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Synlett 2013; 24(3): 305-312
DOI: 10.1055/s-0032-1317540
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© Georg Thieme Verlag Stuttgart · New York

Evolution of the Process for the Preparation of a Selective ErbB VEGF Receptor Inhibitor

Boguslaw Mudryk*
,
Amit Joshi*
,
Adrian Ortiz
,
Ian S. Young
,
James R. Sawyer
,
Bin Zheng
,
Masano Sugiyama
,
Zhongping Shi
,
Jale Müslehiddinoğlu
,
R. Michael Corbett
,
David R. Kronenthal
,
David A. Conlon
Further Information

Publication History

Received: 01 October 2012

Accepted: 17 October 2012

Publication Date:
23 November 2012 (online)

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Abstract

An efficient synthetic route to the potent and selective ErbB VEGF receptor inhibitor, BMS-690514 (1) is described. Strategic modifications in both approach and procedure addressed several issues, which led to a safe, efficient, and economical process for the preparation of multi-kilogram quantities of 1. The convergent route involves alkylation of a suitably protected (3R,4R)-4-aminopiperidin-3-ol with the triethyl(alkyl)ammonium salt of a functionalized pyrrolotriazine 3a followed by deprotection to provide 1 as the crystalline free base.

Key words

antitumor agents - protected piperidines - protecting groups - heterocycles - Schiff bases

Supporting Information

    for this article is available online at http://www.thieme-connect.com/ejournals/toc/synlett.
  • Supporting Information
 

  • References and Notes

  • 1 New address: Celgene Corp., Basking Ridge, NJ, USA.
  • 2 New address: Dupont, Newark, DE, USA.

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  • 8 Use of NMP produced approximately 1 LCAP of the Friedel–Crafts-derived impurity. As a comparison, CH2Cl2, which was the worst performer, produced ca. 12 LCAP of the impurity.
  • 9 The structure of 8 was proposed based on LCMS data. Specifically, the C–N connectivity cannot be confirmed.
  • 10 Loss of acetonitrile and triethylamine, which form a low-boiling azeotrope (b.p. 55 °C), was attributed to the nitrogen sweep used to ensure efficient inertion and prevent formation of colored impurities. This issue was resolved during development runs by using a nitrogen blanket, and was not observed in the pilot plant batches.
  • 11 Carbon treatment after formation of 5 resulted in ca. 5% Boc deprotection even at r.t. and, as a result, the carbon treatment should be implemented during processing of 6 if required.
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  • 15 In general, impurities (organic, residual solvents, or inorganic) do not add any therapeutic value, may present toxicity concerns and are therefore controlled to very low levels in the active pharmaceutical ingredient.
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  • 17 From a procedural perspective, it was noted that this impurity continued to form after the reaction reached its endpoint. As a result, we utilized an internal Raman probe, rather than HPLC after a set amount of time. This allowed us to stop the reaction when it was complete, minimizing additional conversion of 1 into 12.
  • 18 It should be noted that we set a more stringent requirement of 250 ppm m-anisidine in isolated 6 (see above) to ensure that safe levels of this impurity would be present in the drug substance.
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    • 19c First generation: 7 steps, 3 isolations, 26 operations, 22% overall yield. Second generation: 5 steps, 2 isolations, 10 operations, 29% overall yield resulting in 60% reduction in cost. Number of steps refers to number of intermediates that could be isolated.
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  • 22 First generation: three steps, 62% yield, three N-alkyl impurities. Second generation: two steps, 67% yield, no N-alkyl impurities. Number of steps refers to number of intermediates that could be isolated.