi 1303; HY-Phi 1401; Neo-Fat 18-S; C18:0; Kam 2000; Kam 3000; FEMA No. 3035; Oktadekansaeure; Neo-Fat 18-55; Neo-Fat 18-61; acide stearique; Barolub FTA; PD 185; acide octadecanoique; NAA 173; Century 1210; Hydrofol Acid 150 (VAN); CCRIS 2305; Prifac 2918; HSDB 2000; Vis-Plus; UNII-4ELV7Z65AP; NSC 25956; Prodhygine; EPA Pesticide Chemical Code 079082; Stearic Acid Cherry; Edenor C18; Stearic acid (TN); CH3-[CH2]16-COOH; Loxiol G 20; Century 1220; Century 1230; Emersol 6349; AI3-00909; Lunac S 20; Lunac S 40; WO 2 (fatty acid); Hydrofol Acid 1895; Octadecanoic acid, dimer; Bonderlube 235; MFCD00002752; 4ELV7Z65AP; Adeka Fatty Acid SA 910; CHEMBL46403; CHEBI:28842; NSC25956; NSC-25956; NCGC00091596-02; Edenor FHTI; DSSTox_CID_1642; DSSTox_RID_76256; DSSTox_GSID_21642; Stearic acid, pure; Lunac; Stearic Acid (Powder/Beads/Flakes); CAS-57-11-4; Isostearic acid EX; 18639-67-3; Haimaric MKH(R); Prisorine 3501; Prisorine 3502; Prisorine 3508; Emersol 153NF; Emersol 871; Emersol 875; Emery 875D; Emery 871; NSC-261168; Unimac 5680; C-Lube 10; EINECS 200-313-4; Stearic acid [JAN:NF]; BRN 0608585; Stearophanate; Promulsin; Stearex; Tsubaki; n-Octadecanoate; Bassinic acid; Lactaric acid; Proviscol wax; Talgic acid; Kolliwax s fine; Edenor htict-n; 1hmr; 1hmt; 4fnn; Kiri stearic acid; Lunac YA; n-Octadecylic acid; Palmitostearic acid; Stearic acid 70; Stearic acid, CP; Sterene 60b; Sterene 60r; EINECS 250-178-0; F 3 (lubricant); Industrene 4518; Nonsoul SK 1; Pristerene 4900; Pristerene 4904; Pristerene 4910; Pristerene 4916; Pristerene 4963; Pristerene 4981; Pristerene 9429; Pristerene 9559; Pristerine 4989; Hystrene S 97; Hystrene T 70; Edenor ST 1; Sunfat 18S; Emersol 153; Selosol 920; Sterene 460; Industrene 5016K; Purified stearic acid; Stearic Acid 110; Stearic Acid 120; Stearic Acid 420; Dervacid 3155; Hystrene 9718NF; Kortacid 1895; Radiacid 0427; Edenor ST 20; Lunac 30; Serfax MT 90; Stearic acid_ravikumar; Unister NAA 180; Adeka sa 300; Century 1224; Edenor HT-JG 60; Lunac S 90KC; Stearic acid (8CI); Stearic acid, puriss.; Hyfac 410; Hyfac 420; Hyfac 421; Hyfac 422; Hystrene 7018 FG; Hystrene 9718NFFG; Lunac S 30; Lunac S 50; Lunac S 90; Lunac S 98; Prifac 5905; 3v2p; 875D; 1-Heptadecanecarboxylate; Hydrogenated tallow acid; Industrene 7018 FG; Stearic Acid NF Powder; AFCO-Chem B 65; Hydrogenated tallow acids; Stearic Acid - 65%; Stearic Acid - 70%; Stearic Acid 153 NF; Heptadecanecarboxylic acid; Stearic Acid & Glycerin; Edenor C 18/98; Tallow acid, hydrogenated; Neo-fat 18-57; Neo-fat 18-58; S 300 (fatty acid); Octadecanoic acid (9CI); Stearic acid, >=98%; SCHEMBL659; Hystrene 9718 NF FG; SA 400 (fatty acid); bmse000485; Stearic Acid, High Purity; Stearic acid-[13C18]; Stearic acid-2-[13C]; EC 200-313-4; Emery 400 (Salt/Mix); Tallow, acids, hydrogenated; Stearic acid (JP15/NF); Stearic acid (JP17/NF); Stearic Acid Triple-Pressed; Triple Pressed Stearic Acid; Emersol 110 (Salt/Mix); Stearic Acid - High Purity; 4-02-00-01206 (Beilstein Handbook Reference); WLN: QV17; Agar Agar Type K-100 NF; Hydrogenated tallow acid, beef; Hydrogenated tallow fatty acids; Stearic Acid - Triple Pressed; 17FA; GTPL3377; WO 2; Stearic Acid (Fragrance Grade); Stearic Acid High Purity 90%; Stearic acid-1,2-[13C2]; DTXSID8021642; Fatty acids, hydrogenated tallow; Tallow fatty acids, hydrogenated; Tallow, hydrogenated fatty acids; Nonsoul SN 1 (Sodium salt); S 30C S 30C (fatty acid); SNA-2000 (Sodium salt); Stearic acid, analytical standard; VLZ 200; Stearic Acid High Purity 90% V; Stearic Acid Flake 132 NF Flake; Stearic acid, reagent grade, 95%; HY-B2219; Stearic Acid 400 (Rubber Grade); ZINC4978673; Tox21_111154; Tox21_201887; Tox21_300562; BBL012224; BDBM50240485; LMFA01010018; s5733; SA 200; Stearic acid, >=95%, FCC, FG; STL163565; AKOS005716958; Tox21_111154_1; CCG-267314; DB03193; FA 1655; MCULE-5127577640; NSC 261168; T16-55F; NCGC00091596-01; NCGC00091596-03; NCGC00091596-04; NCGC00091596-05; NCGC00254456-01; NCGC00259436-01; E570; I727; VS-03242; Stearic acid, puriss., >=98.5% (GC); Stearic acid, SAJ first grade, >=90.0%; BB 0268543; CS-0021598; FT-0674650; FT-0689088; G 270; S 300; S0163; Stearic acid, SAJ special grade, >=95.0%; Stearic acid, Vetec(TM) reagent grade, 94%; 400JB9103-88; A 