Crystal engineering rescues a solution organic synthesis in a cocrystallization that confirms the configuration of a molecular ladder
Author(s) -
Manza B. J. Atkinson,
S. V. Santhana Mariappan,
Dejan-Krešimir Buč̌ar,
Jonas Baltrušaitis,
Tomislav Friščić,
Naif Sinada,
Leonard R. MacGillivray
Publication year - 2011
Publication title -
proceedings of the national academy of sciences
Language(s) - English
Resource type - Journals
eISSN - 1091-6490
pISSN - 0027-8424
DOI - 10.1073/pnas.1104352108
Subject(s) - diastereomer , isomerization , chemistry , crystallography , molecule , crystallization , nuclear magnetic resonance spectroscopy , stereochemistry , cis–trans isomerism , absolute configuration , crystal structure , organic chemistry , catalysis
Treatment of an achiral molecular ladder of C2h symmetry composed of five edge-sharing cyclobutane rings, or a [5]-ladderane, with acid results incis - totrans -isomerization of end pyridyl groups. Solution NMR spectroscopy and quantum chemical calculations support the isomerization to generate two diastereomers. The NMR data, however, could not lead to unambiguous configurational assignments of the two isomers. Single-crystal X-ray diffraction was employed to determine each configuration. One isomer readily crystallized as a pure form and X-ray diffraction revealed the molecule as being achiral based on Ci symmetry. The second isomer resisted crystallization under a variety of conditions. Consequently, a strategy based on a cocrystallization was developed to generate single crystals of the second isomer. Cocrystallization of the isomer with a carboxylic acid readily afforded single crystals that confirmed a chiral ladderane based on C2 symmetry. The chiral ladderane and acid self-assembled to generate a five-component hydrogen-bonded complex that packs to form large solvent-filled homochiral channels of nanometer-scale dimensions. Whereas cocrystallizations are frequently applied to structure determinations of proteins, our study represents the first application of a cocrystallization to confirm the relative configuration of a small-molecule diastereomer generated in a solution-phase organic synthesis.
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