151911-23-8

Basic information

• Product Name: (R)-3-AMINO-3-(4-FLUORO-PHENYL)-PROPIONIC ACID
• Synonyms: H-D-BETA-PHE(4-F)-OH;(R)-beta-4-Fluorophenylalanine;(R)--(p-Fluorophenyl)alanine;(R)-3-(P-FLUOROPHENYL)-BETA-ALANINE ;(R)-3-amino-3-(4-fluorophenyl)propanoic acid;H-D-b-Phe(4-F)-OH;R-4-F-PHA;Albb-006640
• CAS NO: 151911-23-8
• Molecular Formula: C₉H₁₀FNO₂
• Molecular Weight: 183.18
• EINECS: 200-258-5
• Product Categories: 3-Amino-3-phenylpropionic Acid Analogs;3-Amino-3-phenylpropanoic Acid Analogs;B-Amino
• Mol File: 151911-23-8.mol

Chemical Properties

• Melting Point: 245-247 °C(Solv: water (7732-18-5); acetone (67-64-1))
• Boiling Point: 308.829 °C at 760 mmHg
• Flash Point: 140.575 °C
• Appearance: /
• Density: 1.29 g/cm³
• Vapor Pressure: 0.000287mmHg at 25°C
• Refractive Index: 1.554
• Storage Temp.: Keep in dark place,Inert atmosphere,Room temperature
• PKA: 3.66±0.10(Predicted)
• CAS DataBase Reference: (R)-3-AMINO-3-(4-FLUORO-PHENYL)-PROPIONIC ACID(CAS DataBase Reference)
• NIST Chemistry Reference: (R)-3-AMINO-3-(4-FLUORO-PHENYL)-PROPIONIC ACID(151911-23-8)
• EPA Substance Registry System: (R)-3-AMINO-3-(4-FLUORO-PHENYL)-PROPIONIC ACID(151911-23-8)

Safety Data

• Hazardous Substances Data: 151911-23-8(Hazardous Substances Data)

Usage

Uses

Used in Pharmaceutical Research and Drug Development:
(R)-3-AMINO-3-(4-FLUORO-PHENYL)-PROPIONIC ACID is utilized as a pharmaceutical intermediate for its capacity to interact with biological systems, potentially leading to the development of new therapeutic agents.
Used in Organic Synthesis:
In the field of organic synthesis, (R)-3-AMINO-3-(4-FLUORO-PHENYL)-PROPIONIC ACID serves as a key building block, enabling the creation of novel chemical entities with specific desired properties.
Used in Neurotransmission and Physiological Function Studies:
(R)-3-AMINO-3-(4-FLUORO-PHENYL)-PROPIONIC ACID is employed as a subject of study in research aimed at understanding its potential role in neurotransmission and other bodily functions, which could contribute to advancements in medicine and biology.

InChI:InChI=1/C9H10FNO2/c10-7-3-1-6(2-4-7)8(11)5-9(12)13/h1-4,8H,5,11H2,(H,12,13)/t8-/m1/s1

Upstream product

• 1132-68-9 L-4-fluorophenylalanine 
• 51-65-0 4-Fluorophenylalanine 
• 459-32-5 (E)-4-fluorocinnamic acid 
• 459-57-4 4-fluorobenzaldehyde 
• 325-89-3 3-amino-3-(4-fluorophenyl)propanoic acid 
• 459-32-5 4-fluorocinnamic acid 
• 405-99-2 para-fluorostyrene 
• 930769-46-3 (+/-)-4-(4-fluorophenyl)-2-azetidinone 
• 171002-17-8 β-(N-phenylacetylamino)-β-(4-fluorophenyl)propionic acid 
• 218166-05-3 3-amino-3-(4-fluorophenyl)propionic acid ethyl ester 

Downstream Products

• 784205-28-3 C₁₅H₁₂Cl₂FNO₄S 
• 784205-67-0 C₁₆H₁₃F₄NO₄S 

Relevant articles and documents

Kinetic Resolution of Aromatic β-Amino Acids Using a Combination of Phenylalanine Ammonia Lyase and Aminomutase Biocatalysts

