Evolution of a Green and Sustainable Manufacturing Process for Belzutifan: Part 6─Development of a Nucleophilic Aromatic Substitution in Water

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An improved synthesis has been developed for belzutifan, a novel HIF-2α inhibitor for the treatment of Von Hippel− Lindau (VHL) disease-associated renal cell carcinoma (RCC). The efficiency of previous supply and commercial routes was encumbered by a lengthy 5-step sequence, needed to install a chiral benzylic alcohol by traditional methods. Identification and directed evolution of FoPip4H, an iron/α-ketoglutarate dependent hydroxylase, enabled a direct enantioselective C−H hydroxylation of a simple indanone starting material. While this enabling transformation set the stage for a greatly improved synthesis, several other key innovations were made including the development of a base-metal-catalyzed sulfonylation, a KREDcatalyzed dynamic kinetic resolution, and a facile S N Ar reaction in water. Together, these improvements resulted in a significantly shorter synthesis (9 steps) versus the supply route (16 steps) and a 75% reduction in process mass intensity (PMI), while also removing the reliance on third-row transition metals and toxic solvents.

Section: Results and Discussionmentioning

confidence: 99%

Evolution of a Green and Sustainable Manufacturing Process for Belzutifan: Part 1─Process History and Development Strategy

DiRocco,

Zhong,

et al. 2024

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“…The current commercial process successfully met the aggressive program timelines; however, opportunities to improve the manufacturing route led to the development of an improved commercial process that is more concise, efficient, and atom economical . The electrophilic fluorination/dynamic kinetic resolution (DKR) sequence that sets two of three stereocenters was viewed as a strategic sequence to form the syn -1,2-fluoroalcohol substructure, and this disconnection was retained in the improved commercial process (Figure ).…”

Section: Introductionmentioning

confidence: 99%

Evolution of a Green and Sustainable Manufacturing Process for Belzutifan: Part 5─Chemoenzymatic Diastereoselective Fluorination/DKR

McCann,

Dubina,

Kosjek

et al. 2024

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A ketone fluorination/reduction dynamic kinetic resolution (DKR) was developed for a third-generation synthesis of belzutifan. This new process replaced a precious metal catalyst with a ketoreductase (KRED) in the DKR. Achieving this one-pot reaction required several rounds of enzyme evolution that improved enzyme stability in the presence of acetonitrile and methanol. To maintain development progress and satisfy program timelines, process development around the reaction, workup, and isolation operations was performed in parallel with the enzyme evolution and required ongoing modification, as new variants were made available. Additionally, opportunities for improvements to product quality and process robustness were identified by resolving issues observed in piloting experiments.

“…Thus, belzutifan ( 3 ) represents a breakthrough treatment for those who suffer or will suffer from this disease. We acquired the compound from Peloton Therapeutics in 2019, whereupon a campaign to establish a manufacturing route was initiated . As part of that effort, the preparation of sulfone 2 from aryl bromide 1 was explored (Scheme ).…”

Section: Introductionmentioning

confidence: 99%

Evolution of a Green and Sustainable Manufacturing Process for Belzutifan: Part 2─Development of a Scalable Nickel-Catalyzed Sulfonylation

Hethcox,

Kim,

Johnson

et al. 2024

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A nickel-catalyzed sulfonylation reaction was discovered and developed into a robust process for the manufacturing of belzutifan, an FDA-approved treatment for Von Hippel-Lindau disease-associated renal cell carcinoma. The reaction proceeds via a nickel-catalyzed reductive sulfinylation reaction utilizing two insoluble salts (potassium metabisulfite and potassium formate), followed by methylation with a nontoxic methylating reagent (trimethylphosphate). The doubly heterogeneous nature of the reaction proved difficult to scale due to mixing and particle size issues. Controlled addition of a solution of potassium formate in ethylene glycol was found to mitigate all scaling issues, and mechanistic studies revealed this to be due to control of the catalyst speciation. The reaction was demonstrated on a multikilogram scale with robust kinetics between scales. Reaction discovery, process development, multikilogram-scale demonstration, and mechanistic insights are detailed within.