35960-75-9

Upstream product

• 2038-57-5 3-Phenylpropan-1-amine 
• 25804-49-3 tert-butyl 4-hydroxybenzoate 
• 100-42-5 styrene 
• 495-69-2 Hippuric Acid 
• 98-88-4 benzoyl chloride 
• 94-36-0 dibenzoyl peroxide 
• 100-58-3 phenylmagnesium bromide 
• 61124-61-6 3-phenylpropanal p-tosylhydrazone 
• 55-21-0 benzamide 
• 104-53-0 3-phenyl-propionaldehyde 
• 589-18-4 4-Methylbenzyl alcohol 
• 120-51-4 benzoic acid benzyl ester 
• 100-51-6 benzyl alcohol 
• 645-59-0 dihydrocinnamonitrile 

Downstream Products

• 13157-48-7 2,6-diphenyl-5,6-dihydro-4H-1,3-oxazine 
• 32861-51-1 benzyl-(3-phenyl-propyl)-amine 
• 1443771-39-8 C₁₆H₁₆INO 
• 120086-48-8 1-phenyl-2,3,4,5-tetrahydro-1H-benzo[c]azepine 
• 92963-03-6 N-(3-phenylpropanoyl)benzamide 
• 56900-75-5 1-phenyl-4,5-dihydro-3H-benzo[c]diazepine 
• 115032-08-1 N-(3-Phenylpropyl)benzimidchlorid 

Relevant academic research and scientific papers

Photoinduced Decarboxylative Radical Addition Reactions for Late Stage Functionalization of Peptide Substrates

Photoredox chemistry has greatly stimulated the application of radical based transformations in medicinal chemistry and early drug discovery in recent years. Carboxylate groups have been identified as traceless leaving groups that can be converted into radical intermediates capable of undergoing 1,4-conjugate addition reactions to Michael acceptors. Herein, we show the successful C-terminal derivatization of small peptide substrates by using this methodology in a parallel synthesis setting. Finally, we outline a general strategy for the γ-homologation of several drugs derived from α-amino acids in a late stage functionalization (LSF) approach.

Method for preparing amide compounds through ionic liquid catalysis in high-pressure environment

The invention relates to a method for preparing amide compounds through ionic liquid catalysis in a high-pressure environment. According to the method, ionic liquid 1-ethyl-3-methylimidazolium acetateis used as a catalyst and a solvent, oxygen is used as an oxidizing agent, and aromatic methanol or alkyl alcohol is converted into an amide compound under the conditions of high pressure and heating. The synthesis method provided by the invention has the advantages that the raw material and technical cost is low; compared with other traditional methods, the method is safe, low in toxicity, economical and environmentally friendly; and the method has few steps, is simple and convenient to operate, is beneficial to large-scale synthesis, and has important significance for synthesis of amide compounds and large-scale industrialization of preparation.

Direct amidation of non-activated carboxylic acid and amine derivatives catalyzed by TiCp2Cl2

This paper described a mild and efficient direct amidation of non-activated carboxylic acid and amine derivatives catalyzed by TiCp2Cl2. Arylacetic acid derivatives reacted with different amines to afford the corresponding amides in good to excellent yield except of aniline. Aryl formic acids failed to react with aniline but smoothly reacted with aliphatic amines and benzylamine in moderate to good yield, fatty acids reacting with benzyl and aliphatic amines give amides in good to excellent yield. Chiral amino acids derivatives were transformed into amides without racemization in moderate yield. The possible mechanism of direct amidation catalyzed by TiCp2Cl2 was discussed. This catalytic method is very suitable for the amidation of low sterically hindered arylacetic acid, fatty acids with different low sterically hindered amines except aniline, as well as the amidation of aryl formic acid with benzyl and aliphatic amines.

An unprecedented cobalt-catalyzed selective aroylation of primary amines with aroyl peroxides

A novel and facile cobalt-catalyzed selective aroylation of primary amines with aroyl peroxides was developed for the synthesis of aryl amides. It was unprecedented that C[sbnd]N bond formation product was selectively generated without the common N[sbnd]O bond formation product. Aroyl peroxides act as the sole aroylation reagent without additional base or oxidant. The reactions proceeded under mild conditions and showed broad substrates scope with a series of primary amines and aroyl peroxides.

