95-43-2

Basic information

• Product Name: D-(-)-THREOSE
• Synonyms: D-(-)-THREOSE;D-THREOSE;D(-)-THREOSE SYRUP;Threose;(2S,3R)-2,3,4-Trihydroxybutanal;C06463;D-Threo-tetrose;D-Threose (contains 35% Water at maximum)
• CAS NO: 95-43-2
• Molecular Formula: C₄H₈O₄
• Molecular Weight: 120.1
• EINECS: 202-418-0
• Product Categories: Carbohydrate Synthesis;Carbohydrates;Carbohydrates A to;Carbohydrates P-ZBiochemicals and Reagents;Monosaccharides;MonosaccharideSpecialty Synthesis
• Mol File: 95-43-2.mol
• Article Data: 26

Chemical Properties

• Melting Point: 130℃
• Boiling Point: 144.07°C (rough estimate)
• Flash Point: 129.54 °C
• Appearance: /syrup
• Density: 1.0500 (rough estimate)
• Vapor Pressure: 0mmHg at 25°C
• Refractive Index: 1.4502 (estimate)
• Storage Temp.: 2-8°C
• Solubility: Methanol (Slightly), Water (Soluble)
• BRN: 1721696
• CAS DataBase Reference: D-(-)-THREOSE(CAS DataBase Reference)
• NIST Chemistry Reference: D-(-)-THREOSE(95-43-2)
• EPA Substance Registry System: D-(-)-THREOSE(95-43-2)

Safety Data

• WGK Germany: 3
• F: 3-10
• Hazardous Substances Data: 95-43-2(Hazardous Substances Data)

Usage

Description

D-(-)-THREOSE, also known as D-threose, is a carbohydrate that is the D-stereoisomer of threose. It is a monosaccharide, which is a simple sugar, and plays a crucial role in various biological processes.
Used in Pharmaceutical Industry:
D-(-)-THREOSE is used as a building block for the synthesis of glucose and mannose derivatives, which are important in the development of pharmaceutical compounds. These derivatives have potential applications in the treatment of various diseases and disorders.
Used in Biochemical Research:
D-(-)-THREOSE is used as a research tool in biochemical studies to understand the structure, function, and metabolism of carbohydrates. It helps researchers gain insights into the mechanisms of carbohydrate metabolism and their role in various biological processes.
Used in Food Industry:
D-(-)-THREOSE is used as a sweetener in the food industry due to its natural sugar content. It can be used as an alternative to other sweeteners, providing a healthier option for consumers.
Used in Cosmetic Industry:
D-(-)-THREOSE is used in the cosmetic industry for its moisturizing and skin conditioning properties. It helps improve the texture and appearance of the skin, making it a valuable ingredient in various cosmetic products.

InChI:InChI=1/C4H8O4/c5-2-1-8-4(7)3(2)6/h2-7H,1H2/t2-,3+,4+/m1/s1

Upstream product

• 59-23-4 D-Galactose 
• 95140-39-9 5,5-bis-ethanesulfonyl-D_g-threo-pent-4-ene-1,2,3-triol 
• 533-50-6 D-erythrulose 
• 58-86-6 D-xylose 
• 2418-52-2 D-threitol 
• 72599-80-5 D-threofuranose 
• 80877-73-2 β-D-threo-1,4-furanose 
• 80877-72-1 α-D-threo-1,4-furanose 
• 31873-23-1 4,4-bis-acetylamino-D_g-threo-butane-1,2,3-triol 
• 7664-93-9 sulfuric acid 
• 31880-23-6 1,1-bis-ethanesulfonyl-D-1-deoxy-xylitol 
• 453-17-8 D-Glyceraldehyde 
• 141-46-8 Glycolaldehyde 
• 23147-58-2 glycolaldehyde dimer 

