7325-16-8

Usage

Uses

Used in Cosmetic Industry:
GLYCEROL-(OD)3 is used as a humectant and solvent for its enhanced solubility and reactivity, improving the texture and moisturizing properties of cosmetic products.
Used in Food Industry:
GLYCEROL-(OD)3 is used as a sweetener and humectant in food products, providing a natural and safe alternative to artificial sweeteners and preservatives.
Used in Pharmaceutical Industry:
GLYCEROL-(OD)3 is used as a solvent and humectant in the formulation of pharmaceutical products, potentially improving the stability and effectiveness of medications.
Used in Chemical Synthesis and Manufacturing:
GLYCEROL-(OD)3 is used as a versatile compound in chemical synthesis and manufacturing processes, taking advantage of its enhanced solubility and reactivity due to the presence of three oxygen atoms.
Further research and experimentation are required to fully explore the potential uses and properties of GLYCEROL-(OD)3, as specific information on GLYCEROL-(OD)3 is currently limited.

InChI:InChI=1/C3H8O3/c4-1-3(6)2-5/h3-6H,1-2H2/i4D,5D,6D

Upstream product

• 811-98-3 d⁽⁴⁾-methanol 
• 102-76-1 triacetylglycerol 

Relevant academic research and scientific papers

Catalysis of transesterification reactions by lanthanides - Unprecedented acceleration of methanolysis of aryl and alkyl esters promoted by La(OTf)3 at neutral sspH and ambient temperatures

La3+ catalysis of the methanolysis of the esters p-nitrophenyl, 2,4-dinitrophenyl, and phenyl acetate (1-3), phenyl benzoate (4), and ethyl, i-propyl, cyclohexyl, and tert-butyl acetate (5, 6a, 6b, 7) was studied at 25°C as a function of sspH and [La(OTf)3]. The active form of the catalyst is attributed to a dimethoxy-bridged dimer of stoichiometry (La3+)2(-OCH3)2, having maximum activity atsspH 8 to 9. For preparative reactions, the active catalyst can be made in situ simply by adding 0.01 equiv of La(OTf)3, and 0.01 equiv of NaOCH3 to a methanol solution containing the ester (1 M). Strong catalysis of methanolysis of both aryl and alkyl esters was observed, although tert-butyl acetate was inert. At sspH 8.5, where the catalyst is maximally active, the transesterification reactions are accelerated by 40 000-fold to 18 000 000-fold in the presence of as little as 5 mM catalyst relative to the background reaction depending on the ester structure. A mechanism for catalysis of transesterification is presented wherein the reactive species is generated by breaking a single La-OCH3 bond of the dimethoxy-bridged dimer to reveal a nucleophilic metal-bound methoxide - Lewis acid La3+ electrophilic pair.