621-36-3

Usage

Uses

Used in Pharmaceutical Industry:
3-Methylphenylacetic acid is used as a reactant for the diastereoselective preparation of arylmethylene-isoindolinones, which are important compounds in the development of pharmaceuticals with potential applications in various therapeutic areas.
Used in Chemical Synthesis:
3-Methylphenylacetic acid serves as a key building block in the synthesis of various organic compounds, including those with potential applications in the chemical, material science, and pharmaceutical industries. Its unique structural features make it a valuable intermediate for the creation of novel molecules with specific properties and functions.

InChI:InChI=1/C9H10O2/c1-7-3-2-4-8(5-7)6-9(10)11/h2-5H,6H2,1H3,(H,10,11)/p-1

Upstream product

• 2947-60-6 3-methylbenzyl cyanide 
• 60-29-7 diethyl ether 
• 15719-64-9 methylammonium carbonate 
• 90531-94-5 (3-methylbenzyl)magnesium bromide 
• 124-38-9 carbon dioxide 
• 4662-96-8 1,2-di-m-tolylethane 
• 34403-06-0 1-(3-methylphenyl)-2-phenylethane 
• 201230-82-2 carbon monoxide 
• 620-19-9 1-chloromethyl-3-methyl-benzene 
• 620-13-3 1-bromomethyl-3-methyl-benzene 
• 627-44-1 diethylmercury 
• 108-38-3 m-xylene 
• 7647-01-0 hydrogenchloride 
• 1878-67-7 3-Bromophenylacetic acid 

Downstream Products

• 53088-69-0 methyl 3-methylphenylacetate 
• 105279-22-9 (Z)-3-(3-methylbenzylidene)isobenzofuran-1(3H)-one 
• 40061-55-0 ethyl m-methylphenylacetate 
• 15160-68-6 (E)-3-(2-Bromo-phenyl)-2-m-tolyl-acrylic acid 
• 15160-66-4 (E)-3-(2-Nitro-phenyl)-2-m-tolyl-acrylic acid 
• 83307-71-5 E-methyl-3-(2-furyl)-(2-m-methylphenyl) acrylic acid 
• 83307-81-7 (Z)-2-(3-tolyl)-3-(2-furyl)acrylic acid 
• 83307-76-0 (E)-3-(5-Methyl-furan-2-yl)-2-m-tolyl-acrylic acid 
• 83307-86-2 (Z)-3-(5-Methyl-furan-2-yl)-2-m-tolyl-acrylic acid 
• 107402-37-9 4-Benzoylamino-2-m-tolyl-butyric acid 
• 75245-41-9 threo-4,4-dimethyl-2-(m-tolyl)-valeriansaeure 
• 75245-41-9 erythro-4,4-dimethyl-2-(m-tolyl)-valeriansaeure 
• 106-49-0 p-toluidine 
• 36707-25-2 m-Methyl-phenylessigsaeure-(m-methoxy-benzyl)-ester 

Relevant academic research and scientific papers

Visible-Light-Enabled Carboxylation of Benzyl Alcohol Derivatives with CO2 Using a Palladium/Iridium Dual Catalyst

A highly efficient carboxylation of benzyl alcohol derivatives with CO2 using a palladium/iridium dual catalyst under visible-light irradiation was developed. A wide range of benzyl alcohol derivatives could be employed to provide benzylic carboxylic acids in moderate to high yields. Mechanistic studies indicated that the oxidative addition of benzyl alcohol derivatives was possibly the rate-determining-step. It was also found that a switchable site-selective carboxylation between benzylic C?O and aryl C?Cl moieties could be achieved simply by changing the palladium catalyst.

Suppressing carboxylate nucleophilicity with inorganic salts enables selective electrocarboxylation without sacrificial anodes

Although electrocarboxylation reactions use CO2as a renewable synthon and can incorporate renewable electricity as a driving force, the overall sustainability and practicality of this process is limited by the use of sacrificial anodes such as magnesium and aluminum. Replacing these anodes for the carboxylation of organic halides is not trivial because the cations produced from their oxidation inhibit a variety of undesired nucleophilic reactions that form esters, carbonates, and alcohols. Herein, a strategy to maintain selectivity without a sacrificial anode is developed by adding a salt with an inorganic cation that blocks nucleophilic reactions. Using anhydrous MgBr2as a low-cost, soluble source of Mg2+cations, carboxylation of a variety of aliphatic, benzylic, and aromatic halides was achieved with moderate to good (34-78%) yields without a sacrificial anode. Moreover, the yields from the sacrificial-anode-free process were often comparable or better than those from a traditional sacrificial-anode process. Examining a wide variety of substrates shows a correlation between known nucleophilic susceptibilities of carbon-halide bonds and selectivity loss in the absence of a Mg2+source. The carboxylate anion product was also discovered to mitigate cathodic passivation by insoluble carbonates produced as byproducts from concomitant CO2reduction to CO, although this protection can eventually become insufficient when sacrificial anodes are used. These results are a key step toward sustainable and practical carboxylation by providing an electrolyte design guideline to obviate the need for sacrificial anodes.

