930-46-1

Basic information

• Product Name: (1R)-TRANS-1,2-CYCLOPENTANEDIOL
• Synonyms: (1R,2R)-(-)-TRANS-1,2-CYCLOPENTANEDIOL;(1R,2R)-TRANS-1,2-CYCLOPENTANEDIOL;(1R)-TRANS-1,2-CYCLOPENTANEDIOL
• CAS NO: 930-46-1
• Molecular Formula: C₅H₁₀O₂
• Molecular Weight: 102.13
• Product Categories: Chiral Building Blocks;Organic Building Blocks;Polyols
• Mol File: 930-46-1.mol
• Article Data: 30

Chemical Properties

• Melting Point: 47-51 °C(lit.)
• Boiling Point: 216.4°Cat760mmHg
• Flash Point: 112.7°C
• Appearance: /
• Density: 1.235g/cm³
• Vapor Pressure: 0.0304mmHg at 25°C
• Refractive Index: 1.547
• Storage Temp.: 2-8°C
• CAS DataBase Reference: (1R)-TRANS-1,2-CYCLOPENTANEDIOL(CAS DataBase Reference)
• NIST Chemistry Reference: (1R)-TRANS-1,2-CYCLOPENTANEDIOL(930-46-1)
• EPA Substance Registry System: (1R)-TRANS-1,2-CYCLOPENTANEDIOL(930-46-1)

Safety Data

• Safety Statements: 22-24/25
• WGK Germany: 3
• F: 3-10
• Hazardous Substances Data: 930-46-1(Hazardous Substances Data)

Usage

Uses

(1R,2R)-trans-1,2-Cyclopentanediol can be used as a chiral auxiliary. It is a building block for the synthesis of chiral phosphine ligands.

InChI:InChI=1/C5H10O2/c6-4-2-1-3-5(4)7/h4-7H,1-3H2/t4-,5-/m1/s1

Upstream product

• 5057-99-8 trans-cyclopentane-1,2-diol 
• 285-67-6 Cyclopentene oxide 
• 20520-67-6 (1R,2R)-2-hydroxycyclopentyl acetate 
• 135357-03-8 trans-1-Phenoxy-cyclopentanol-⁽²⁾ 
• 26620-22-4 (+/-)-trans-1,2-diacetoxycyclopentane 
• 113625-73-3 (1R,2R)-(-)-2-benzyloxycyclopentanol 
• 113350-85-9 (1R,2R)-(-)-1,2-bis(phenylmethoxy)cyclopentane 
• 329-15-7 4-trifluoromethyl-phenyl acetyl chloride 
• 122-01-0 4-chloro-benzoyl chloride 
• 113625-72-2 (1R,2R)-(-)-trans-2-methoxycyclopentanol 
• 1072-59-9 1-methoxycyclopentene 
• 241147-46-6 ((1R,2R)-2-Methoxy-cyclopentyloxy)-trimethyl-silane 
• 81455-00-7 trans-2-Phenoxycyclopentan-1-ol 
• 113625-73-3 rel-(1R,2R)-2-(benzyloxy)-1-cyclopentanol 

Downstream Products

• 20520-67-6 (1R,2R)-2-hydroxycyclopentyl acetate 
• 156618-45-0 R,R-P(C₆F₅)2OC₅H₈OP(C₆H₅)2 
• 7234-76-6 7,8,9,10-tetrahydrobenzo[g]cyclopenta[b]indole 
• 113625-73-3 (1R,2R)-(-)-2-benzyloxycyclopentanol 
• 99440-98-9 2-hydroxycyclopentanone 
• 287-92-3 Cyclopentane 
• 96-41-3 Cyclopentanol 
• 120-92-3 cyclopentanone 

Relevant articles and documents

One-Pot Enzymatic Synthesis of Cyclic Vicinal Diols from Aliphatic Dialdehydes via Intramolecular C?C Bond Formation and Carbonyl Reduction Using Pyruvate Decarboxylases and Alcohol Dehydrogenases

An enzymatic cascade reaction was developed for one-pot enantioselective conversion of aliphatic dialdehydes to chiral vicinal diols using pyruvate decarboxylases (PDCs) and alcohol dehydrogenases (ADHs). The PDCs showed promiscuity in catalysing the cyclization of aliphatic dialdehydes through intramolecular stereoselective carbon-carbon bond formation. Consequently, 1,2-cyclopentanediols in three different stereoisomeric forms and 1,2-cyclohexanediols in two different stereoisomeric forms could be prepared with high conversion and stereoisomeric ratio from the respective initial substrates, glutaraldehyde and adipaldehyde. These cascade reactions represent a promising approach to the biocatalytic synthesis of important chiral vicinal diols. (Figure presented.).

Hydrogen Bonding-Assisted Enhancement of the Reaction Rate and Selectivity in the Kinetic Resolution of d,l-1,2-Diols with Chiral Nucleophilic Catalysts

An extremely efficient acylative kinetic resolution of d,l-1,2-diols in the presence of only 0.5 mol% of binaphthyl-based chiral N,N-4-dimethylaminopyridine was developed (selectivity factor of up to 180). Several key experiments revealed that hydrogen bonding between the tert-alcohol unit(s) of the catalyst and the 1,2-diol unit of the substrate is critical for accelerating the rate of monoacylation and achieving high enantioselectivity. This catalytic system can be applied to a wide range of substrates involving racemic acyclic and cyclic 1,2-diols with high selectivity factors. The kinetic resolution of d,l-hydrobenzoin and trans-1,2-cyclohexanediol on a multigram scale (10 g) also proceeded with high selectivity and under moderate reaction conditions: (i) very low catalyst loading (0.1 mol%); (ii) an easily achievable low reaction temperature (0 °C); (iii) high substrate concentration (1.0 M); and (iv) short reaction time (30 min). (Figure presented.).

Structure-Guided Triple-Code Saturation Mutagenesis: Efficient Tuning of the Stereoselectivity of an Epoxide Hydrolase

The directed evolution of enzymes promises to eliminate the long-standing limitations of biocatalysis in organic chemistry and biotechnology - the often-observed limited substrate scope, insufficient activity, and poor regioselectivity or stereoselectivity. Saturation mutagenesis at sites lining the binding pocket with formation of focused libraries has emerged as the technique of choice, but choosing the optimal size of the randomization site and reduced amino acid alphabet for minimizing the labor-determining screening effort remains a challenge. Here, we introduce structure-guided triple-code saturation mutagenesis (TCSM) by encoding three rationally chosen amino acids as building blocks in the randomization of large multiresidue sites. In contrast to conventional NNK codon degeneracy encoding all 20 canonical amino acids and requiring the screening of more than 1015 transformants for 95% library coverage, TCSM requires only small libraries not exceeding 200-800 transformants in one library. The triple code utilizes structural (X-ray) and consensus-derived sequence data, and is therefore designed to match the steric and electrostatic characteristics of the particular enzyme. Using this approach, limonene epoxide hydrolase has been successfully engineered as stereoselective catalysts in the hydrolytic desymmetrization of meso-type epoxides with formation of either (R,R)- or (S,S)-configurated diols on an optional basis and kinetic resolution of chiral substrates. Crystal structures and docking computations support the source of notably enhanced and inverted enantioselectivity.