207127-50-2

Usage

Uses

Used in Analytical Chemistry:
cis-Decahydro-1-naphthol is used as a reagent in the solid-phase microextraction (SPME) and membrane-assisted solvent extraction (MASE) methods for the detection of 2-methylisoborneol and geosmin in aqueous samples. These methods are employed to analyze trace amounts of odor-causing compounds in water, which are essential for monitoring water quality and ensuring safety for consumption and environmental health.
In the SPME method, cis-Decahydro-1-naphthol acts as a selective adsorbent for the target compounds, allowing for their extraction from the aqueous phase onto a solid-phase fiber. This technique offers advantages such as simplicity, sensitivity, and minimal sample preparation, making it a popular choice for analyzing trace organic compounds in various matrices.
In the MASE method, cis-Decahydro-1-naphthol is incorporated into a supported liquid membrane, which serves as a barrier between the aqueous sample and the organic solvent used for extraction. This approach enhances the selectivity and efficiency of the extraction process, enabling the detection of trace levels of 2-methylisoborneol and geosmin in water samples.
Overall, the use of cis-Decahydro-1-naphthol in SPME and MASE methods demonstrates its potential as a valuable tool in analytical chemistry for the detection and quantification of odor-causing compounds in water, contributing to the assessment and maintenance of water quality.

Upstream product

• 493-01-6 cis-decalin 
• 4832-16-0 1-decalone 
• 825-51-4 decahydronaphthalen-2-ol 
• 90-15-3 α-naphthol 
• 29587-92-6 cis-1,2-epoxy-cyclodecane 
• 2001-49-2 trans-1,2,3,4,4a,5,6,8a-octahydronaphthalene 
• 21370-71-8 trans-1-decalone 
• 7647-01-0 hydrogenchloride 
• 7732-18-5 water 
• 64-19-7 acetic acid 
• 2384-64-7 (+/-)-2cis-Dimethylamino-1trans-hydroxy-(9refH,10transH)-dekalin 
• 67-56-1 methanol 
• 56-23-5 tetrachloromethane 
• 93-59-4 Perbenzoic acid 

Downstream Products

• 93477-80-6 carbanilic acid-(decahydro-naphthyl-(1))-ester 
• 101787-81-9 phenylglyoxylic acid-((4aR)-(4ar,8at)-decahydro[1t]naphthyl ester) 
• 2384-57-8 (+/-)-phthalic acid mono-((4arH.8atH)-decahydro-naphthyl-(1c)-ester) 
• 4029-75-8 p-Toluolsulfonat des 1t.9c.10t-α-Dekalols (F: 62grad) 
• 54422-08-1 1t.9c.10t-α-Dekalol 
• 6240-39-7 (+/-)-(4ar,8at)-decahydro-[1t]naphthoic acid 
• 2384-57-8 (+/-)-phthalic acid mono-((4arH.8atH)-decahydro-naphthyl-(1t)-ester) 
• 4029-75-8 (+/-)-toluene-4-sulfonic acid-((4ar,8at)decahydro[1t]naphthyl ester) 
• 1123-79-1 (+/-)-cis-1,2,3,4,4a,5,6,8a-octahydro-naphthalene 
• 2384-57-8 (+/-)-phthalic acid mono-((4arH.8acH)-decahydro-naphthyl-(1t)-ester) 
• 4029-75-8 (+/-)-toluene-4-sulfonic acid-((4ar,8ac)decahydro[1t]naphthyl ester) 
• 2384-57-8 (+/-)-phthalic acid mono-((4arH.8acH)-decahydro-naphthyl-(1c)-ester) 
• 54289-26-8 cis-1-decalyl p-nitrobenzoate 
• 4029-75-8 1c.9c.10c-α-Decalol-p-toluolsulfonat 

Relevant academic research and scientific papers

Mechanism of the Transannular Cyclization of 5-Cyclodecynone

Acid-catalyzed intramolecular cyclization of 5-cyclodecynone (1) under a variety of conditions gives bicyclo-1(6)-decen-2-one (8) as the only product.In earlier reports the reaction was formulated as involving triple-bond participation with a polarized carbonyl group to give a vinyl cation, followed by external attack by a nucleophile.Studies of the rearrangement using Lewis acids in aprotic solvents, taking care to exclude water and moist air during workup, have shown that the oxygen atom in the starting acetylenic ketone 1 is the same as that in the bicyclic product 8.When the reaction was carried out with HCl in a solvent of methanol-H2(18)O, oxygen-18 incorporation in the final product was not significantly above exchange levels observed when the bicyclic ketone itself was treated with methanol-H2(18)O under similar conditions.A mechanism that will account for these observations is presented.