Downstream Products

• 109257-00-3 2-p-toluidino-2-deoxy-D-xylononitrile 
• 3154-37-8 3,4-dihydroxy-2-phenylhydrazono-butyraldehyde phenylhydrazone 
• 141-46-8 Glycolaldehyde 
• 533-50-6 D-erythrulose 
• 583-50-6 D-erythrose 
• 512-20-9 α-D-tagatopyranose 
• 20197-42-6 tagatose (β-pyranose) 
• 87-81-0 D-tagatose 
• 781577-54-6 calcium(II) oxalate 
• 5892-21-7 calcium mesotartrate*3H₂O 
• 2319-57-5 1,2,3,4-butanetetrol 
• 57-48-7 sorbose 
• 2418-52-2 D-threitol 

Relevant articles and documents

Enzymatic Synthesis of Unusual Sugars: Galactose Oxidase Catalyzed Stereospecific Oxidation of Polyols

-

Selective Reductive Dimerization of CO2into Glycolaldehyde

The selective dimerization of CO2 into glycolaldehyde is achieved in a one-pot two-step process via formaldehyde as a key intermediate. The first step concerns the iron-catalyzed selective reduction of CO2 into formaldehyde via formation and controlled hydrolysis of a bis(boryl)acetal compound. The second step concerns the carbene-catalyzed C-C bond formation to afford glycolaldehyde. Both carbon atoms of glycolaldehyde arise from CO2 as proven by the labeling experiment with 13CO2. This hybrid organometallic/organic catalytic system employs mild conditions (1 atm of CO2, 25 to 80 °C in less than 3 h) and low catalytic loadings (1 and 2.5%, respectively). Glycolaldehyde is obtained in 53% overall yield. The appealing reactivity of glycolaldehyde is exemplified (i) in a dimerization process leading to C4 aldose compounds and (ii) in a tri-component Petasis-Borono-Mannich reaction generating C-N and C-C bonds in one process.

Catalytic Gels for a Prebiotically Relevant Asymmetric Aldol Reaction in Water: From Organocatalyst Design to Hydrogel Discovery and Back Again

This paper reports an investigation into organocatalytic hydrogels as prebiotically relevant systems. Gels are interesting prebiotic reaction media, combining heterogeneous and homogeneous characteristics with a structurally organized active solid-like catalyst separated from the surrounding environment, yet in intimate contact with the solution phase and readily accessible via liquid-like diffusion. A simple self-assembling glutamine amide derivative 1 was initially found to catalyze a model aldol reaction between cyclohexanone and 4-nitrobenzaldehyde, but it did not maintain its gel structure during reaction. In this study, it was observed that compound 1 could react directly with the benzaldehyde to form a hydrogel in situ based on Schiff base 2 as a low-molecular-weight gelator (LMWG). This new dynamic gel is a rare example of a two-component self-assembled LMWG hydrogel and was fully characterized. It was demonstrated that glutamine amide 1 could select an optimal aldehyde component and preferentially assemble from mixtures. In the hunt for an organocatalyst, reductive conditions were applied to the Schiff base to yield secondary amine 3, which is also a highly effective hydrogelator at very low loadings with a high degree of nanoscale order. Most importantly, the hydrogel based on 3 catalyzed the prebiotically relevant aldol dimerization of glycolaldehyde to give threose and erythrose. In buffered conditions, this reaction gave excellent conversions, good diastereoselectivity, and some enantioselectivity. Catalysis using the hydrogel of 3 was much better than that using non-assembled 3 - demonstrating a clear benefit of self-assembly. The results suggest that hydrogels offer a potential strategy by which prebiotic reactions can be promoted using simple, prebiotically plausible LMWGs that can selectively self-organize from complex mixtures. Such processes may have been of prebiotic importance.

Catalytic effect of aluminium chloride on the example of the conversion of sugar model compounds

Abstract In this work, the catalytic effect of the Bronsted acid hydrochloric acid, the Bronsted base sodium hydroxide and the Lewis acid AlCl3 on the conversion of biomass derived carbohydrates is investigated. On the example of the glycolaldehyde conversion, it is shown that the Lewis acid catalyses the ketol-endiol-tautomerism, the dehydration, the retro-aldol-reaction and the benzilic-acid-rearrangement. The main products are C4- and C6-carbohydrates as well as their secondary products 2-hydroxybut-3-enoic acid 1 and several furans. Under the same reaction conditions hydrochloric acid catalyzes mainly the dehydration and sodium hydroxide the tautomerism and subsequent aldolization.