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Synlett 2019; 30(14): 1632-1642
DOI: 10.1055/s-0037-1611866
DOI: 10.1055/s-0037-1611866
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Evolution of a Chemical Strategy Toward the Synthesis of Unsymmetrically Oxidized Nuphar Alkaloids
This work was supported by the National Institutes of Health (NIH) – National Institute of General Medical Sciences (NIGMS R01, Grant No. 077379). J.J.L. was supported by a UCSB Chancellor’s Fellowship. Funding for the UCSB MRL Mass Spectrometry Facility was provided by the MRSEC Program of the National Science Foundation (NSF, under award NSF DMR 1121053).Further Information
Publication History
Received: 29 April 2019
Accepted after revision: 21 May 2019
Publication Date:
27 June 2019 (online)
Abstract
Here we describe the frustrations, joys, and unexpected turns experienced in our journey toward a successful strategy directed at the total synthesis of unsymmetrically oxidized Nuphar thioalkaloids. While many adjustments were made to our initial synthesis plan, our general approach to the construction of the central bis(spirothiolane) moiety remained unchanged. Specifically, each iteration of our synthesis design involved the formation of the thiaspirane motif through the stereodivergent coupling of a thietane with a metal carbenoid, followed by a Stevens-type rearrangement of the resulting sulfonium ylide.
1 Introduction
2 First-Generation Strategy
3 Second-Generation Strategy
4 Third-Generation Strategy
5 Conclusion
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Initial isolation of monomeric Nuphar alkaloids was first reported in 1962:
The isolation of the dimeric alkaloids was reported later in 1964, see:
For structural characterization studies on the nuphar alkaloids, see
For explorations into the antibiotic and anti-inflammatory activity of the Nuphar alkaloids, see:
For additional synthetic studies on monomeric Nuphar alkaloids after 2013, see:
Sulfur has been shown to poison RCM reactions in other examples, see:
For selected examples of metal-catalyzed allene aminations to form vinyl piperidines, see:
For a review on the formation of rhodium and copper carbenoids, see:
For selected examples of the use of the catalysts see in Scheme [9] in metal-carbenoid chemistry, see:
The thiaspirane stereochemistry of compounds 59a, C7-epi-59a, C7-epi-59b and the corresponding deallyloxycarbonylated compounds 60a, C7-epi-60a, and C7-epi-60b was never determined. We were only able to determine the stereochemistry of 59b after Alloc removal, cyclization, and reduction to (–)-thionuphlutine (2c) through comparison to literature data. See:
For selected examples of ester reductions with i-Bu2AlH to form hemiaminals, see:
Once again, the thiaspirane stereochemistry in compounds 68a, 68b, 61a, and 62b was determined following conversion to the natural products 1b, 1c, 2b, and 2c through comparison to literature spectral and optical rotation data. See: