3380-95-8

Usage

Explanation

The compound is composed of 9 carbon atoms, 8 hydrogen atoms, 2 nitrogen atoms, and 2 oxygen atoms.
2. Heterocyclic compound

Explanation

It contains a ring structure with atoms of different elements, specifically carbon, nitrogen, and oxygen.
3. Triaza-1,2-dien-2-ium core

Explanation

The central structure of the compound consists of three nitrogen atoms and two carbon atoms, forming a six-membered ring with alternating single and double bonds.
4. Carboxy(phenyl)methyl group attached

Explanation

A phenyl group (C6H5) is connected to a carboxylic acid (COOH) through a methylene (CH2) bridge, which is then attached to the triaza-1,2-dien-2-ium core.
5. Positively charged species
6. Iminium ion

Explanation

The positively charged nitrogen atom in the compound is part of an iminium ion, which is a resonance-stabilized, positively charged species.
7. Intermediate in organic synthesis

Explanation

It is commonly used as a building block or precursor in the synthesis of more complex organic compounds, including pharmaceuticals.
8. Participation in chemical reactions

Explanation

Due to its unique structure, the compound can undergo various chemical reactions, such as nucleophilic attack, electrophilic substitution, and rearrangements.
9. Catalyst in certain reactions

Explanation

The compound can act as a catalyst to facilitate and increase the rate of specific chemical reactions, making it an important compound in the production of various chemicals and pharmaceuticals.

Upstream product

• 53432-39-6 (R)-1,1,1-trichloro-2-phenylethan-2-ol 
• 279676-21-0 (+/-)-2-azido-2-phenylacetamide 
• 104266-89-9 (S)-4-benzyl-3-phenylacetyl-2-oxazolidinone 
• 65-85-0 benzoic acid 
• 113543-39-8 (4S)-3-(2-bromo-1-oxo-2-phenylethyl)-4-(phenylmethyl)-2-oxazolidinone 
• 2935-35-5 (S)-2-phenylglycine 
• 875-74-1 (R)-phenylglycine 
• 113543-46-7 (3(2R),4S)-3-(2-azido-1-oxo-2-phenethyl)-4-(phenylmethyl)-2-oxazolidinone 
• 116911-14-9 (2S,3S)-3-azido-3-phenyl-propane-1,2-diol 
• 111525-67-8 (3(2S),4S)-3-(2-azido-2-phenyl-1-oxoethyl)-4-(phenylmethyl)-2-oxazolidinone 
• 124718-93-0 2-azido-2-phenylethanol 
• 96-09-3 styrene oxide 
• 4870-65-9 2-bromophenylacetic acid 

Relevant academic research and scientific papers

Montmorillonite K10 catalyzed highly regioselective azidolysis of epoxides: A short and efficient synthesis of phenylglycine

A series of β‐hydroxyazides were effectively synthesized from the regioselective ring opening of epoxides by sodium azide using montmorillonite K10 as a novel heterogeneous catalyst in aqueous acetonitrile in good to excellent yields. The utility of this method has been demonstrated by achieving a short synthesis of phenylglycine in 33.5% overall yield.

REAGENTS AND METHODS FOR ESTERIFICATION

Methods and reagents for esterification of biological molecules including proteins, polypeptides and peptides. Diazo compounds of formula (I): where R is hydrogen, an alkyl, an alkenyl or an alkynyl, RA represents 1-5 substituents on the indicated phenyl ring and RM is an organic group, which includes a label, a cell penetrating group, a cell targeting group, or a reactive group or latent reactive group for reaction to bond to a label, a cell penetrating group, or a cell targeting group, among other organic groups are useful for esterification of biological molecules. Also provided are diazo compounds which are bifunctional and trifunctional coupling reagents as well as reagents for the synthesis of compounds of formula (I).

Optimized Diazo Scaffold for Protein Esterification

The O-alkylation of carboxylic acids with diazo compounds provides a means to esterify carboxylic acids in aqueous solution. A Hammett analysis of the reactivity of diazo compounds derived from phenylglycinamide revealed that the (p-methylphenyl)-glycinamide scaffold has an especially high reaction rate and ester/alcohol product ratio and esterifies protein carboxyl groups more efficiently than any known reagent. (Chemical Equation Presented).