1760; C01530; D00119; EC 250-178-0; Stearic acid 50, tested according to Ph.Eur.; Vegetable Stearic Acid 7036 FG, Kosher, NF; Q209685; SR-01000944717; Melting Point Standard 69-71C, analytical standard; SR-01000944717-1; Stearic acid, Grade I, >=98.5% (capillary GC); Stearic acid, SAJ first grade, >=90.0%, powder; F0001-1489; Stearic acid, certified reference material, TraceCERT(R); Z955123678; UNII-13FB83DEYU component QIQXTHQIDYTFRH-UHFFFAOYSA-N; UNII-44NH37HHP9 component QIQXTHQIDYTFRH-UHFFFAOYSA-N; UNII-5U9XZ261ER component QIQXTHQIDYTFRH-UHFFFAOYSA-N; UNII-7N137Q0QYJ component QIQXTHQIDYTFRH-UHFFFAOYSA-N; UNII-96GS7P39SN component QIQXTHQIDYTFRH-UHFFFAOYSA-N; UNII-B6G0Y5Z616 component QIQXTHQIDYTFRH-UHFFFAOYSA-N; UNII-D1CZ545P7Z component QIQXTHQIDYTFRH-UHFFFAOYSA-N; UNII-HBA528N3PW component QIQXTHQIDYTFRH-UHFFFAOYSA-N; UNII-J505W0PXX8 component QIQXTHQIDYTFRH-UHFFFAOYSA-N; UNII-MO7HV04S9Y component QIQXTHQIDYTFRH-UHFFFAOYSA-N; UNII-ODL221H4AM component QIQXTHQIDYTFRH-UHFFFAOYSA-N; UNII-Q8Y7S3B85M component QIQXTHQIDYTFRH-UHFFFAOYSA-N; UNII-X33R8U0062 component QIQXTHQIDYTFRH-UHFFFAOYSA-N; CD7993EA-AD14-452A-A907-33376CC98790; Stearic acid, European Pharmacopoeia (EP) Reference Standard; UNII-79P21R4317 component QIQXTHQIDYTFRH-UHFFFAOYSA-N; Stearic acid, United States Pharmacopeia (USP) Reference Standard; Stearic Acid, Pharmaceutical Secondary Standard; Certified Reference Material Click to Show/Hide
Formula		C₁₈H₃₆O₂
Weight		284.5
Structure
Structure		3D Structure Download			2D Structure Download
InChI		InChI=1S/C18H36O2/c1-2-3-4-5-6-7-8-9-10-11-12-13-14-15-16-17-18(19)20/h2-17H2,1H3,(H,19,20)
InChI Key		QIQXTHQIDYTFRH-UHFFFAOYSA-N
Isomeric SMILES		CCCCCCCCCCCCCCCCCC(=O)O
Canonical SMILES		CCCCCCCCCCCCCCCCCC(=O)O
External Links		PubChem ID		5281
		CAS ID		1957-11-04
		NPASS ID		NPC209970
		HIT ID		C0416
		CHEMBL ID		CHEMBL46403
NP Activity Charts		Click to show/hide
Activity Info

The Content Variation of Natural Product Induced by Different Factor(s)
Species Name: Artemisia annua
					Factor Name: Cultivar Comparison																																																																[1]
Species Info Factor Info
Experiment Detail																						Populations of A. annua cultivar 'Jeevanraksha' and accession Suraksha were grown in the experimental field plot of the Institute at New Delhi. The seeds were sown in January 2004, seedlings transplanted in late February 2004 and aerial parts (flowers, leaves and stems from the upper 0.5 m of crop canopy) sampled in late October 2004. Click to Show/Hide
Factor Function																						Ninety-seven compounds comprising 91.3% of the total oil of 'Jeevanraksha' were identified. Forty-three monoterpenes (56.6%), 32 sesquiterpenes (31.1%), and 2 diterpenes (0.2%) comprised bulk of the oil (87.9%). The oil was devoid of artemisia ketone and contained camphor (13.5%), 1,8-cineole (9.4%), trans-sabinol (7.1%), p-mentha-1(7), 5-dien-2-ol (6.3%), myrcene (4.7%), germacrene D (4.4%), (E)-beta-farnesene (3.9%), beta-caryophyllene (3.7%), dihydroartemisinic lactone (3.0%) and p-cymene (2.0%) as the major constituents. Eighty-six compounds representing 93.3% of the composition were identified in the Suraksha oil. This oil contained artemisia ketone (47%), 1,8-cineole (8.4%), camphor (5.9%) and alpha-pinene (5.2%) as the major components. Click to Show/Hide
Factor																																								Part										Location																				NP Content
Artemisia annua cv. Jeevanraksha																																								Aerial parts										India																				NP Content: <0.05 %
Species Name: Lagenaria siceraria
					Factor Name: Cultivar Comparison; Developmental Stage Variation																																																																[2]
Species Info Factor Info
