84-16-2

Basic information

• Product Name: HEXESTROL
• Synonyms: 3,4-bis(p-hydroxyphenyl)-hexan;alpha,alpha’-diethyl-4,4’dihydroxy-bibenzy;Bibenzyl, alpha,alpha'-diethyl-4,4'-dihydroxy-;Cycloestrol;dihydro-stilbestro;Dihydrostilbestrol;Estra-Plex;Estrifar
• CAS NO: 84-16-2
• Molecular Formula: C₁₈H₂₂O₂
• Molecular Weight: 270.37
• EINECS: 201-518-1
• Product Categories: Aromatics;Intermediates & Fine Chemicals;Pharmaceuticals;Chiral Reagents;Inhibitors
• Mol File: 84-16-2.mol
• Article Data: 6

Chemical Properties

• Melting Point: 186 °C
• Boiling Point: 353.48°C (rough estimate)
• Flash Point: 181.6 °C
• Appearance: crystalline solid
• Density: 1.093
• Refractive Index: 1.4800 (estimate)
• Storage Temp.: Sealed in dry,Room Temperature
• Solubility: almost transparency in Methanol
• PKA: 9.80±0.26(Predicted)
• Merck: 14,4701
• BRN: 3209460
• CAS DataBase Reference: HEXESTROL(CAS DataBase Reference)
• NIST Chemistry Reference: HEXESTROL(84-16-2)
• EPA Substance Registry System: HEXESTROL(84-16-2)

Safety Data

• Hazard Codes: T
• Statements: 45
• Safety Statements: 53-45
• WGK Germany: 2
• RTECS: SL0560850
• Hazardous Substances Data: 84-16-2(Hazardous Substances Data)

Usage

Chemical Properties

Crystalline Solid

Originator

Estra Plex,Rowell,US,1956

Uses

Different sources of media describe the Uses of 84-16-2 differently. You can refer to the following data:
1. Nonsteroidal synthetic estrogen
2. Estrogen; antineoplastic (hormonal).

Manufacturing Process

50 parts by weight of p-hydroxypropiophenone are dissolved in 200 parts by weight of a 12.5% solution of caustic soda and shaken with 350 parts by weight of 3% sodium amalgam. The sodium salt of the pinacol thereby precipitating is reacted with glacial acetic acid, whereby the free pinacol is obtained (MP 205°C to 210°C, after purification 215°C to 217°C). The yield amounts to 95% of the theoretical. The pinacol is suspended in ether and gaseous hydrogen chloride introduced, whereby water separates and the pinacolin formed is dissolved in the ether, from which it is obtained by evaporation as a viscous oil (diacetate of MP 91°C). The yield is quantitative. 40 parts by weight of pinacolin are dissolved in ethyl alcohol and gradually treated with 80 parts by weight of sodium under reflux. The solution is decomposed with water and the pinacolin alcohol formed extracted from the neutalized solution with ether. The pinacolin alcohol is a viscous oil which is characterized by a dibenzoate of MP 172°C. The yield is 95% of the theoretical. 30 parts by weight of pinacolin alcohol are dissolved in 25 parts by weight of glacial acetic acid and heated for 30 minutes to 135°C to 140°C after having added 20 parts by weight of hydroiodic acid (specific gravity = 1.94) and 5 parts by weight of red phosphorus. The whole is filtered, the solution poured into water, extracted with ether and the ether solution washed with bicarbonate. The oil remaining after distilling off the ether is taken up in chloroform, whereby hexoestrol [α,β-(p,p-dihydroxy-diphenyl)-α,β-diethylethane] crystallizes out. MP after recrystallization from benzene: 185°C. Yield: 20%.

Therapeutic Function

Estrogen

InChI:InChI=1/C18H22O2/c1-3-17(13-5-9-15(19)10-6-13)18(4-2)14-7-11-16(20)12-8-14/h5-12,17-20H,3-4H2,1-2H3

Upstream product

• 13029-44-2 Dienol 
• 13029-44-2 dienestrol 
• 4180-23-8 E-1-(4'-methoxyphenyl)prop-1-ene 
• 5349-60-0 1-(4-methoxyphenyl)-1-propanol 
• 1226-42-2 1,2-bis(4-methoxyphenyl)-1,2-ethanedione 
• 130-80-3 Clinestrol 
• 67-56-1 methanol 
• 56-53-1 diethylstilbestrol 
• 84-16-2 dl-hexestrol 
• 5331-23-7 3,4-bis-(4-methoxy-phenyl)-hexan-3-ol 
• 130-79-0 Diethylstilbestrol dimethyl ether 
• 4390-94-7 1,2-bis(4-methoxyphenyl)butanone 
• 70-70-2 4-hydroxypropiophenone 
• 84234-15-1 bis-[1-(4-hydroxy-phenyl)-propylidene]-hydrazine 