An enzymatic strategy for the preparation of (R)-β-arylalanines employing phenylalanine aminomutase and ammonia lyase (PAM and PAL) enzymes has been demonstrated. Candidate PAMs with the desired (S)-selectivity from Streptomyces maritimus (EncP) and Bacillus sp. (PabH) were identified via sequence analysis using a well-studied template sequence. The newly discovered PabH could be linked to the first ever proposed biosynthesis of pyloricidin-like secondary metabolites and was shown to display better β-lyase activity in many cases. In spite of this, a method combining the higher conversion of EncP with a strict α-lyase from Anabaena variabilis (AvPAL) was found to be more amenable, allowing kinetic resolution of five racemic substrates and a preparative-scale reaction with >98% (R) enantiomeric excess. This work represents an improved and enantiocomplementary method to existing biocatalytic strategies, allowing simple product separation and modular telescopic combination with a preceding chemical step using an achiral aldehyde as starting material. (Figure presented.).

Influence of the aromatic moiety in α- And β-arylalanines on their biotransformation with phenylalanine 2,3-aminomutase from: Pantoea agglomerans

In this study enantiomer selective isomerization of various racemic α- and β-arylalanines catalysed by phenylalanine 2,3-aminomutase from Pantoea agglomerans (PaPAM) was investigated. Both α- and β-arylalanines were accepted as substrates when the aryl moiety was relatively small, like phenyl, 2-, 3-, 4-fluorophenyl or thiophen-2-yl. While 2-substituted α-phenylalanines bearing bulky electron withdrawing substituents did not react, the corresponding substituted β-aryl analogues were converted rapidly. Conversion of 3- and 4-substituted α-arylalanines happened smoothly, while conversion of the corresponding β-arylalanines was poor or non-existent. In the range of pH 7-9 there was no significant influence on the conversion of racemic α- or β-(thiophen-2-yl)alanines, whereas increasing the concentration of ammonia (ammonium carbonate from 50 to 1000 mM) inhibited the isomerization progressively and decreased the amount of the by-product (i.e. (E)-3-(thiophen-2-yl)acrylic acid was detected). In all cases, the high ee values of the products indicated excellent enantiomer selectivity and stereospecificity of the isomerization except for (S)-2-nitro-α-phenylalanine (ee 92%) from the β-isomer. Substituent effects were rationalized by computational modelling revealing that one of the main factors controlling biocatalytic activity was the energy difference between the covalent regioisomeric enzyme-substrate complexes.

Enantioselective acylation of β-phenylalanine acid and its derivatives catalyzed by penicillin G acylase from alcaligenes faecalis

This study developed a simple, efficient method for producing racemic β-phenylalanine acid (BPA) and its derivatives via the enantioselective acylation catalyzed by the penicillin G acylase from Alcaligenes faecalis (Af-PGA). When the reaction was run at 25°C and pH 10 in an aqueous medium containing phenylacetamide and BPA in a molar ratio of 2:1, 8 U/mL enzyme and 0.1 M BPA, the maximum BPA conversion efficiency at 40 min only reached 36.1%, which, however, increased to 42.9% as the pH value and the molar ratio of phenylacetamide to BPA were elevated to 11 and 3:1, respectively. Under the relatively optimum reaction conditions, the maximum conversion efficiencies of BPA derivatives all reached about 50% in a relatively short reaction time (45-90 min). The enantiomeric excess value of product (eep) and enantiomeric excess value of substrate (ees) were all above 98% and 95%, respectively. These results suggest that the method established in this study is practical, effective, and environmentally benign and may be applied to industrial production of enantiomerically pure BPA and its derivatives.

Mechanism-inspired engineering of phenylalanine aminomutase for enhanced β-regioselective asymmetric amination of cinnamates

Turn to switch: A mutant of phenylalanine aminomutase was engineered that can catalyze the regioselective amination of cinnamate derivatives (see scheme, red) to, for example, β-amino acids. This regioselectivity, along with the X-ray crystal structures, suggests two distinct carboxylate binding modes differentiated by Cβi￡Cipso bond rotation, which determines if β- (see scheme) or α-addition takes place. Copyright

Kinetic resolution of aromatic β-amino acids by ω-transaminase

Racemic aromatic β-amino acids have been kinetically resolved into (R)-β-amino acids with high enantiomeric excess (>99%) by a novel ω-TA with ca. 50% conversion.

