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Evolution of a Manufacturing Route to Omarigliptin, A Long-Acting DPP‑4 Inhibitor for the Treatment of Type 2 Diabetes

Development of a convergent synthesis of omarigliptin (MK-3102) suitable for commercial manufacture is described. The target molecule is assembled through a diastereoselective reductive amination of a highly functionalized pyranone with a mesylated pyrazole followed by deprotection of a Boc group. T...

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Published in:Organic process research & development 2015-11, Vol.19 (11), p.1760-1768
Main Authors: Chung, John Y. L, Scott, Jeremy P, Anderson, Camille, Bishop, Brian, Bremeyer, Nadine, Cao, Yang, Chen, Qinghao, Dunn, Robert, Kassim, Amude, Lieberman, David, Moment, Aaron J, Sheen, Faye, Zacuto, Michael
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cited_by cdi_FETCH-LOGICAL-a388t-962e26dad643285474e75beb4b55f2ac669c15b4334ebb1129ba6c20189ed1133
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container_end_page 1768
container_issue 11
container_start_page 1760
container_title Organic process research & development
container_volume 19
creator Chung, John Y. L
Scott, Jeremy P
Anderson, Camille
Bishop, Brian
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Chen, Qinghao
Dunn, Robert
Kassim, Amude
Lieberman, David
Moment, Aaron J
Sheen, Faye
Zacuto, Michael
description Development of a convergent synthesis of omarigliptin (MK-3102) suitable for commercial manufacture is described. The target molecule is assembled through a diastereoselective reductive amination of a highly functionalized pyranone with a mesylated pyrazole followed by deprotection of a Boc group. The synthesis of the pyranone relies on three Ru-catalyzed reactions: (1) a DKR reduction of a rac-α-aminoketone to set the two contiguous stereogenic centers, (2) a cycloisomerization of a bis-homopropargylic alcohol to a dihydropyran, and, finally, (3) a Ru-catalyzed oxidation of a pyranol to the desired pyranone. The regioselective synthesis of a N-Boc-1-mesyl pyrazole fragment was achieved via base-promoted mesyl group isomerization to afford 30:1 selectivity. A highlight of the endgame process development is telescoping a Boc deprotection and reductive amination followed by direct crystallization of the penultimate from the reaction mixture. This avoids handling of an unstable, mutagenic 1-mesylpyrazole BSA salt used in the earlier multikilogram deliveries and improves the overall diastereoselectivity and efficiency of the route.
doi_str_mv 10.1021/acs.oprd.5b00267
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title Evolution of a Manufacturing Route to Omarigliptin, A Long-Acting DPP‑4 Inhibitor for the Treatment of Type 2 Diabetes
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