Experiment Detail																						The experiment was conducted from July to November 2007 at the experimental station of the University of Abobo-Adjame (Abidjan, Ivory Coast) (latitude between 5° 17′ and 5° 31′ N, longitude between 3° 45′ and 4° 22′ W). During this period, rainfall, mean temperature and humidity varied from 5.33 to 192.28 mm, from 23.3 to 26.4 ℃ and from 86.7 to 96% respectively. Open-pollinated accessions from two edible-seeded L. siceraria (Molina) Standl. cultivars recognisable by their fruit shape (oval or round) were used. Seeds from the round fruit cultivar are characterised by the presence of a cap on the distal side, whereas those from the oval fruit cultivar lack this cap. Differences are also noted between the two cultivars in their rates of seed germination and seedling emergence, the best performances being observed for the round fruit cultivar. However, the visual changes in fruits during their growth as well as at plant whiteness are the same in the two cultivars. Both round and oval fruit cultivars were obtained from the cucurbit germplasm of the university, where they are identified by the alphanumeric codes NI354 and NI260 respectively. Each cultivar was sown on a plot of 20 m × 20 m in 12 holes. Female flowers were tagged after their closure in order to monitor the fruits until the date determined for harvesting. Fruits were harvested at three stages of maturation: (i) 30 days after fruit set (DAFS), at which stage fruits do not grow any more; (ii) 50 DAFS, at which stage the colour of fruits no longer changes; (iii) complete plant whiteness (CPW), indicating the end of plant growth. For each of the three fruit maturation times, five fruits per cultivar were selected. The seeds were extracted from each fruit, washed and dried in the sun for 1 week. After drying, the seeds of all five fruits were grouped and decorticated to obtain seed kernels that were used for analysis. Click to Show/Hide
Factor Function																						The results of this study showed that there were considerable modifications during fruit maturation in the oilseed gourd L. siceraria and that chemical characterisation of the seed kernel is important for controlling the processes of maturation. The two cultivars of L. siceraria studied should be harvested at 50 days after fruit set (DAFS) owing to their high contents of proteins, lipids, energy and minerals at this stage. At 50 DAFS the leaves of L. siceraria were still green and could serve as a source of nutrients for livestock. However, to obtain the best amino acid composition and biological values of proteins, the round and oval berry cultivars should be harvested at 30 DAFS and complete plant whiteness (CPW) respectively. At these stages their proteins could be used as a supplement. The low digestibility of the proteins at this stage could be improved by appropriate technological treatment. Click to Show/Hide
Factor																																								Part										Location																				NP Content
Lagenaria siceraria cv. Round berry + Harvesting time: 30 days after fruit set																																								Seed kernels										Abidjan, Cote d'lvoire																				NP Content: 83.1 ± 0.1 g/kg dry matter
Lagenaria siceraria cv. Round berry + Harvesting time: 50 days after fruit set																																								Seed kernels										Abidjan, Cote d'lvoire																				NP Content: 75.1 ± 0.0 g/kg dry matter
Lagenaria siceraria cv. Round berry + Harvesting time: complete plant whiteness stage																																								Seed kernels										Abidjan, Cote d'lvoire																				NP Content: 77.6 ± 0.2 g/kg dry matter
Lagenaria siceraria cv. Oval berry + Harvesting time: 30 days after fruit set																																								Seed kernels										Abidjan, Cote d'lvoire																				NP Content: 75.4 ± 0.1 g/kg dry matter
Lagenaria siceraria cv. Oval berry + Harvesting time: 50 days after fruit set																																								Seed kernels										Abidjan, Cote d'lvoire																				NP Content: 64.6 ± 0.0 g/kg dry matter
Lagenaria siceraria cv. Oval berry + Harvesting time: complete plant whiteness stage																																								Seed kernels										Abidjan, Cote d'lvoire																				NP Content: 62.9 ± 0.1 g/kg dry matter

References
1	Volatile Metabolite Compositions of the Essential Oil from Aerial Parts of Ornamental and Artemisinin Rich Cultivars of Artemisia annua
2	Effect of harvest time on seed oil and protein contents and compositions in the oleaginous gourd Lagenaria siceraria (Molina) Standl

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