Cation induced changes to the structure of cryptophane cages

Oscar H. Lloyd Williams; Claudia S. Cox; Meng Yuan Zhang; Martina Lessio; Olivia Rusli; William A. Donald; Lachlan Jekimovs; David L. Marshall; Michael C. Pfrunder; Berwyck L. J. Poad; Thierry Brotin; Nicole J. Rijs

doi:10.1039/d4dt01824a

Cation induced changes to the structure of cryptophane cages

Oscar H. Lloyd Williams, Claudia S. Cox, Meng Yuan Zhang, Martina Lessio, Olivia Rusli, William A. Donald, Lachlan Jekimovs, David L. Marshall, Michael C. Pfrunder, Berwyck L. J. Poad, Thierry Brotin, Nicole J. Rijs

Research output: Contribution to Journal › Article › Academic › peer-review

Abstract

Here the monocation complexes of seven anti-cryptophanes are examined with high-resolution ion-mobility mass spectrometry. The relative size of the [cation + cryptophane]+ complexes were compared based on their measured mobilities and derived collisional cross sections. A paradoxical trend of structural contraction was observed for complexes of increasing cation size. Density functional theory confirmed encapsulation occurs for cation = Na+, K+, Rb+, Cs+ and NH4+. However, cation = Li+ preferred oxygen coordination at a linker over encapsulation within the cavity, leading to a slightly larger gas phase structure overall. Protonated cryptophanes yielded much larger collision cross sections via imploded cryptophane structures. Thus, competing physical effects led to the observed non-periodic size trend of the complexes. Trends in complexation from isothermal titration calorimetry and other condensed phase techniques were borne out by the gas phase studies. Further, predicted cavity sizes compared with the gas phase experimental findings reveal more about the encapsulation mechanisms themselves.

Original language	English
Pages (from-to)	18473-18483
Journal	Dalton Transactions
Volume	53
Issue number	46
DOIs	https://doi.org/10.1039/d4dt01824a
Publication status	Published - 26 Sept 2024
Externally published	Yes

Funding

We acknowledge: the Australian Research Council via grants DE170100677 and LE220100031; subsidized access to the Bioanalytical Mass Spectrometry Facility within the Mark Wainwright Analytical Centre of the University of New South Wales; the Queensland University of Technology, Central Analytical Research Facility (CARF, QUT); both the UNSW Resource Allocation Scheme and Katana managed by Research Technology Services at UNSW Sydney, with the assistance of resources and services from the National Computational Infrastructure (NCI, gy60, bb55), which is supported by the Australian Government. Preliminary work was carried out with the support of the Karlsruhe Nano Micro Facility (KNMF, https://www.knmf.kit.edu), a Helmholtz Research Infrastructure at Karlsruhe Institute of Technology. Finally, we thank Jessica Holmes, Felix Rizzuto, Tyren Dodgen, Niklas Geue, Perdita Barran, and Terry Frankcombe for helpful discussions.

Funders	Funder number
Australian Government
Queensland University of Technology
National Computational Infrastructure
Bioanalytical Mass Spectrometry Facility
Central Analytical Research Facility
University of New South Wales
Australian Research Council	DE170100677, LE220100031

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title = "Cation induced changes to the structure of cryptophane cages",

abstract = "Here the monocation complexes of seven anti-cryptophanes are examined with high-resolution ion-mobility mass spectrometry. The relative size of the [cation + cryptophane]+ complexes were compared based on their measured mobilities and derived collisional cross sections. A paradoxical trend of structural contraction was observed for complexes of increasing cation size. Density functional theory confirmed encapsulation occurs for cation = Na+, K+, Rb+, Cs+ and NH4+. However, cation = Li+ preferred oxygen coordination at a linker over encapsulation within the cavity, leading to a slightly larger gas phase structure overall. Protonated cryptophanes yielded much larger collision cross sections via imploded cryptophane structures. Thus, competing physical effects led to the observed non-periodic size trend of the complexes. Trends in complexation from isothermal titration calorimetry and other condensed phase techniques were borne out by the gas phase studies. Further, predicted cavity sizes compared with the gas phase experimental findings reveal more about the encapsulation mechanisms themselves.",

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AU - Cox, Claudia S.

AU - Zhang, Meng Yuan

AU - Lessio, Martina

AU - Rusli, Olivia

AU - Donald, William A.

AU - Jekimovs, Lachlan

AU - Marshall, David L.

AU - Pfrunder, Michael C.

AU - Poad, Berwyck L. J.

AU - Brotin, Thierry

AU - Rijs, Nicole J.

PY - 2024/9/26

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N2 - Here the monocation complexes of seven anti-cryptophanes are examined with high-resolution ion-mobility mass spectrometry. The relative size of the [cation + cryptophane]+ complexes were compared based on their measured mobilities and derived collisional cross sections. A paradoxical trend of structural contraction was observed for complexes of increasing cation size. Density functional theory confirmed encapsulation occurs for cation = Na+, K+, Rb+, Cs+ and NH4+. However, cation = Li+ preferred oxygen coordination at a linker over encapsulation within the cavity, leading to a slightly larger gas phase structure overall. Protonated cryptophanes yielded much larger collision cross sections via imploded cryptophane structures. Thus, competing physical effects led to the observed non-periodic size trend of the complexes. Trends in complexation from isothermal titration calorimetry and other condensed phase techniques were borne out by the gas phase studies. Further, predicted cavity sizes compared with the gas phase experimental findings reveal more about the encapsulation mechanisms themselves.

AB - Here the monocation complexes of seven anti-cryptophanes are examined with high-resolution ion-mobility mass spectrometry. The relative size of the [cation + cryptophane]+ complexes were compared based on their measured mobilities and derived collisional cross sections. A paradoxical trend of structural contraction was observed for complexes of increasing cation size. Density functional theory confirmed encapsulation occurs for cation = Na+, K+, Rb+, Cs+ and NH4+. However, cation = Li+ preferred oxygen coordination at a linker over encapsulation within the cavity, leading to a slightly larger gas phase structure overall. Protonated cryptophanes yielded much larger collision cross sections via imploded cryptophane structures. Thus, competing physical effects led to the observed non-periodic size trend of the complexes. Trends in complexation from isothermal titration calorimetry and other condensed phase techniques were borne out by the gas phase studies. Further, predicted cavity sizes compared with the gas phase experimental findings reveal more about the encapsulation mechanisms themselves.

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Cation induced changes to the structure of cryptophane cages

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