3839-69-8

Upstream product

• 52805-92-2 1-methoxy-2-styrylbenzene 
• 100-42-5 styrene 
• 533-58-4 2-Iodophenol 
• 1080-32-6 O,O-diethyl benzylphosphonate 
• 90-02-8 salicylaldehyde 
• 100-39-0 benzyl bromide 
• 100-51-6 benzyl alcohol 
• 92151-73-0 2-phenylethynylphenol 
• 271-89-6 1-benzofurane 
• 591-51-5 phenyllithium 
• 57999-46-9 2-(tetrahydropyran-2-yloxy)phenyl bromide 
• 108-95-2 phenol 
• 95-56-7 2-hydroxybromobenzene 
• 4846-21-3 O-phenylhydroxylamine 

Downstream Products

• 136560-67-3 stilben-2-yloxy-acetic acid 
• 52805-92-2 1-methoxy-2-styrylbenzene 
• 7294-84-0 2-(2-phenylethyl)phenol 
• 72279-15-3 2-(2-bromoethoxy)bibenzyl 
• 72279-13-1 2-(3-bromopropoxy)bibenzyl 
• 86819-32-1 2-(2-Phenethyl-phenoxymethyl)-oxirane 
• 72279-14-2 2-(4-bromobutoxy)-1-(2-phenylethyl)benzene 
• 127003-01-4 {Methyl-[4-(2-phenethyl-phenoxy)-butyl]-amino}-acetic acid 
• 72278-97-8 <2-<2-<4-(4-carbamoylpiperidino)butoxy>phenyl>ethyl>benzene 
• 72279-00-6 2-[4-(3-carbamoylpiperidino)butoxy]bibenzyl 
• 127003-10-5 4-(2-Phenethyl-phenoxy)-butylamine 
• 72279-19-7 2-(2-dimethylaminoethoxy)bibenzyl 
• 127003-06-9 2-(3-dimethylaminopropoxy)bibenzyl 
• 127003-09-2 2-(4-methylaminobutoxy)bibenzyl 

Relevant academic research and scientific papers

Cascade Claisen and Meinwald Rearrangement for One-Pot Divergent Synthesis of Benzofurans and 2 H-Chromenes

A new cascade approach has been developed for the one-pot four-step divergent synthesis of polysubstituted benzofurans and 2H-chromenes, featuring a novel cascade aromatic Claisen rearrangement/Meinwald rearrangement/dehydrative or oxidative cyclization. This new method was demonstrated with 39 examples tolerating different substitutions at an epoxide, allylic ether, and aromatic ring, and we showcased its utility with the first total synthesis of natural product liparacid A in seven steps.

Phenol compound ortho-position direct olefination method and olefinated phenol compound

The invention relates to a phenol compound ortho-position direct olefination method and an olefinated phenol compound prepared with the method. The method comprises the steps that a phenol compound shown by the formula (II) and an olefin compound shown by

Application of metallide/palladium compound catalytic reduction system in reaction of removing allyl groups and deuteration reaction

The invention discloses application of a metallide/palladium compound catalytic reduction system in reaction of removing allyl groups of a compound containing the allyl groups and deuteration reaction. The reaction comprises the following steps: under protection of nitrogen gas, suspending a palladium compound and a metallide in a solvent, stirring for 5 minutes, adding the compound containing theallyl groups, reacting for 0.5-36 hours at the temperature of minus 50-120 DEG C, adding ice water to stop reaction, regulating a pH value to 3.5 by using diluted hydrochloric acid, and carrying outsolvent extraction, drying by steaming and column-chromatography purification on reaction liquid to finish the reaction.

Pd-Catalyzed debenzylation and deallylation of ethers and esters with sodium hydride

Herein we demonstrate simply that the addition of Pd(OAc)2 as a promotor switches the reactivity of a commonly used base NaH to a nucleophilic reductant. The reactivity is engineered into a palladium-catalyzed reductive debenzylation and deallylation of aryl ethers and esters. This operationally simple, mild protocol displays a broad substrate scope and a broad spectrum of functional group tolerance (>50 examples) and high chemoselectivity toward aryl ethers over aliphatic structures. Moreover, the dual reactivity of NaH as a base and a reductant is demonstrated in efficient synthetic elaboration.

Manganese-Catalyzed Ring Opening of Benzofurans and Its Application to Insertion of Heteroatoms into the C2-O Bond

A new class of aromatic metamorphosis in which benzofurans are converted into diverse six-membered oxaheterocycles has been developed. This transformation is composed of two reactions in one pot: manganese-catalyzed arylative or alkylative ring-opening of benzofurans affording dianionic intermediates and subsequent trapping with multivalent heteroatom electrophiles. Various electrophiles containing silicon, boron, phosphorus, germanium, and titanium could be applied to this heteroatom insertion.

