STRATEGY OF 4-ALLYLPHENOL SYNTHESIS AS DRUG PRECURSORS
The intermediate molecule 4-allylphenol or p-allylphenol has several applications, one of which is as a precursor for the synthesis of pharmacological compounds such as betaxolol. Betaxolol is a propanolamine-derived ?-blocker compound that is relatively cardio selective. Drug compounds classi...
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| Format: | Final Project |
| Language: | Indonesia |
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| Online Access: | https://digilib.itb.ac.id/gdl/view/80703 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | The intermediate molecule 4-allylphenol or p-allylphenol has several applications, one of
which is as a precursor for the synthesis of pharmacological compounds such as betaxolol.
Betaxolol is a propanolamine-derived ?-blocker compound that is relatively cardio
selective. Drug compounds classified as ?-blockers have been shown in several studies to
help treat people with hypertension and glaucoma. The effective way to treat glaucoma is
by reducing the IOP. In this case, betaxolol acts as a ? -1 adrenergic receptor blocking agent
which will selectively block one of receptors so that it will slow down the disease
progression and reduce the IOP. Based on the investigation of betaxolol compound
retrosynthesis, the simplest reagent for producing betaxolol compounds can be obtained,
namely 4-allylphenol (p-AP), which can be synthesized from allyl phenyl ether (APE). This
research aim to synthesize APE as a precursor for the synthesis of p-AP intermediate
compounds and characterize it as a synthesized product using NMR spectroscopy, as well
as to investigate several techniques for synthesizing p-AP intermediate compounds as
precursors for the synthesis of drug compounds via Claisen-Cope rearrangement reactions.
In this research, APE compound was effectively synthesized form phenol (C6H5OH) with
allyl bromide (C3H5Br) and anhydrous potassium carbonate (K2CO3) in anhydrous acetone
solvent through the Williamson ether reaction at 60 ?. Different treatments were used
throughout the reaction, including an overnight reaction without heating for 76 hours and
an overnight reaction with heating for 72 hours. Pure APE compounds were produced with
a higher yield of 60,06% during an overnight reaction followed by heating, than the yield
without heating, which was 23,84%. A further strategy that has been carried out in this
research is transformation of APE to allylphenol via the Claisen-Cope rearrangement
reaction. The reactions were carried out in static batch and flow systems. In the batch
system, two distinct reaction conditions were used: heating batch and heating batch
catalyzed by H-ZSM-5. The reactions under these various circumstances produced impure
mixed compound products. The H-ZSM-5 catalyzed heating reaction produced more
complex compounds than the heating-only reaction. In the flow system, two reaction
conditions were used: heating with or without acid-base extraction, and flow through an H
ZSM-5 catalyzed column. Impure mixed compound products were produced under reaction
circumstances involving acid-base extraction and/or the inclusion of H-ZSM-5 catalyst.
The reaction through the H-ZSM-5 acid-catalyzed column produced more selective
products, including simpler new stains on the chromatogram, than the reaction using acid
base extraction. According to the reaction results, the Claisen-Cope rearrangement of APE
to allylphenol occurs quite selectively in the flow system through the H-ZSM-5 catalyzed
column. Products obtained then analyzed using Nuclear Magnetic Resonance (NMR)
Spectroscopy. |
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