David A. Siler scite author profile

A Robinson annulation, van Leusen homologation, and a desymmetrizing C–H oxidation enabled an enantiospecific synthesis of the neurotrophic natural product jiadifenolide. From a pulegone-derived building block, a key propellane intermediate was constructed through the use of simple reagents in a highly diastereoselective fashion. A short series of oxidations of this tricylic framework allowed progression to the natural product.

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Factors Affecting Protein–Glycan Specificity: Effect of Spacers and Incubation Time

Lewallen

Siler

Iyer

2009

ChemBioChem

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Glycan binding: We monitored the binding of synthetic glycans to influenza hemagglutinin by using ELISA and surface plasmon resonance, thereby demonstrating that the glycan's presentation influences binding dramatically. Also, the binding observed in static systems was very different from that in dynamic fluid systems. These studies suggest that binding specificities are dependent on glycan structure, valency, presentation, and assay conditions.magnified image

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Synthesis of Rovafovir Etalafenamide (Part I): Active Pharmaceutical Ingredient Process Development, Scale-Up, and Impurity Control Strategy

Standley

Bringley

Çalimsiz³

et al. 2021

Org. Process Res. Dev.

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This manuscript describes the chemical process development and multi-kilogram synthesis of rovafovir etalafenamide (GS-9131), a phosphonamidate prodrug nucleotide reverse transcriptase inhibitor under investigation for the treatment of HIV-1 infection. Rovafovir etalafenamide is assembled in a four-step sequence beginning from the nucleoside core and an elaborated phosphonamidate alcohol. The assembly starts with a decarboxylative elimination of a β-hydroxyacid to yield the corresponding cyclic enol ether, which is subsequently coupled to a functionalized phosphonamidate alcohol in an iodoetherification reaction. Oxidative syn elimination then installs the required fluoroalkene, after which a final deprotection reaction yields the active pharmaceutical ingredient (API). Understanding the genesis, fate, and purge of the des-fluoro analog of the API, a mitochondrial toxin, proved to be a central driver in the development of the manufacturing route and impurity control strategy. Initial control strategies revolved around the use of silica gel chromatography or simulated moving bed chromatography to purge the des-fluoro impurity to an acceptable level, but ultimately a chromatography-free approach to mitigate the formation of this impurity was devised that expanded manufacturing flexibility. Design of experiments was used to improve the iodoetherification fragment coupling reaction and to reduce the level of the des-fluoro impurity formed in this step. Furthermore, several new crystalline intermediate forms were discovered and implemented as isolation points to bolster the overall impurity control strategy for standard, diastereomeric, and potentially mutagenic impurities as well as for the des-fluoro impurity. These processes were executed on multikilogram scale to produce API for clinical studies.

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Synthesis of Rovafovir Etalafenamide (Part IV): Evolution of the Synthetic Process to the Fluorinated Nucleoside Fragment

Siler

Çalimsiz²,

Doxsee

et al. 2021

Org. Process Res. Dev.

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Fluorinated nucleoside 1 is a key starting material in the synthesis of rovafovir etalafenamide (2), a novel nucleotide reverse transcriptase inhibitor under development at Gilead Sciences for the treatment of HIV. While an initial manufacturing route enabled the production of 1 to support clinical development, alternative approaches were explored to further enhance manufacturing effectiveness, improve processing time, reduce cost, and minimize the environmental impact. Toward this end, two new routes were developed to a key synthetic intermediate, which was converted to 1 using a new protecting group strategy. The new chemistry led to improvements in the manufacturing process while reducing the overall process mass intensity (PMI).

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An Enantiospecific Synthesis of Jiadifenolide

2014

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A Robinson annulation, van Leusen homologation, and a desymmetrizing C-H oxidation enabled an enantiospecific synthesis of the neurotrophic natural product jiadifenolide. From a pulegonederived building block, a key propellane intermediate was constructed through the use of simple reagents in a highly diastereoselective fashion. A short series of oxidations of this tricylic framework allowed progression to the natural product.

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David A. Siler

An Enantiospecific Synthesis of Jiadifenolide

Factors Affecting Protein–Glycan Specificity: Effect of Spacers and Incubation Time

Synthesis of Rovafovir Etalafenamide (Part I): Active Pharmaceutical Ingredient Process Development, Scale-Up, and Impurity Control Strategy

Synthesis of Rovafovir Etalafenamide (Part IV): Evolution of the Synthetic Process to the Fluorinated Nucleoside Fragment

An Enantiospecific Synthesis of Jiadifenolide

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