98719-44-9

Upstream product

• 39850-84-5 Acetic acid 1-[2-((1R,2R,4aS,8aS)-2-hydroxy-2,5,5,8a-tetramethyl-decahydro-naphthalen-1-yl)-ethyl]-1-methyl-allyl ester 
• 6790-58-5 (-)-ambroxide 
• 105014-29-7 8α-hydroxy-13,14,15,16-tetranorlabdan-12-al 
• 67-64-1 acetone 
• 10266-75-8 4-((1S,4aS,8aS)-5,5,8a-trimethyl-2-methylene-decahydronaphthalen-1-yl)butan-2-one 
• 159970-19-1 8α,12-epoxy-13,14,15,16-tetranorlabdan-12-ol acetate 
• 31207-65-5 8α-acetoxy-13,14,15,16-tetranor-12-labdanoic acid 
• 1255210-93-5 C₁₇H₃₁NO₂ 
• 462-66-8 (3E,7E)-4,8,12-trimethyltrideca-3,7,11-trienoic acid 
• 94851-53-3 (3aR,5aS,7R,9aR,9bS)-7-Bromo-3a,6,6,9a-tetramethyl-decahydro-naphtho[2,1-b]furan-2-one 
• 80183-39-7 (3Z,7E)-4,8,12-trimethyltrideca-3,7,11-trienoic acid 
• 64-18-6 formic acid 
• 7664-93-9 sulfuric acid 
• 876503-21-8 (+/-)-4-methyl-6-(2,6,6-trimethyl-cyclohex-2-enyl)-hex-3ξ-enoic acid ethyl ester 

Downstream Products

• 29064-99-1 2-oxosclareolide 
• 74483-92-4 (+)-3-oxo-sclareolide 
• 292643-80-2 (+)-1-oxo-sclareolide 
• 1422446-22-7 C₁₆H₂₆O₃ 
• 150267-49-5 (1R,2R,4aS,8aS)-1-(2-(benzyloxy)ethyl)-2,5,5,8a-tetramethyldecahydronaphthalen-2-ol 

Relevant academic research and scientific papers

Degradation of the side chain of (-)-sclareol: A very short synthesis of nor-ambreinolide and ambrox

The synthesis of nor-Ambreinolide (8) from (-)-sclareol (1) was carried out by treatment with KMnO4-Ac2O and further alkaline hydrolysis. 8 was directly transformed into (-)-ambrox (11) by reduction with metal borohydride in the presence of Lewis acids.

Catalytic Highly Regioselective C-H Oxygenation Using Water as the Oxygen Source: Preparation of 17O/18O-Isotope-Labeled Compounds

We found that the oxygen atom of water is activated to iodosylbenzene derivatives via reversible hydrolysis of PhI(OOCR)2 and can be used to the oxygen source for ruthenium(bpga)-catalyzed site-selective C-H oxygenation. Ru(bpga)/PhI(OOCR)2/H2O system, sterically less bulky methinic and methylenic C-H bonds in various compounds can be converted to desired oxygen functional groups in a site-selective manner. Using this method, oxygen-isotope labeled compounds such as d-[3-17O/18O]-mannose can be prepared in a multigram scale.

Palladium-Catalyzed Low Pressure Carbonylation of Allylic Alcohols by Catalytic Anhydride Activation

A direct carbonylation of allylic alcohols has been realized for the first time with high catalyst activity at low pressure of CO (10 bar). The procedure is described in detail for the carbonylation of E-nerolidol, an important step in a new BASF-route to (?)-ambrox. Key to high activities in the allylic alcohol carbonylation is the finding that catalytic amounts of carboxylic anhydride activate the substrate and are constantly regenerated with carbon monoxide under the reaction conditions. The identified reaction conditions are transferrable to other substrates as well.