Triazolopeptides: chirospecific synthesis and cis/trans prolyl ratios of structural isomers

As cis/trans prolyl isomerization plays a crucial role in various biological processes, peptide mimics capable of modifying the cis/trans Xaa-Pro ratio are of particular interest. A practical approach toward proline derived triazolopeptides employing [3+2] azide-alkyne cycloadditions as the key reaction step and the analysis of their cis/trans prolyl ratios are reported. Structural investigations indicated the adjustability of both the cis-percentage and the conformational stability toward intramolecular H-bonding effects.

Improved solid-phase peptide synthesis method utilizing alpha-azide-protected amino acids.

[structure: see text]. Pure alpha-azido acids were prepared using an efficient diazo transfer method followed by buffered workup. These building blocks were used to prepare small peptides on Wang resin by two approaches. Peptides prone to diketopiperazine formation were prepared in good yields by coupling acids to resin bound iminophosphoranes during Fmoc-Wang synthesis. The iminophosphoranes can also be hydrolyzed under neutral conditions to provide unprotected amines ready for further coupling.

A practical asymmetric synthesis of homochiral α-arylglycines

Enantioselective reduction of a series of substituted aryl trichloromethyl ketones with the CBS-catecholborane reagent afforded homochiral aryl trichloromethyl carbinols which have been elaborated to give homochiral α-arylglycines in high e.e.

Enzymatic and chiral HPLC resolution of α-azido acids and amides

For the first time, enzymatic resolution of α-azido acid amides has been successfully demonstrated with high yields and enantiomeric excess. In one case dynamic kinetic resolution was achieved leading to more than 50% yield of the enantiomerically pure azido acid. Chiral HPLC was also used to separate racemic α-azido acids and the separation process was automated. Two routes to enantiopure α-azido acid building blocks for solid-phase peptide synthesis have, therefore, been established. Copyright (C) 2000 Elsevier Science Ltd.

The asymmetric synthesis of α-amino acids. Electrophilic azidation of chiral imide enolates, a practical approach to the synthesis of (R)- and (S)-α-azido carboxylic acids

Two complementary approaches to the asymmetric synthesis of α-amino acids have been achieved. In the initially investigated reaction sequence, the diastereoselective bromination of the illustrated boron enolate with N-bromosuccinimide was followed by stereospecific azide displacement by tetramethylguanidinium azide. The resulting α-azido carboximides may be readily purified to high diastereomeric purity by chromatography on silica. equation presented In the second reaction sequence, the illustrated potassium enolate was treated with 2,4,6-triisopropylbenzenesulfonyl azide, and the intermediate sulfonyl triazene was decomposed through an acetic acid quench to give the α-azido carboximide. The diastereoselection of the reaction as a function of R is as follows: R = Me, CH2Ph, 97:3; R = CHMe2, 98:2; R = CMe3, >99:1; R = Ph, 91:9. The important parameters of this azidation process were evaluated, and experiments were conducted to help elucidate the mechanism of the reaction. equation presented The α-azido carboximide products have been shown to be versatile α-amino acid synthons that may be readily converted to α-amino acids as well as to N-protected α-amino acid derivatives. The racemization-free removal of the chiral auxiliary was achieved in high yield both by saponification and transesterification, either before or after reduction and acylation of the azide functionality.

Regioselective Azide Opening of 2,3-Epoxy Alcohols by : Synthesis of α-Amino Acids

Treatment of 2,3-epoxy alcohols with affords the corresponding 3-azido 1,2-diols, which are readily transformed in two steps to the α-amino acids.

ASYMMETRIC HALOGENATION OF CHIRAL IMIDE ENOLATES. A GENERAL APPROACH TO THE SYNTHESIS OF ENANTIOMERICALLY PURE α-AMINO ACIDS.

The chiral N-acyl oxazolidones 2, as the derived dibutyl boron enolates, have been demonstrated to undergo diastereoselective bromination and subsequent azide displacement to give the α-azido carboximides 4a (5 cases).These adducts may be hydrolyzed under mild conditions to the enantiomerically pure α-azido carboxylic acids 5a.