Enhanced conversion of racemic α-arylalanines to (R)-β- arylalanines by coupled racemase/aminomutase catalysis

(Graph Presented) The Taxus phenylalanine aminomutase (PAM) enzyme converts several (S)-α-arylalanines to their corresponding (R)-β- arylalanines. After incubating various racemic substrateswith 100 μg of PAM for 20 h at 31°C, each (S)-α-arylalanine was enantioselectively isomerized to its corresponding (R)-β-product. With racemic starting materials, the ratio of (R)-β-arylalanine product to the (S)-α-substrate ranged between 0.4 and 1.8, and the remaining nonproductive (R)-α-arylalanine became enriched. To utilize the (R)-α-isomer, the catalysis of a promiscuous alanine racemase from Pseudomonas putida (KT2440) was coupled with that of PAM to increase the production of enantiopure (R)-β-arylalanines from racemic α-arylalanine substrates. The inclusion of a biocatalytic racemization along with the PAM-catalyzed reactionmoderately increased the overall reaction yield of enantiopure β-arylalanines between 4% and 19% (depending on the arylalanine), which corresponded to as much as a 63% increase compared to the turnover with the aminomutase reaction alone. The use of these biocatalysts, in tandem, could potentially find application in the production of chiral β-arylalanine building blocks, particularly, as refinements to the process are made that increase reaction flux, such as by selectively removing the desired (R)-β-arylalanine product from the reaction mixture. 2009 American Chemical Society.

Phenylalanine aminomutase-catalyzed addition of ammonia to substituted cinnamic acids: A route to enantiopure α- and β-amino acids

(Chemical Equation Presented) An approach is described for the synthesis of aromatic α- and β-amino acids that uses phenylalanine aminomutase to catalyze a highly enantioselective addition of ammonia to substituted cinnamic acids. The reaction has a broad scope and yields substituted α- and β-phenylalanines with excellent enantiomeric excess. The regioselectivity of the conversion is determined by substituents present at the aromatic ring. A box model for the enzyme active site is proposed, derived from the influence of the hydrophobicity of substituents on the enzyme affinity toward various substrates.

β-styryl- and β-aryl-β-alanine products of phenylalanine aminomutase catalysis

The substrate specificity of a Taxus-derived phenylalanine aminomutase (PAM) was investigated, and the enzyme was found to catalyze the conversion of variously substituted vinyl- and aryl-S-∞-alanines to corresponding β-amino acids. This study shows the b

A new route to enantiopure β-aryl-substituted β-amino acids and 4-aryl-substituted β-lactams through lipase-catalyzed enantioselective ring cleavage of β-lactams

A simple and efficient direct enzymatic method was developed for the synthesis of 4-aryl-substituted β-lactams and the corresponding β-amino acid enantiomers through the CAL-B (lipase B from Candida antarctica)-catalyzed enantioselective (E > 200) ring cleavage of the corresponding racemic β-lactams with 1 equiv. of H2O in i-Pr2O at 60°C. The product (R)-β-amino acids (ee ≥ 98%, yields ≥ 42%) and unreacted (S)-β-lactams (ee ≥ 95%, yields ≥ 41%) could be easily separated. The ring opening of enantiomeric β-lactams with 18% HCl afforded the corresponding enantiopure β-amino acid hydrochlorides (ee ≥ 99%).

The first aminoacylase-catalyzed enantioselective synthesis of aromatic β-amino acids

The first aminoacylase-catalyzed enantioselective synthesis of aromatic β-amino acids is reported. The presence of an N-chloroacetyl group as acyl group in the substrate as well as the use of porcine kidney acylase I as a suitable enzyme component are prerequisites for this resolution process whereby optically active β-amino acids are formed with high enantioselectivlties of >98% ee.