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Deoxyarbutin is an important intermediate in the synthesis of a variety of natural products, pharmaceuticals, and fine chemicals.
The natural sources of deoxyarbutin include the rhizomes of the Chinese herb Coptis chinensis and the southeastern Asian plant Pelsaurum triste.
However, the demand for deoxyarbutin often exceeds the availability of its natural sources, making it necessary to develop synthetic routes for its preparation.
The following are some of the synthetic routes that have been developed for the preparation of deoxyarbutin:
- The Strey-Bristol reaction
The Strey-Bristol reaction is a widely used method for the synthesis of deoxyarbutin.
This reaction involves the condensation of salicylic acid with tropinone in the presence of a Lewis acid catalyst, such as aluminum chloride or ferric chloride.
The reaction proceeds through a free-radical mechanism and results in the formation of a benzoxazepine ring.
This ring is then transformed into deoxyarbutin through a series of chemical reactions, including hydrolysis, reduction, and oxidation.
- The Robinson-Patel reaction
The Robinson-Patel reaction is another widely used method for the synthesis of deoxyarbutin.
This reaction involves the condensation of salicylaldehyde with phenyl-2-propanone in the presence of a base, such as sodium hydroxide.
The reaction proceeds through an imine intermediate and results in the formation of a β-hydroxyester, which is then reduced to produce deoxyarbutin.
- The Stork-Ellis reaction
The Stork-Ellis reaction is a variant of the Strey-Bristol reaction that uses a different catalyst and reaction conditions.
In this reaction, a mixture of salicylic acid and tropinone is heated with a molten salt, such as sodium hydroxide or potassium hydroxide, in the presence of a Lewis acid catalyst, such as aluminum chloride or ferric chloride.
The reaction proceeds through a free-radical mechanism and results in the formation of a benzoxazepine ring, which is then transformed into deoxyarbutin through a series of chemical reactions.
- The Mori-Pugnaloni reaction
The Mori-Pugnaloni reaction is a multistep synthetic route for the preparation of deoxyarbutin that involves several chemical reactions.
In this route, salicylic acid is first converted into a derivative known as 3,5-dimethoxy-4-hydroxybenzaldehyde through a series of chemical reactions.
This derivative is then converted into deoxyarbutin through a series of chemical reactions, including hydrolysis, reduction, and oxidation.
Advantages and disadvantages of synthetic routes
Each of the synthetic routes for the preparation of deoxyarbutin has its own advantages and disadvantages.
The Strey-Bristol reaction is one of the most widely used methods for the synthesis of deoxyarbutin, but it requires the use of Lewis acid catalysts, which can be hazardous and difficult to handle.
The Robinson-Patel reaction is a simpler and more cost-effective method, but it requires the use of strong bases, which can be corrosive and dangerous to handle.
The Stork-Ellis reaction and the Mori-Pugnaloni reaction are more complex and multistep synthetic routes, but they offer greater flexibility and are less hazardous to handle.
The Stork-Ellis reaction uses a molten salt as a catalyst, which can be easier to handle than Lewis acid catalysts, and the Mori-Pugnaloni reaction involves fewer steps and requires fewer dangerous chemicals.
Conclusion
Deoxyarbutin is an important
