13212-57-2

Usage

Uses

Used in Pharmaceutical Industry:
2-(2-NITRO-PHENOXY)-PROPIONIC ACID serves as a key building block in the synthesis of various pharmaceutical compounds. Its structural similarity to NSAIDs suggests potential applications in developing new anti-inflammatory and analgesic drugs, offering alternative treatment options for pain and inflammation management.
Used in Agrochemical Industry:
In the agrochemical sector, 2-(2-NITRO-PHENOXY)-PROPIONIC ACID is utilized as an intermediate in the production of agrochemicals. Its chemical properties make it a valuable component in the development of pesticides, herbicides, and other agricultural chemicals, contributing to enhanced crop protection and yield.
As a Research Compound:
2-(2-NITRO-PHENOXY)-PROPIONIC ACID is also used in scientific research for studying its potential biological activities and exploring its applications in drug discovery. Researchers investigate its anti-inflammatory and analgesic properties, as well as other possible therapeutic effects, to advance the understanding of its mechanisms of action and potential uses in medicine.
In Chemical Synthesis:
Beyond its direct applications, 2-(2-NITRO-PHENOXY)-PROPIONIC ACID is employed as a versatile intermediate in the synthesis of a wide range of organic compounds. Its unique structure allows for various chemical reactions, enabling the creation of new molecules with diverse applications in different industries, including materials science, specialty chemicals, and more.

InChI:InChI=1/C9H9NO5/c1-6(9(11)12)15-8-5-3-2-4-7(8)10(13)14/h2-6H,1H3,(H,11,12)

Upstream product

• 940-31-8 2-phenoxypropionic acid 
• 90923-22-1 α-(2-Nitrophenoxy)-propionsaeure-methylester 
• 598-78-7 (R,S)-2-chloropropionic acid 
• 88-75-5 2-hydroxynitrobenzene 
• 824-38-4 potassium 2-nitrophenoxide 
• 824-39-5 sodium o-nitrophenate 
• 139-02-6 sodium phenoxide 
• 42412-84-0 ethyl 2-phenoxypropionate 
• 13212-56-1 ethyl 2-[2'-nitrophenoxy]propanoate 

Downstream Products

• 1448338-46-2 di(1-naphthyl)methyl (S)-2-(2-nitrophenoxy)propanoate 
• 77285-93-9 (R)-2-(2-nitrophenoxy)propanoic acid 
• 2852-86-0 (S)-2-(2-nitrophenoxy)propanoic acid 
• 360051-40-7 2-(2-nitro-phenoxy)-propionyl chloride 
• 21744-83-2 3,4-dihydro-2-methyl-3-oxo-1,4(2H)-benzoxazine 

Relevant academic research and scientific papers

Chlorination of 2-phenoxypropanoic acid with NCP in aqueous acetic acid: Using a novel ortho-para relationship and the para/meta ratio of substituent effects for mechanism elucidation

(Graph Presented) Rate constants were measured for the oxidative chlorodehydrogenation of (R,S)-2-phenoxypropanoic acid and nine ortho-, ten para- and five meta-substituted derivatives using (R,S)-1-chloro-3-methyl-2,6- diphenylpiperidin-4-one (NCP) as chlorinating agent. The kinetics was run in 50% (v/v) aqueous acetic acid acidified with perchloric acid under pseudo-first-order conditions with respect to NCP at temperature intervals of 5 K between 298 and 318 K, except at the highest temperature for the meta derivatives. The dependence of rate constants on temperature was analyzed in terms of the isokinetic relationship (IKR). For the 20 reactions studied at five different temperatures, tne isokinetic temperature was estimated to be 382 K, which suggests the preferential involvement of water molecules in the rate-determining step. The dependence of rate constants on meta and para substitution was analyzed using the tetralinear extension of the Hammett equation. The parameter λ for the para/meta ratio of polar substituent effects was estimated to be 0.926, and its electrostatic modeling suggests the formation of an activated complex bearing an electric charge near the oxygen atom belonging to the phenoxy group. A new approach is introduced for examining the effect of ortho substituents on reaction rates. Using IKR-determined values of activation enthalpies for a set of nine pairs of substrates with a given substituent, a linear correlation is found between activation enthalpies of ortho and para derivatives. The correlation is interpreted in terms of the selectivity of the reactant toward para- or ortho-monosubstituted substrates, the slope of which being related to the ortho effect. This slope is thought to be approximated by the ratio of polar substituent effects from ortho and para positions in benzene derivatives. Using the electrostatic theory of through-space interactions and a dipole length of 0.153 nm, this ratio was calculated at various positions of a charged reaction center along the benzene C1-C4 axis, being about 2.5 near the ring and decreasing steeply with increasing distance until reaching a minimum value of -0.565 at 1.3 nm beyond the aromatic ring. Activation enthalpies and entropies were estimated for substrates bearing the isoselective substituent in either ortho and para positions, being demonstrated that they are much different from the values for the parent substrate. The electrophilic attack on the phenolic oxygen atom by the protonated chlorinating agent is proposed as the rate-determining step, this step being followed by the fast rearrangement of the intermediate thus formed, leading to products containing chlorine in the aromatic ring.

Optical resolution of aryloxypropionic acids and their esters by HPLC on cellulose tris-3,5-dimethyl-triphenylcarbamate derivative

Chiral chromatographic resolution of a series of antiphlogistic 2- aryloxypropionic acids and their methyl and ethyl esters was performed using a Chiralcel OD column. The CSP selected resolved most of the acids and esters efficiently, the enantiomers being well separated without requiring time consuming analysis. Chromatographic separation of R enriched samples was performed to determine the correct elution order. Using eluting systems such as hexane and 2-propanol, or hexane, 2-propanol and formic acid, the S enantiomer of all acids and esters was always found to elute first. We also considered the role of electron-donating or electron-withdrawing substituents (at the aryloxylic moiety) on the chiral resolution. It was shown that the electronic features of the substituents have more influence on the chiral interactions between the solutes and the CSP than their steric hindrance. Finally we determined, by molecular models, the interaction between CSP and solutes. In this way were able to determine all the potential sites for interactions, which are compatible with the conformations of the compounds and the structure of the stationary phase, and point out those interactions which enable chiral resolution.