Pd(OH)2/C, a Practical and Efficient Catalyst for the Carboxylation of Benzylic Bromides with Carbon Monoxide

A simple, efficient, cheap, and broadly applicable system for the carboxylation of benzylic bromides with carbon monoxide and water is reported. Upon simple reaction with only 2.5 wt % of Pearlman's catalyst and 10 mol % of tetrabutylammonium bromide in tetrahydrofuran at 110 °C for 4 h, a range of benzylic bromides can be smoothly converted to the corresponding arylacetic acids in good to excellent yields after simple extraction and acid-base wash. The reaction was found to be broadly applicable, scalable, and could be successfully extended to the use of ex situ-generated carbon monoxide and applied to the synthesis of the nonsteroidal anti-inflammatory drug diclofenac.

Macrolactam Synthesis via Ring-Closing Alkene-Alkene Cross-Coupling Reactions

Reported herein is a practical method for macrolactam synthesis via a Rh(III)-catalyzed ring closing alkene-alkene cross-coupling reaction. The reaction proceeded via a Rh-catalyzed alkenyl sp2 C-H activation process, which allows access to macrocyclic molecules of different ring sizes. Macrolactams containing a conjugated diene framework could be easily prepared in high chemoselectivities and Z,E stereoselectivities.

Carboxylation of benzylic and aliphatic C-H bonds with CO2 induced by light/ketone/nickel

A photoinduced carboxylation reaction of benzylic and aliphatic C-H bonds with CO2 is developed. Toluene derivatives capture gaseous CO2 at the benzylic position to produce phenylacetic acid derivatives when irradiated with UV light in the presence of an aromatic ketone, a nickel complex, and potassium tert-butoxide. Cyclohexane reacts with CO2 to furnish cyclohexanecar-boxylic acid under analogous reaction conditions. The present photoinduced carboxylation reaction provides a direct access from readily available hydrocarbons to the corresponding carboxylic acids with one carbon extension.

Electrogenerated Sm(II)-Catalyzed CO2 Activation for Carboxylation of Benzyl Halides

Sm(II)-catalyzed carboxylation of benzyl halides is reported through the electrochemical reduction of CO2. The transformation proceeds under mild reaction conditions to afford the corresponding phenylacetic acids in good to excellent yields. This user-friendly and operationally simple protocol represents an alternative to traditional strategies, which usually proceeds through the C(sp3)-halide activation pathway.

Preparation method of phenylacetic acid type compound

The invention discloses a preparation method of a phenylacetic acid type compound. The preparation method of the phenylacetic acid type compound I comprises the following steps that in a solvent and aCO gas phase system, a benzyl halide type compound II, pyridine-2-cobalt carboxylate, palladium acetate and alkaline neutralizers take carbonylation reaction to obtain the phenylacetic acid type compound I. A mixed catalytic system has a synergistic effect; the whole use quantity of catalysts is greatly reduced. When the mixed catalyst is used, a better catalytic effect can be achieved; the characteristics of easily obtaining the catalyst, avoiding the production safety risk of toxic three wastes and the like, reducing the reaction pressure, realizing mild reaction conditions, reducing the production risk, facilitating the production and the like are realized. The formulas are shown in description.

An improved method for the synthesis of phenylacetic acid derivatives via carbonylation

2,4-Dichlorophenylacetic acid is synthesized in high yield via the carbonylation of 2,4-dichlorobenzyl chloride, and various experimental conditions are evaluated. Xylene, bistriphenylphosphine palladium dichloride, tetraethylammonium chloride and sodium hydroxide in solution are added to the reaction system and held at 80 °C under a CO atmosphere. 2,4-Dichlorophenylacetic acid is obtained in a maximum yield of 95percent, and a mechanism for 2,4-dichlorobenzyl chloride carbonylation is proposed. The reaction system provides a mild, effective and novel means by which to prepare phenylacetic acid derivatives from their corresponding benzyl chloride derivatives.

Visible-Light-Driven External-Reductant-Free Cross-Electrophile Couplings of Tetraalkyl Ammonium Salts

Cross-electrophile couplings between two electrophiles are powerful and economic methods to generate C-C bonds in the presence of stoichiometric external reductants. Herein, we report a novel strategy to realize the first external-reductant-free cross-electrophile coupling via visible-light photoredox catalysis. A variety of tetraalkyl ammonium salts, bearing primary, secondary, and tertiary C-N bonds, undergo selective couplings with aldehydes/ketone and CO2. Notably, the in situ generated byproduct, trimethylamine, is efficiently utilized as the electron donor. Moreover, this protocol exhibits mild reaction conditions, low catalyst loading, broad substrate scope, good functional group tolerance, and facile scalability. Mechanistic studies indicate that benzyl radicals and anions might be generated as the key intermediates via photocatalysis, providing a new direction for cross-electrophile couplings.

A General, Activator-Free Palladium-Catalyzed Synthesis of Arylacetic and Benzoic Acids from Formic Acid

A new catalyst for the carboxylative synthesis of arylacetic and benzoic acids using formic acid (HCOOH) as the CO surrogate was developed. In an improvement over previous work, CO is generated in situ without the need for any additional activators. Key to success was the use of a specific system consisting of palladium acetate and 1,2-bis((tert-butyl(2-pyridinyl)phosphinyl)methyl)benzene. The generality of this method is demonstrated by the synthesis of more than 30 carboxylic acids, including non-steroidal anti-inflammatory drugs (NSAIDs), under mild conditions in good yields.