Improved Synthetic Route to Dexamethasone Acetate from Tigogenin

Ohta, Tetsuo; Zhang, Huyue; Torihara, and Yoshitaka; Furukawa, Isao

doi:10.1021/op9700338

Cited by 16 publications

(9 citation statements)

References 14 publications

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“…Introduction of ketone at C‐3 position was done by the oxidation of C‐3 OH by the treatment of calcium hypochlorite to produce 4.6. In the next step, dibromination was carried out at C‐2 and C‐4 positions by using Br 2 /AcOH in the mixture of dioxane‐AcOH as solvent to produce 4.7, which was then treated with DMF containing 6 % water for dehydrobromination reaction to introduce two double bonds in ring A (4.8) [133] . Next, hydrolysis of C‐21 acetyl group by NaOH and subsequent hydroxylation at C‐11 in presence of a fungi Peslalotia foedans produced 4.9.…”

Section: Drug Developmentmentioning

confidence: 99%

“…[132] In the year 1997 Furukawa et al improved few steps of the existing synthetic routes to obtain Dexamethasone acetate with higher yield. [133] The synthesis starts from tigogenin, (4.1) (Scheme 8) which undergoes ring opening in the presence of acetic acid at 200°C, followed by oxidation with chromic acid and elimination by application of heat to form 4.2. [132] Then 4.2 was treated with CH 3 MgCl/CuCl for the introduction of methyl moiety at C-16 and further epoxidation was done using peracid followed by alkaline hydrolysis to produce 4.3.…”

Section: Dexamethasonementioning

confidence: 99%

“…In the next step, dibromination was carried out at C-2 and C-4 positions by using Br 2 /AcOH in the mixture of dioxane-AcOH as solvent to produce 4.7, which was then treated with DMF containing 6 % water for dehydrobromination reaction to introduce two double bonds in ring A (4.8). [133] Next, hydrolysis of C-21 acetyl group by NaOH and subsequent hydroxylation at C-11 in presence of a fungi Peslalotia foedans produced 4.9. Further, a double bond was incorporated in the C-ring (between C-9 and C-11) by the treatment with sodium acetate to produce 4.10.…”

Section: Dexamethasonementioning

confidence: 99%

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COVID‐19 into Chemical Science Perspective: Chemical Preventive Measures and Drug Development

Adhikari

Sahu

2021

ChemistrySelect

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COVID‐19 facts and literature are discussed into chemical science intuition highlighting the direct role of chemistry to the ongoing global pandemic by covering structural identification of the virus, chemical preventive measures and development of drugs. We reviewed the four most promising repurposed drugs which are presently being investigated in mass clinical trials on COVID‐19 infected persons and synthetic routes of these drugs with their recent advancement. Chemical preventive measures such as soap water, hand sanitizer and disinfectant are the only available options in the arsenal to fight against COVID‐19, till an effective medicine or vaccine will be made available. As such the present review will focus on the mode of action of the major chemical preventives.

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Section: Drug Developmentmentioning

confidence: 99%

Section: Dexamethasonementioning

confidence: 99%

Section: Dexamethasonementioning

confidence: 99%

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COVID‐19 into Chemical Science Perspective: Chemical Preventive Measures and Drug Development

Adhikari

Sahu

2021

ChemistrySelect

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“…The longer route developed by Merck via the more expensive bovine bile acids was no longer an attractive approach. In the six decades since the first publication of the Schering route to dexamethasone, improvements to the route have been made using more modern chemistry and a different order of steps. In a review of industrial syntheses of corticosteroids in 2017, Herraiz described a 14-step manufacturing route to dexamethasone from 80 (Scheme ), available from 76 in four steps via Marker degradation (Scheme ).…”

Section: Dexamethasonementioning

confidence: 99%

Quest for a Cure: Potential Small-Molecule Treatments for COVID-19, Part 2

Hughes¹

2021

Org. Process Res. Dev.

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During the first year of the outbreak of the COVID-19 pandemic, many drugs and drug candidates have been evaluated as treatment options. None yet has proved to be an effective cure, but progress in controlling the disease has been made. In June 2020 we published an article that described the mechanistic rationale behind the repurposing of seven licensed drugs in clinical trials for the treatment of COVID-19 and reviewed synthetic routes to these drugs. Several developments have occurred since then. Remdesivir (trade name Veklury) has been approved for use in the U.S. and Europe. Dexamethasone, a steroid drug first approved in 1959, has shown mortality reduction in severe COVID patients. Molnupiravir, a new and promising oral antiviral drug, is being studied in late-stage clinical trials. In this review, we update synthetic work that has been recently published on remdesivir, provide an overview of several routes to molnupiravir, and review classical routes to dexamethasone as well as some of those more recently developed.

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“…The oxidation of alcohol to ketone is one of the most important reactions in organic chemistry. Various oxidation methods have been reported, including Jones oxidation, Swern oxidation, Dess−Martin oxidation, Oppeneure oxidation, TEMPO oxidation, , Ca(OCl) 2 with acetic acid, and TPAP oxidation . However, oxidation is not often used in large-scale manufacturing because of inherent safety concerns and waste of byproducts .…”

Section: Introductionmentioning

confidence: 99%

Practical Application of Oxidation Using a Novel Na₂WO₄−H₂O₂ System under Neutral Conditions for Scale-Up Manufacturing of 12α-Hydroxy-3-oxooleanano-28,13-lactone: Key Intermediate of Endothelin A Receptor Antagonist S-0139

Hida

Fukui

Kawata

et al. 2009

Org. Process Res. Dev.

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Novel alcohol oxidation using a Na2WO4−H2O2 system was applied to manufacture 12α-hydroxy-3-oxooleanano-28,13-lactone which is a key intermediate of S-0139. Oxidation of the hydroxyl group of oleanolic acid was optimized based on the design of experiment (DoE) approach. Statistical analysis was used to maximize the yield of the corresponding ketone and minimize the generation of byproducts. The safety evaluation of this oxidation was also conducted in detail, and pilot manufacturing was achieved.

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Improved Synthetic Route to Dexamethasone Acetate from Tigogenin

Cited by 16 publications

References 14 publications

COVID‐19 into Chemical Science Perspective: Chemical Preventive Measures and Drug Development

COVID‐19 into Chemical Science Perspective: Chemical Preventive Measures and Drug Development

Quest for a Cure: Potential Small-Molecule Treatments for COVID-19, Part 2

Practical Application of Oxidation Using a Novel Na₂WO₄−H₂O₂ System under Neutral Conditions for Scale-Up Manufacturing of 12α-Hydroxy-3-oxooleanano-28,13-lactone: Key Intermediate of Endothelin A Receptor Antagonist S-0139

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Improved Synthetic Route to Dexamethasone Acetate from Tigogenin

Cited by 16 publications

References 14 publications

COVID‐19 into Chemical Science Perspective: Chemical Preventive Measures and Drug Development

COVID‐19 into Chemical Science Perspective: Chemical Preventive Measures and Drug Development

Quest for a Cure: Potential Small-Molecule Treatments for COVID-19, Part 2

Practical Application of Oxidation Using a Novel Na2WO4−H2O2 System under Neutral Conditions for Scale-Up Manufacturing of 12α-Hydroxy-3-oxooleanano-28,13-lactone: Key Intermediate of Endothelin A Receptor Antagonist S-0139

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Practical Application of Oxidation Using a Novel Na₂WO₄−H₂O₂ System under Neutral Conditions for Scale-Up Manufacturing of 12α-Hydroxy-3-oxooleanano-28,13-lactone: Key Intermediate of Endothelin A Receptor Antagonist S-0139