Downstream Products

• 119641-53-1 (RS,SR)-α,α'-diethyl-4,4'-bis-((Ξ)-tetrahydropyran-2-yloxy)-bibenzyl 
• 123080-76-2 (RS,SR)-α,α'-diethyl-4,4'-bis-((Ξ)-2-methyl-tetrahydro-pyran-2-yloxy)-bibenzyl 
• 138690-27-4 3,4-bis-(4-butoxy-phenyl)-hexane 
• 36557-18-3 3,4-bis-(4-butyryloxy-phenyl)-hexane 
• 79154-14-6 meso-hexestrol diethyl ether 
• 36614-35-4 3,4-bis-(4-hexanoyloxy-phenyl)-hexane 
• 119851-88-6 meso-3,4-bis-[4-(2-benzyl-3-phenyl-propionyloxy)-phenyl]-hexane 
• 14188-82-0 Cytostatin 
• 55508-15-1 3,3'-Diiodohexestrol 
• 74536-62-2 meso-3,3',5,5'-tetrabromohexestrol 
• 55508-18-4 meso-3,4-bis-(4-hydroxy-3,5-diiodo-phenyl)-hexane 
• 5693-81-2 meso-3.4-bis-(4t-hydroxy-cyclohexyl-(1r))-hexane 
• 5693-81-2 (+/-)-erythro-3-(4c-hydroxy-cyclohexyl-(1r))-4-(4t-hydroxy-cyclohexyl-(1r))-hexane 
• 66877-40-5 3,3'-Dinitrohexestrol 

Relevant articles and documents

Photocatalytic Upgrading of Lignin Oil to Diesel Precursors and Hydrogen

Producing renewable biofuels from biomass is a promising way to meet future energy demand. Here, we demonstrated a lignin to diesel route via dimerization of the lignin oil followed by hydrodeoxygenation. The lignin oil undergoes C?C bond dehydrogenative coupling over Au/CdS photocatalyst under visible light irradiation, co-generating diesel precursors and hydrogen. The Au nanoparticles loaded on CdS can effectively restrain the recombination of photogenerated electrons and holes, thus improving the efficiency of the dimerization reaction. About 2.4 mmol gcatal?1 h?1 dimers and 1.6 mmol gcatal?1 h?1 H2 were generated over Au/CdS, which is about 12 and 6.5 times over CdS, respectively. The diesel precursors are finally converted into C16–C18 cycloalkanes or aromatics via hydrodeoxygenation reaction using Pd/C or porous CoMoS catalyst, respectively. The conversion of pine sawdust to diesel was performed to demonstrate the feasibility of the lignin-to-diesel route.

Cobalt-catalyzed arylzincation of alkynes

Cobalt(II) bromide catalyzes arylzincation of alkynes with arylzinc iodide·lithium chloride complexes in acetonitrile. The scope of the arylzincation is wide enough to use unfunctionalized alkynes, such as 6-dodecyne, as well as arylacetylenes. The inherent functional group compatibility of arylzinc reagents allows preparation of various functionalized styrene derivatives. The reaction is applicable to the efficient and stereoselective synthesis of a synthetic estrogen and its derivative.

Estrogen receptor-β potency-selective ligands: Structure-activity relationship studies of diarylpropionitriles and their acetylene and polar analogues

Through an effort to develop novel ligands that have subtype selectivity for the estrogen receptors alpha (ERα) and beta (ERβ), we have found that 2,3-bis(hydroxyphenyl)propionitrile (DPN) acts as an agonist on both ER subtypes, but has a 70-fold higher relative binding affinity and 170-fold higher relative potency in transcription assays with ERβ than with ERα. To investigate the ERβ affinity- and potency-selective character of this DPN further, we prepared a series of DPN analogues in which both the ligand core and the aromatic rings were modified by the repositioning of phenolic hydroxy groups and by the addition of alkyl substituents and nitrile groups. We also prepared other series of DPN analogues in which the nitrile functionality was replaced with acetylene groups or polar functions, to mimic the linear geometry or polarity of the nitrile, respectively. To varying degrees, all of the analogues show preferential binding affinity for ERβ (i.e., they are ERβ affinity-selective), and many, but not all of them, are also more potent in activating transcription through ERβ than through ERα (i.e., they are ERβ potency-selective). meso-2,3-Bis(4-hydroxyphenyl)succinonitrile and dl-2,3-bis(4-hydroxyphenyl)succinonitrile are among the highest ERβ affinity-selective ligands, and they have an ERβ potency selectivity that is equivalent to that of DPN. The acetylene analogues have higher binding affinities but somewhat lower selectivities than their nitrile counterparts. The polar analogues have lower affinities, and only the fluorinated polar analogues have substantial affinity selectivities. This study suggests that, in this series of ligands, the nitrile functionality is critical to ERβ selectivity because it provides the optimal combination of linear geometry and polarity. Furthermore, the addition of a second nitrile group β to the nitrile in DPN or the addition of a methyl substitutent at an ortho position on the β-aromatic ring increases the affinity and selectivity of these compounds for ERβ. These ERβ-selective compounds may prove to be valuable tools in understanding the differences in structure and biological function of ERα and ERβ.