Enzymatic desymmetrization of meso-1α,4α-dihydroxy-cis-decalins

The stereoselective acetylation of meso-decalindiols 1 and 2 by vinyl acetate in the presence of Candida antarctica lipase gave monoester (1R,4S,4aR,8aS)-5 and (1R,4S,4aR,8aS)-6 in high enantiomeric excess (ee ≥98%). The hydrolysis of the corresponding meso-diacetates 3 and 4 in the presence of porcine liver esterase in phosphate buffer provided the opposite enantiomers.

Aromatic compound hydrogenation and hydrodeoxygenation method and application thereof

The invention belongs to the technical field of medicines, and discloses an aromatic compound hydrogenation and hydrodeoxygenation method under mild conditions and application of the method in hydrogenation and hydrodeoxygenation reactions of the aromatic compounds and related mixtures. Specifically, the method comprises the following steps: contacting the aromatic compound or a mixture containing the aromatic compound with a catalyst and hydrogen with proper pressure in a solvent under a proper temperature condition, and reacting the hydrogen, the solvent and the aromatic compound under the action of the catalyst to obtain a corresponding hydrogenation product or/and a hydrodeoxygenation product without an oxygen-containing substituent group. The invention also discloses specific implementation conditions of the method and an aromatic compound structure type applicable to the method. The hydrogenation and hydrodeoxygenation reaction method used in the invention has the advantages of mild reaction conditions, high hydrodeoxygenation efficiency, wide substrate applicability, convenient post-treatment, and good laboratory and industrial application prospects.

Insights into the Substrate Promiscuity of Novel Hydroxysteroid Dehydrogenases

Hydroxysteroid dehydrogenases (HSDHs) are valuable biocatalysts for the regio- and stereoselective modification of steroids, bile acids and other steroid derivatives. In this work, we investigated the substrate promiscuity of this highly selective class of enzymes. In order to reach this goal, a preliminary search of HSDH homologues in in-house or public available (meta)genomes was carried out. Eight novel NAD(H)-dependent HSDHs, showing either 7α-, 7β-, or 12α-HSDH activity, and including, for the first time, enzymes from extremophilic microorganisms, were identified, recombinantly produced, and characterized. Among the novel HSDHs, four highly active (up to 92 U mg?1) NAD(H)-dependent 7β-HSDHs showing negligible similarity towards previously described 7β-HSDHs, were discovered. These enzymes, along with previously characterized HSDHs, were tested as biocatalysts for the stereoselective reduction of a panel of substrates including two α-ketoesters of pharmaceutical interest and selected ketones that partially resemble the structural features of steroids. All the reactions were coupled with a suitable cofactor regeneration system. Regarding the α-ketoesters, nearly all of the tested HSDHs showed a good activity toward the selected substrates, yielding the reduced α-hydroxyester with up to 99% conversions and enantiomeric excesses. On the other hand, only the 7β-HSDHs from Collinsella aerofaciens and Clostridium absonum showed appreciable activity toward more complex ketones, i. e., (±)-trans-1-decalone, but with interesting as well as different selectivity. (Figure presented.).

