74069-74-2

Basic information

• Product Name: (R)-2-Nonanamine
• Synonyms: (R)-(-)-2-AMINONONANE;(R)-2-NONYLAMINE;(S)-(+)-2-AMINONONANE;(S)-2-NONYLAMINE;(2R)-Nonylamine;(R)-1-Methyloctylamine;(R)-(-)-2-AMINONONANE: CHIPROS 99%, EE 98%;(R)-(-)-2-Aminononane, ChiPros 99+%, ee 98+%
• CAS NO: 74069-74-2
• Molecular Formula: C₉H₂₁N
• Molecular Weight: 143.27
• EINECS: -0
• Mol File: 74069-74-2.mol

Chemical Properties

• Melting Point: <-20°C
• Boiling Point: 73°C 19mm
• Flash Point: 71°C
• Appearance: /
• Density: 0,782 g/cm3
• Vapor Pressure: 0.526mmHg at 25°C
• Refractive Index: 1.4271
• Sensitive: Air Sensitive
• CAS DataBase Reference: (R)-2-Nonanamine(CAS DataBase Reference)
• NIST Chemistry Reference: (R)-2-Nonanamine(74069-74-2)
• EPA Substance Registry System: (R)-2-Nonanamine(74069-74-2)

Safety Data

• Hazard Codes: C,N
• Statements: 34-50/53-35-20/21/22
• Safety Statements: 26-36/37/39-45-61
• RIDADR: 2735
• WGK Germany: 3
• HazardClass: 8
• PackingGroup: II
• Hazardous Substances Data: 74069-74-2(Hazardous Substances Data)

Usage

Uses

Used in Pharmaceutical Industry:
(R)-2-Nonanamine is used as a key intermediate in the synthesis of various pharmaceuticals for its ability to contribute to the chiral centers of drug molecules, which is crucial for their biological activity and selectivity.
Used in Agrochemical Industry:
In agrochemicals, (R)-2-Nonanamine serves as a building block for the creation of chiral pesticides and other compounds, enhancing the effectiveness and selectivity of these products in agricultural applications.
Used in Organic Synthesis:
(R)-2-Nonanamine is utilized as a reagent in organic synthesis, particularly for the preparation of chiral amines and other complex organic molecules, due to its unique structural features.
Used in Research and Development:
(R)-2-Nonanamine is employed as a target in research for the development of new drugs and materials, given its potential to influence biological processes and its applicability in various industrial settings.
Used in Material Science:
(R)-2-Nonanamine is also used in material science for the development of new materials with specific properties, leveraging its chiral nature to create materials with unique characteristics for various applications.

InChI:InChI=1/C9H21N/c1-3-4-5-6-7-8-9(2)10/h9H,3-8,10H2,1-2H3/t9-/m1/s1

Upstream product

• 821-55-6 2-Nonanone 
• 869278-88-6 (S)-(+)-2-aminononane 
• 5329-79-3 (R)‐2‐aminohexane 

Downstream Products

• 821-55-6 2-Nonanone 
• 869278-88-6 (S)-(+)-2-aminononane 
• 5329-79-3 (R)‐2‐aminohexane 

Relevant articles and documents

Separate Sets of Mutations Enhance Activity and Substrate Scope of Amine Dehydrogenase

Mutations were introduced into the leucine amine dehydrogenase (L-AmDH) derived from G. stearothermophilus leucine dehydrogenase (LeuDH) with the goals of increased activity and expanded substrate acceptance. A triple variant (L-AmDH-TV) including D32A, F101S, and C290V showed an average of 2.5-fold higher activity toward aliphatic ketones and an 8.0 °C increase in melting temperature. L-AmDH-TV did not show significant changes in relative activity for different substrates. In contrast, L39A, L39G, A112G, and T133G in varied combinations added to L-AmDH-TV changed the shape of the substrate binding pocket. L-AmDH-TV was not active on ketones larger than 2-hexanone. L39A and L39G enabled activity for straight-chain ketones as large as 2-decanone and in combination with A112G enabled activity toward longer branched ketones including 5-methyl-2-octanone.

Reshaping the Active Pocket of Amine Dehydrogenases for Asymmetric Synthesis of Bulky Aliphatic Amines

The asymmetric reductive amination of ketones with ammonia using engineered amine dehydrogenases (AmDHs) is a particularly attractive and environmentally friendly method for the synthesis of chiral amines. However, one major challenge for these engineered AmDHs is their limited range of accepted substrates. Herein, several engineered AmDHs were developed through the evolution of naturally occurring leucine dehydrogenases, which displayed good amination activity toward aliphatic ketones but restricted catalytic scope for short-chain substrates. Computational analysis helped identify two residues, located at the distal end of the substrate-binding cavity, that generate steric hindrance and prevent the binding of bulky aliphatic ketones. By fine-tuning these two key hotspots, the resulting AmDH mutants are able to accept previously inaccessible bulky substrates. More importantly, the mutations were also proved applicable for expanding the substrate scope of other homologous AmDHs with sequence identities as low as 70%, indicating a broad effect on the development of AmDHs and the synthesis of structurally diverse chiral amines.

Enzymatic asymmetric synthesis of enantiomerically pure aliphatic, aromatic and arylaliphatic amines with (R)-selective amine transaminases

Seven (R)-selective amine transaminases (R-ATAs) recently discovered by an in silico-based approach in sequence databases were produced recombinantly in Escherichia coli and subjected to partial purification by ammonium sulfate precipitation. A range of additives and various buffers were investigated to identify best conditions to ensure good storage stability and stable activity during biocatalysis. All enzymes show pH optima between pH 7.5-9. These R-ATAs were then applied in the asymmetric synthesis of twelve aliphatic, aromatic and arylaliphatic (R)-amines starting from the corresponding prochiral ketones using a lactate dehydrogenase/glucose dehydrogenase system to shift the equilibrium. For all ketones, at least one enzyme was found that allows complete conversion to the corresponding chiral amine having excellent optical purities >99% ee. Variations in substrate profiles are also discussed based on the phylogenetic relationships between the seven R-ATAs. Thus, we have identified a versatile toolbox of (R)-amine transaminases showing remarkable properties for application in biocatalysis. Copyright

Enzymatic racemization of amines catalyzed by enantiocomplementary ω-Transaminases

A strategy for the biocatalytic racemization of primary α-chiral amines was developed by employing a pair of stereocomplementary PLP-dependent ω-transaminases. The interconversion of amine enantiomers proceeded through reversible transamination by a prochiral ketone intermediate, either catalyzed by a pair of stereocomplementary ω-transaminases or by a single enzyme possessing low stereoselectivity. To tune the system, the type and concentration of a nonchiral amino acceptor proved to be crucial. Finally, racemization could be achieved by the cross-transamination of two different amines without a requirement for an external amino acceptor. Several synthetically and industrially important amines could be enzymatically racemized under mild reaction conditions. ω-Transaminases play ping-pong: A biocatalytic protocol for the 'clean' racemization of α-chiral prim-amines was developed by an equilibrium-controlled deamination/amination sequence catalyzed by a pair of (R)- and (S)-ω-transaminases (see scheme).