76496-63-4

Basic information

• Product Name: (S)-4-CHLOROMANDELIC ACID
• Synonyms: (S)-4-CHLOROMANDELIC ACID;(S)-2-(4-Chlorophenyl)-2-hydroxyacetic acid;L-4-chloro Mandelic acid
• CAS NO: 76496-63-4
• Molecular Formula: C₈H₇ClO₃
• Molecular Weight: 186.59
• EINECS: 1312995-182-4
• Mol File: 76496-63-4.mol
• Article Data: 50

Chemical Properties

• Boiling Point: 361.4±27.0 °C(Predicted)
• Appearance: /
• Density: 1.468±0.06 g/cm3(Predicted)
• Storage Temp.: Sealed in dry,Room Temperature
• Solubility: Methanol (Slightly), Water (Slightly)
• PKA: 3.14±0.10(Predicted)
• CAS DataBase Reference: (S)-4-CHLOROMANDELIC ACID(CAS DataBase Reference)
• NIST Chemistry Reference: (S)-4-CHLOROMANDELIC ACID(76496-63-4)
• EPA Substance Registry System: (S)-4-CHLOROMANDELIC ACID(76496-63-4)

Safety Data

• Hazardous Substances Data: 76496-63-4(Hazardous Substances Data)

Usage

General Description

(S)-4-chloromandelic acid is an organic compound with the molecular formula C9H9ClO3. It is a white crystalline solid that is used in the pharmaceutical industry as a key intermediate in the synthesis of various drugs. (S)-4-CHLOROMANDELIC ACID has shown potential pharmacological properties, including antimicrobial and antiviral activities. It is also used as a chiral resolving agent in the separation of racemic mixtures. (S)-4-chloromandelic acid is considered to be a valuable building block for the synthesis of various pharmaceutical compounds and is of interest to researchers in the field of medicinal chemistry and drug development.

Upstream product

• 13312-83-9 4-chloromandelonitrile 
• 99-91-2 para-chloroacetophenone 
• 7138-34-3 p-chloromandelic acid 
• 76334-33-3 S-butyl 2-hydroxy-2-(p-chlor-phenyl)-thioacetate 
• 75-77-4 chloro-trimethyl-silane 
• 151-50-8 potassium cyanide 
• 104-88-1 4-chlorobenzaldehyde 
• 66985-46-4 (+/-)-2-(4-chlorophenyl)-2-(trimethylsiloxy)-acetonitrile 
• 33512-03-7 3-(4-chlorophenyl)oxirane-2,2-dicarbonitrile 
• 14062-24-9 4-chloro-benzeneacetic acid, ethyl ester 
• 3240-34-4 [bis(acetoxy)iodo]benzene 
• 106-39-8 bromochlorobenzene 
• 201230-82-2 carbon monoxide 
• 1878-66-6 4-chlorophenylacetic Acid 

Downstream Products

• 83-05-6 bis(4'-chlorophenyl)acetic acid 
• 21771-88-0 α-(4-chlorophenyl)phenylacetic acid 
• 492-86-4 (R)-4-chloro-α-hydroxy-benzeneacetic acid 
• 75188-06-6 2-chloro-2-(4-chlorophenyl)acetyl chloride 
• 74-11-3 para-chlorobenzoic acid 
• 104-88-1 4-chlorobenzaldehyde 
• 65-85-0 benzoic acid 
• 389889-38-7 (2R,5R)-2-(t-butyl)-5-(4-chlorophenyl)-1,3-dioxolan-4-one 
• 1217298-38-8 C₈H₇ClO₃*C₁₀H₁₅OP 
• 1217298-40-2 C₈H₇ClO₃*C₁₀H₁₅OP 
• 164293-06-5 (R)-1-phenylethanaminium (R)-4-chloromandelate 
• 1131311-98-2 (R)-PEA*(S)-p-ClMA 
• 6265-91-4 2-(4-chlorophenyl)benzothiazole 
• 32174-34-8 methyl 4-chloromandelate 

Relevant articles and documents

Synthesis of α-hydroxycarboxylic acids from various aldehydes and ketones by direct electrocarboxylation: A facile, efficient and atom economy protocol

In present work, the formation of α-hydroxycarboxylic acids have been described from various aromatic aldehydes and ketones via direct electrocarboxylation method with 80-92% of yield without any side product and can be purified by simple recrystallization using sacrificial Mg anode and Pt cathode in an undivided cell, CO2at (1 atm) was continuously bubbled in the cell throughout the reaction using tetrapropylammonium chloride as a supporting electrolyte in acetonitrile. The synthesized compounds obtained in fair to excellent yield with a high level of purity. The characterization of electrocarboxylated compounds was done with spectroscopic techniques like IR, NMR (1H & 13C), mass and elemental analysis.

Oxalyl-CoA Decarboxylase Enables Nucleophilic One-Carbon Extension of Aldehydes to Chiral α-Hydroxy Acids

The synthesis of complex molecules from simple, renewable carbon units is the goal of a sustainable economy. Here we explored the biocatalytic potential of the thiamine-diphosphate-dependent (ThDP) oxalyl-CoA decarboxylase (OXC)/2-hydroxyacyl-CoA lyase (HACL) superfamily that naturally catalyzes the shortening of acyl-CoA thioester substrates through the release of the C1-unit formyl-CoA. We show that the OXC/HACL superfamily contains promiscuous members that can be reversed to perform nucleophilic C1-extensions of various aldehydes to yield the corresponding 2-hydroxyacyl-CoA thioesters. We improved the catalytic properties of Methylorubrum extorquens OXC by rational enzyme engineering and combined it with two newly described enzymes—a specific oxalyl-CoA synthetase and a 2-hydroxyacyl-CoA thioesterase. This enzymatic cascade enabled continuous conversion of oxalate and aromatic aldehydes into valuable (S)-α-hydroxy acids with enantiomeric excess up to 99 %.

Highly Efficient Deracemization of Racemic 2-Hydroxy Acids in a Three-Enzyme Co-Expression System Using a Novel Ketoacid Reductase

Enantiopure 2-hydroxy acids (2-HAs) are important intermediates for the synthesis of pharmaceuticals and fine chemicals. Deracemization of racemic 2-HAs into the corresponding single enantiomers represents an economical and highly efficient approach for synthesizing chiral 2-HAs in industry. In this work, a novel ketoacid reductase from Leuconostoc lactis (LlKAR) with higher activity and substrate tolerance towards aromatic α-ketoacids was discovered by genome mining, and then its enzymatic properties were characterized. Accordingly, an engineered Escherichia coli (HADH-LlKAR-GDH) co-expressing 2-hydroxyacid dehydrogenase, LlKAR, and glucose dehydrogenase was constructed for efficient deracemization of racemic 2-HAs. Most of the racemic 2-HAs were deracemized to their (R)-isomers at high yields and enantiomeric purity. In the case of racemic 2-chloromandelic acid, as much as 300 mM of substrate was completely transformed into the optically pure (R)-2-chloromandelic acid (> 99% enantiomeric excess) with a high productivity of 83.8 g L?1 day?1 without addition of exogenous cofactor, which make this novel whole-cell biocatalyst more promising and competitive in practical application.