Chemoselective Oxidation of Equatorial Alcohols with N-Ligated λ3-Iodanes

The site-selective and chemoselective functionalization of alcohols in complex polyols remains a formidable synthetic challenge. Whereas significant advancements have been made in selective derivatization at the oxygen center, chemoselective oxidation to the corresponding carbonyls is less developed. In cyclic systems, whereas the selective oxidation of axial alcohols is well known, a complementary equatorial selective process has not yet been reported. Herein we report the utility of nitrogen-ligated (bis)cationic λ3-iodanes (N-HVIs) for alcohol oxidation and their unprecedented levels of selectivity for the oxidation of equatorial over axial alcohols. The conditions are mild, and the simple pyridine-ligated reagent (Py-HVI) is readily synthesized from commercial PhI(OAc)2 and can be either isolated or generated in situ. Conformational selectivity is demonstrated in both flexible 1,2-substituted cyclohexanols and rigid polyol scaffolds, providing chemists with a novel tool for chemoselective oxidation.

(Poly)cationic λ3-Iodane-Mediated Oxidative Ring Expansion of Secondary Alcohols

Herein, a simplified approach to the synthesis of medium-ring ethers through the electrophilic activation of secondary alcohols with (poly)cationic λ3-iodanes (N-HVIs) is reported. Excellent levels of selectivity are achieved for C–O bond migration over established α-elimination pathways, enabled by the unique reactivity of a novel 2-OMe-pyridine-ligated N-HVI. The resulting hexafluoroisopropanol (HFIP) acetals are readily derivatized with a range of nucleophiles, providing a versatile functional handle for subsequent manipulations. The utility of this methodology for late-stage natural product derivatization was also demonstrated, providing a new tool for diversity-oriented synthesis and complexity-to-diversity (CTD) efforts. Preliminary mechanistic investigations reveal a strong effect of alcohol conformation on the reactive pathway, thus providing a predictive power in the application of this approach to complex molecule synthesis.

Microwave-assisted isomerizations of epoxides to allylic alcohols

The present work reports a study on the isomerization reactions of several alkyl epoxides to the corresponding allylic alcohols or bicyclic alcohols under microwave irradiation. The reaction occurred in the presence of lithium diisopropylamide as a base and different experimental conditions in terms of solvent, amount of the base, times and temperatures. The traditional heating with an oil-bath and the use of alternative organometallic bases, as the Lochmann-Schlosser bases, have been furthermore compared with the microwave heating. The results obtained show that the use of microwave irradiations on promoting the isomerization of epoxides gives access to a series of synthetically useful products, among which allylic alcohols and bicyclic alcohols, depending on the starting substrate.

Regioselective and Chemoselective Reduction of Naphthols Using Hydrosilane in Methanol: Synthesis of the 5,6,7,8-Tetrahydronaphthol Core

A regioselective and chemoselective method for catalytic synthesis of biologically interesting 5,6,7,8-tetrahydronaphthols by reduction of naphthols was described. The side aromatic hydrocarbons in naphthols were site-selectively reduced, using hydrosilanes in methanol, allowing for retaining functional phenol scaffolds intact. It presents a rare example of using low-cost and air-stable hydrosilane for catalytic reduction of unactivated aromatic hydrocarbons under mild conditions. This reaction is scalable and proceeds in high selectivity without the formation of 1,2,3,4-tetrahydronaphthol byproducts with toleration of sensitive functionalities such as bromide, chloride, fluoride, ketone, ester, and amide.

Alkane oxidation catalysed by a self-folded multi-iron complex

A preorganised ligand scaffold is capable of coordinating multiple Fe(II) centres to form an electrophilic CH oxidation catalyst. This catalyst oxidises unactivated hydrocarbons including simple, linear alkanes under mild conditions in good yields with selectivity for the oxidation of secondary CH bonds. Control complexes containing a single metal centre are incapable of oxidising unstrained linear hydrocarbons, indicating that participation of multiple centres aids the CH oxidation of challenging substrates.

Selective Catalytic Hydrogenation of Arenols by a Well-Defined Complex of Ruthenium and Phosphorus-Nitrogen PN3-Pincer Ligand Containing a Phenanthroline Backbone

Selective catalytic hydrogenation of aromatic compounds is extremely challenging using transition-metal catalysts. Hydrogenation of arenols to substituted tetrahydronaphthols or cyclohexanols has been reported only with heterogeneous catalysts. Herein, we demonstrate the selective hydrogenation of arenols to the corresponding tetrahydronaphthols or cyclohexanols catalyzed by a phenanthroline-based PN3-ruthenium pincer catalyst.