Aryiolefins compound synthetic method

The invention discloses an aryiolefins compound synthetic method and belongs to the field of organic chemistry synthesis. The aryiolefins compound synthetic method particularly includes dissolving an o-hydroxy (amino) aryl alkynes compound, a bis(pinacolato) borate compound, a transition metal (rhodium, iridium, palladium or platinum), alkali and a hydrogen source into an organic solvent at a nitrogen atmosphere prior to heating and stirring reaction, removing the organic solvent under reduced pressure after the reaction is terminated, and conducting column chromatography separation so as to obtain various o-hydroxy (amino) aryiolefins compounds. Compared with an existing method, the aryiolefins compound synthetic method has the advantages of simpler synthetic and reaction steps, mild reaction conditions, simplicity, convenience and feasibility in operation, cheap and easily available raw materials and capabilities of reaching more than 80% in product yield, inhibiting production of cyclization product benzofuran or indole derivatives and improving reaction efficiency and reactive atom economy, thereby being a novel approach to synthesis of the o-hydroxy (amino) aryiolefins compounds.

One-Step Synthesis of Substituted Benzofurans from ortho- Alkenylphenols via Palladium-Catalyzed C=H Functionalization

A dehydrogenative oxygenation of C(sp2)=H bonds with intramolecular phenolic hydroxy groups has been developed, which provides a straightforward and concise access to structurally diversely benzofurans from ortho-alkenylphenols. The reaction is catalyzed by palladium on carbon (Pd/C) without any oxidants and sacrificing hydrogen acceptors.

TRPA1 channels as targets for resveratrol and related stilbenoids

A series of twenty resveratrol analogues was synthesized and tested on TRPA1 and TRPV1 channels. None was able to significantly modulate TRPV1 channels. Conversely, most of them exhibited remarkably higher TRPA1 modulating activity than resveratrol. Optimal potency was observed with ortho monoxygenated stilbenes 6 and 17.

Geometry constrained N-(5,6,7-trihydroquinolin-8-ylidene)arylaminopalladium dichloride complexes: Catalytic behavior toward methyl acrylate (MA), methyl acrylate-co-norbornene (MA-co-NB) polymerization and heck coupling

A new pair of plladium complexes (Pd4 and Pd5) ligated with constrained N-(5,6,7-trihydroquinolin-8-ylidene)arylamine ligands have been prepared and well characterized by 1H-, 13C-NMR and FTIR spectroscopies as well as elemental analysis. The molecular structure of Pd4 and Pd5 in solid state have also been determined by X-ray diffraction, showing slightly distorted square planar geometry around the palladium metal center. All complexes Pd1-Pd5 are revealed highly efficient catalyst in methyl acrylate (MA) polymerization as well as methyl acrylate/norbornene (MA/NB) copolymerization. In the case of MA polymerization, as high as 98.4% conversion with high molecular weight up to 6282 kg·mol-1 was achieved. Likewise, Pd3 complex has good capability to incorporate about 18% NB content into MA polymer chains. Furthermore, low catalyst loadings (0.002 mol %) of Pd4 or Pd5 are able to efficiently mediate the coupling of haloarenes with styrene affording up to 98% conversion.

Naturally occurring Batatasins and their derivatives as α-glucosidase inhibitors

Batatasins are endogenous plant hormones found in yams and other related plant species. These plants are widely consumed as botanical dietary supplements in many parts of the world. This study investigated the inhibitory effects and mechanisms of Batatasin I, III, IV, V against α-glucosidase regarding their antidiabetic activities. The results revealed that Batatasin I, III, IV inhibited α-glucosidase in a reversible and noncompetitive manner, with IC50 values of 2.55, 1.89 and 2.52 mM respectively, while Batatasin V completely abolished its inhibitory activity even at the highest concentrations tested. Furthermore, a class of Batatasin-derived compounds with different substitution patterns was synthesized and subjected to the assay to clarify the structure-activity relationships, which suggested that the hydroxyl at the C-2′ position may play a significant role in improving the inhibitory activities. Their probable binding modes and the specificity of the binding sites were studied using molecule docking simulation. It was concluded that Batatasins, especially Batatasin III and IV, are promising α-glucosidase inhibitors, which therefore could be used as functional food to alleviate postprandial hyperglycemia and as potential candidates for the development of antidiabetic agents.