Aryl fluorides are widely used in the pharmaceutical and agrochemical industries, and recent advances have enabled their synthesis through the conversion of various functional groups. However, there is a lack of general methods for direct aromatic carbon-hydrogen (C-H) fluorination. Conventional methods require the use of either strong fluorinating reagents, which are often unselective and difficult to handle, such as elemental fluorine, or less reactive reagents that attack only the most activated arenes, which reduces the substrate scope. A method for the direct fluorination of aromatic C-H bonds could facilitate access to fluorinated derivatives of functional molecules that would otherwise be difficult to produce. For example, drug candidates with improved properties, such as increased metabolic stability or better blood-brain-barrier penetration, may become available. Here we describe an approach to catalysis and the resulting development of an undirected, palladium-catalysed method for aromatic C-H fluorination using mild electrophilic fluorinating reagents. The reaction involves a mode of catalysis that is unusual in aromatic C-H functionalization because no organometallic intermediate is formed; instead, a reactive transition-metal-fluoride electrophile is generated catalytically for the fluorination of arenes that do not otherwise react with mild fluorinating reagents. The scope and functional-group tolerance of this reaction could provide access to functional fluorinated molecules in pharmaceutical and agrochemical development that would otherwise not be readily accessible.
A new method to rapidly generate pyrrolidines via a SOMO-activated enantioselective (3 + 2) coupling of aldehydes and conjugated olefins has been accomplished. A radical-polar crossover mechanism is proposed wherein olefin addition to a transient enamine radical cation and oxidation of the resulting radical furnishes a cationic intermediate which is vulnerable to nucleophilic addition of a tethered amine group. A range of olefins, including styrenes and dienes, are shown to provide stereochemically complex pyrrolidine products with high chemical efficiency and enantiocontrol.
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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