140630-45-1

Basic information

• Product Name: 2-Propanol, 1-chloro-3-phenoxy-, (R)-
• CAS NO: 140630-45-1
• Molecular Formula: C9H11ClO2
• Molecular Weight: 186.638
• Mol File: 140630-45-1.mol
• Article Data: 28

Chemical Properties

• CAS DataBase Reference: 2-Propanol, 1-chloro-3-phenoxy-, (R)-(CAS DataBase Reference)
• NIST Chemistry Reference: 2-Propanol, 1-chloro-3-phenoxy-, (R)-(140630-45-1)
• EPA Substance Registry System: 2-Propanol, 1-chloro-3-phenoxy-, (R)-(140630-45-1)

Safety Data

• Hazardous Substances Data: 140630-45-1(Hazardous Substances Data)

Upstream product

• 140428-46-2 1-chloro-3-phenoxypropan-2-yl acetate 
• 108-05-4 vinyl acetate 
• 4769-73-7 (RS)-1-chloro-3-phenyloxy-2-propanol 
• 940-47-6 1-chloro-3-phenoxyacetone 
• 106-89-8 epichlorohydrin 
• 108-95-2 phenol 
• 122-60-1 Phenyl glycidyl ether 
• 71031-03-3 (R)-phenyl glycidyl ether 
• 108-22-5 Isopropenyl acetate 
• 51594-55-9 (R)-(-)-epichlorohydrin 
• 538-43-2 3-phenoxy-1,2-propanediol 
• 123-20-6 vinyl n-butyrate 
• 876-27-7 4-chlorophenyl acetate 
• 1746-13-0 allyl phenyl ether 

Downstream Products

• 71031-03-3 (R)-phenyl glycidyl ether 
• 71031-03-3 (2R)-1,2-epoxy-3-phenoxypropane 
• 4769-73-7 (RS)-1-chloro-3-phenyloxy-2-propanol 
• 82430-43-1 (S)-3-chloro-1-phenoxy-2-propanol 
• 538-43-2 3-phenoxy-1,2-propanediol 
• 112243-65-9 (S)-2-hydroxy-3-phenoxypropylamine 
• 106351-44-4 (2S)-1-Isopropylamino-3-phenoxy-2-propanol 

Relevant articles and documents

Exploring the Biocatalytic Scope of a Novel Enantioselective Halohydrin Dehalogenase from an Alphaproteobacterium

A gene encoding halohydrin dehalogenase from an alphaproteobacterium (AbHHDH) was identified, cloned and over-expressed in Escherichia coli. AbHHDH was able to catalyze the stereoselective dehalogenation of prochiral and racemic halohydrins. It showed the highest enantioselectivity in the dehalogenation of 20?mM (R,S)-2-bromo-1-phenylethanol, which yielded (S)-2-bromo-1-phenylethanol with 99% ee and 34.5% yield. Moreover, AbHHDH catalyzed the azidolysis of epoxides with low to moderate (S)-enantioselectivity. The highest enantioselectivity (E = 18.6) was observed when (R,S)-benzyl glycidyl ether was used as the substrate. A sequential kinetic resolution catalyzed by HHDH was employed for the synthesis of chiral 1-chloro-3-phenoxy-2-propanol. We prepared enantiopure (S)-isomer with a high enantiopurity of ee > 99% and a yield of 30.7% (E-value: 21.3) by kinetic resolution of 20?mM substrate. The (S)-isomer with 99% ee readily obtained from 40 to 150?mM (R,S)-1-chloro-3-phenoxy-2-propanol. Taken together, the results of this study demonstrate the applicability of this HHDH for the production of optically active compounds. [Figure not available: see fulltext.].

Synthesis of enantiopure epoxide by 'one pot' chemoenzymatic approach using a highly enantioselective dehydrogenase

Enantiopure α-phenethyl alcohols, including aromatic halohydrins, are important chiral building blocks. One of the best approaches to synthesise α-phenethyl alcohols is asymmetric reduction of prochiral ketones by alcohol dehydrogenases (ADHs). The obtained enantiopure halohydrin could be directly used to produce enantiopure epoxide through a base-induced ring-closure reaction, which is an attractive 'one pot' chemoenzymatic method for producing high-yield epoxide. In this study, a novel medium-chain dehydrogenase (KcDH) from Kuraishia capsulate CBS1993 was identified and characterised to show its broad substrate scope and excellent enantioselectivity. KcDH showed activities on 25 substrates of the 26 tested aromatic ketones and heteroaryl ketones, with an enantiomeric excess (ee) >99% and the highest relative activity observed with para-nitro acetophenone. Due to its high enantioselectivity for α-haloketones, a chemoenzymatic method for the synthesis of enantiopure styrene oxide (SO) and phenyl glycidyl ether (PGE) was developed through a base-induced ring-closure reaction on enantiopure halohydrin obtained with KcDH. (R)-SO and (S)-PGE were obtained in 86% and 94% analytical yield, respectively, and both epoxides were obtained with ee >99%. Thus, our results suggested that KcDH may be a promising biocatalyst for the production of multiple enantiopure α-phenethyl alcohols and epoxides.

Tuning of the electronic properties of a cyclopentadienylruthenium catalyst to match racemization of electron-rich and electron-deficient alcohols

The synthesis of a new series of cyclopentadienylruthenium catalysts with varying electronic properties and their application in racemization of secondary alcohols are described. These racemizations involve two key steps: 1) β-hydride elimination (dehydrogenation) and 2) re-addition of the hydride to the intermediate ketone. The results obtained confirm our previous theory that the electronic properties of the substrate determine which of these two steps is rate determining. For an electron-deficient alcohol the rate-determining step is the β-hydride elimination (dehydrogenation), whereas for an electron-rich alcohol the re-addition of the hydride becomes the rate-determining step. By matching the electronic properties of the catalyst with the electronic properties of the alcohol, we have now shown that a dramatic increase in racemization rate can be obtained. For example, electron-deficient alcohol 15 racemized 30 times faster with electron-deficient catalyst 6 than with the unmodified standard catalyst 4. The application of these protocols will extend the scope of cyclopentadienylruthenium catalysts in racemization and dynamic kinetic resolution. Copyright