Synthesis of Medium-Ring-Sized Benzolactams by Using Strong Electrophiles and Quantitative Evaluation of Ring-Size Dependency of the Cyclization Reaction Rate

Benzolactams with medium-sized rings were synthesized via the electrophilic aromatic substitution reaction of carbamoyl cations (R1R2N+═C═O) in good to high yields without dilution. These reactions were utilized to quantitatively examine the extent of retardation of medium-sized ring formation, compared to five- or six-membered ring formation. The order of reaction rates of formation of cyclic benzolactams is six- > five- > seven- > eight- > nine-membered ring at 25 °C. The present reaction provides a route to eight- A nd nine-membered benzolactams.

A carbonylation reaction of carbon monoxide in the method of preparing amide

The invention belongs to the technical field of synthesis of amides, discloses a process for the carbonylation of carbon monoxide in the method of preparing amide, the method is to cheap and easy to obtain the halogenated aromatic hydrocarbon and organic amine compounds as the substrate of reaction, to carbon monoxide as carbonyl source, under light-struck, halogenated aromatic hydrocarbons are cracked to produce free radical, by free-radical addition process to obtain the amide compound. Compared with the traditional carbonylation reaction, the carbon monoxide pressure is extremely low, can react to the atmospheric pressure. This process does not need to rely on any metal catalyst of the booster, mild reaction conditions, environmental protection, with a shorter synthetic route and high utilization efficiency of the atoms, the reaction system with higher substrate tolerance, green sustainable light source as the driving force, the atom economy is high, application prospect.

An open-source approach to automation in organic synthesis: The flow chemical formation of benzamides using an inline liquid-liquid extraction system and a homemade 3-axis autosampling/product-collection device

Several open-source hardware and software technologies (RAMPS, Python, PySerial, OpenCV) were used to control an automated flow chemical synthesis system. The system was used to effect the synthesis of a series of benzamides. An inexpensive Raspberry Pi single board computer provided an electronic interface between the control computer and the RAMPS motor driver boards.

From [11C]CO2 to [11C]amides: A rapid one-pot synthesis: Via the Mitsunobu reaction

A novel amide synthesis methodology is described using amines, CO2 and Grignard reagents and Mitsunobu reagents. The method was applied to carbon-11 radiochemistry to label amides using cyclotron-produced [11C]CO2. The synthetic utility of the one-pot labelling methodology was demonstrated by producing [11C]melatonin. The incorporation of [11C]CO2 into [11C]melatonin was 36%-determined by radioHPLC 2 min post [11C]CO2 delivery.

Copper(I)-Catalyzed Reductive Cross-Coupling of N-Tosylhydrazones with Amides: A Straightforward Method for the Construction of C(sp3)- N Amide Bonds from Aldehydes

A method for the one-pot synthesis of substituted amides from aldehydes and amides is presented. Namely, condensation of aldehydes with N-tosylhydrazide generated the N-tosylhydrazones which were then reductively cross-coupled in situ with primary or secondary amides in the presence of a copper catalyst to afford secondary or tertiary amides, respectively. The reaction proceeded efficiently for a wide range of aldehydes and amides under the optimized conditions, i.e., 10 mol% of tetrakis(acetonitrile)copper(I) tetrafluoroborate [Cu(CH3CN)4BF4], 1 mol% of tetra-n-butylammonium iodide [(n-Bu)4NI], and sodium hydroxide [NaOH] as base in tetrahydrofuran (THF) at 80 C. As a result, the method provides a straightforward route for the synthesis of substituted amides from readily available aldehydes via a transition metal-catalyzed C(sp3)- N amide bond forming reaction.

Synergistic cascade catalysis by metal nanoparticles and Lewis acids in hydrogen autotransfer

Of the many types of catalysis involving two or more catalysts, synergistic catalysis is of great interest because novel reactions or reaction pathways may be discovered when there is synergy between the catalysts. Herein, we describe a synergistic cascade catalysis, in which immobilized Au/Pd bimetallic nanoparticles and Lewis acids work in tandem to achieve the N-alkylation of primary amides to secondary amides with alcohols via hydrogen autotransfer. When Au/Pd nanoparticles were used with metal triflates, a significant rate acceleration was observed, and the desired secondary amides were obtained in excellent yields. The metal triflate is thought to not only facilitate the addition of primary amides to aldehydes generated in situ, but also enhance the returning of hydrogen from nanoparticles to hydrogen-accepting intermediates. This resulted in a more rapid turnover of the nanoparticle catalyst, and ultimately translated into an increase in the overall rate of the reaction. The two catalysts in this co-catalytic system work in a synergistic and cascade fashion, resulting in an efficient hydrogen autotransfer process.