Flavin Nitroalkane Oxidase Mimics Compatibility with NOx/TEMPO Catalysis: Aerobic Oxidization of Alcohols, Diols, and Ethers

Biomimetic flavin organocatalysts oxidize nitromethane to formaldehyde and NOx - providing a relatively nontoxic, noncaustic, and inexpensive source for catalytic NO2 for aerobic TEMPO oxidations of alcohols, diols, and ethers. Alcohols were oxidized to aldehydes or ketones, cyclic ethers to esters, and terminal diols to lactones. In situ trapping of NOx and formaldehyde suggest an oxidative Nef process reminiscent of flavoprotein nitroalkane oxidase reactivity, which is achieved by relatively stable 1,10-bridged flavins. The metal-free flavin/NOx/TEMPO catalytic cycles are uniquely compatible, especially compared to other Nef and NOx-generating processes, and reveal selectivity over flavin-catalyzed sulfoxide formation. Aliphatic ethers were oxidized by this method, as demonstrated by the conversion of (-)-ambroxide to (+)-sclareolide.

Direct Decarboxylative Functionalization of Carboxylic Acids via O-H Hydrogen Atom Transfer

Decarboxylative functionalization via hydrogen atom transfer offers an attractive alternative to standard redox approaches to this important class of transformations. Herein, we report a direct decarboxylative functionalization of aliphatic carboxylic acids using N-xanthylamides. The unique reactivity of amidyl radicals in hydrogen atom transfer enables decarboxylative xanthylation under redox-neutral conditions. This platform provides expedient access to a range of derivatives through subsequent elaboration of the xanthate group.

Chiral complementary alkyl heterocyclic compounds and their use as fungicides

The invention relates to a chiral drimane heterocyclic compound and a purpose of the chiral drimane heterocyclic compound as a sterilizing agent. A chemical structural general formula of the compoundis shown as a formula (I), in the formula (I), 8-bit stereo configuration is R or S, and represents the heterocyclic compound, comprising iso-oxazoline, isoxazole, pyrazoline, pyrimidine, benzimidazole and pyrimidine, or diazepine.

METHOD FOR PRODUCING SCLAREOLIDE

A method for producing slcareolide comprising the following steps: (a) providing sclareol as starter material; (b) contacting the starter material sclareol with ozone in air or oxygen as the sole oxidant in an acidic medium.

Selective C(sp3)?H Aerobic Oxidation Enabled by Decatungstate Photocatalysis in Flow

A mild and selective C(sp3)?H aerobic oxidation enabled by decatungstate photocatalysis has been developed. The reaction can be significantly improved in a microflow reactor enabling the safe use of oxygen and enhanced irradiation of the reaction mixture. Our method allows for the oxidation of both activated and unactivated C?H bonds (30 examples). The ability to selectively oxidize natural scaffolds, such as (?)-ambroxide, pregnenolone acetate, (+)-sclareolide, and artemisinin, exemplifies the utility of this new method.

Synthesis and bio-inspired optimization of drimenal: Discovery of chiral drimane fused oxazinones as promising antifungal and antibacterial candidates

The synthesis of antifungal natural product drimenal was accomplished. Bio-inspired optimization protruded chiral 8-(R)-drimane fused oxazinone D as a lead, considering favorable physicochemical profiles for novel pesticides. The improved scalable synthesis of scaffold D was implemented by Hofmann rearrangment under mild conditions. Detailed structural optimization was discussed for both antifungal and antibacterial exploration. Substituted groups (SGs) with C3～C5 hydrocarbon chain are recommended for exploration of antifungal agents, while substituents with C4～C6 carbon length are preferred for antibacterial ingredients. The chiral drimane fused oxazinone D8 was selected as a promising antifungal candidate against Botrytis cirerea, with an EC50 value of 1.18 mg/L, with the enhancement of up to >25 folds and >80 folds than the mother compound D, and acyclic counterpart AB5, respectively. The in vivo bioassay confirmed much better preservative effect of D8 than that of Carbendazim. The chiral oxazinone variant D10 possessed prominent antibacterial activity, with MIC values of 8 mg/L against both Bacillus subtilis and Ralstonia solanacearum, showing advantages over the positive control streptomycin sulfate.

Chiral drimane oxazinone compounds and use thereof as bactericide

The invention relates to chiral drimane oxazinone compounds and a use thereof as a bactericide. The chemical formula of the compounds is represented by a formula (I) as shown in the description, wherein the stereoscopic configuration of a site 8 is R or S.