COMPUTATIONAL STUDY WITH DENSITY FUNCTIONAL THEORY APPROACH FOR REACTION MECHAMISM OF CHALCONE-FLAVANONE CONVERSION
Flavanones are compounds of the flavanoid class which have many benefits, one of them that is very useful in the field of pharmacology as a precursor of drugs. The synthesis of flavanones, both naturally in plants and experimentally in the laboratory, is often carried out by converting chalcon...
Saved in:
| Main Author: | |
|---|---|
| Format: | Dissertations |
| Language: | Indonesia |
| Subjects: | |
| Online Access: | https://digilib.itb.ac.id/gdl/view/75435 |
| Tags: |
Add Tag
No Tags, Be the first to tag this record!
|
| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Flavanones are compounds of the flavanoid class which have many benefits, one of
them that is very useful in the field of pharmacology as a precursor of drugs. The
synthesis of flavanones, both naturally in plants and experimentally in the
laboratory, is often carried out by converting chalcone molecule to flavanone.
Biosynthetically, the conversion reaction of chalcone into flavanone takes place
with the help of the enzyme chalcone isomerase (CHI). This reaction is known to
occur in a simple, one-step, and produces enantioselective products. However, the
synthesis of flavanone from 2-hydroxy chalcone in the laboratory often results in a
racemic product, a mixture of 2S-flavanone and 2R-flavanone. One of the effective
methods for converting chalcone into flavanone that has been done by previous
researchers is to use methane sulfonic acid as a catalyst. Even though the reaction
product is a racemic product, this reaction can take place by producing a good
yield. In addition, the methane sulfonic acid catalyst is suitable for green chemistry
applications. Other catalysts that have been used to produce enantioselective
products are from aminoquinoline and pyrrolidine derivatives. This catalyst is
taken from the active site segment of the CHI enzyme. Whether catalyzed by
methane sulfonic acid or by aminoquinoline and pyrrolidine derivatives, the
mechanism for this reactions are not known with certainty. So the purpose of this
research is to study the reaction mechanism for the conversion of chalcones to
flavanones with methane sulfonic acid catalyst and aminoquinoline and
pyrrolidone derivatives as catalysts. The research method used is quantum
computing with density function theory (DFT) at the level of theory and basis sets
M06-2X/6-311**(d,p). The results of computational calculations show that the
reaction mechanism of the conversion of chalcones into flavanones with methane
sulfonic acid catalyst occurs through two steps, namely the cyclization step and the
carbonylation step. The reaction mechanism of the conversion of chalcones into
flavanones with the catalyst of aminoquinoline and pyrrolidine derivatives takes
place through two similar steps, the cyclization and carbonylation steps. The use of
asymmetric catalysts derived from aminoquinoline and pyrrolidine can lead to the
formation of S-flavanone products by forming ?…?-stacking interaction and
hydrogen bonds between the reactants and the catalyst.
|
|---|