Countereation transport modeled by porous spherical molybdenum oxide based nanocapsules

Rehder D, Haupt ETK, Bögge H, Müller A (2006)
CHEMISTRY-AN ASIAN JOURNAL 1(1-2): 76-81.

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Zeitschriftenaufsatz | Veröffentlicht | Englisch
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Abstract / Bemerkung
Porous nanosized polyoxomolybdate capsule anions of composition [{Mo-VI((Mo5O21)-O-VI)(H2O)(6)}(12) (linker)(30)](n-), where (linker)(30) is {(Mo2O4)-O-V(SO4)}(30) (n = 72) (1a) or ((Mo2O4)-O-V(SO4)}(24)((Mo2O4)-O-v(CH3COO)}(6) (n=64) (2a), model the (competitive) cellular transmembrane transport of Li+, Na+, K+, and Ca2+ ions along ion channels. According to X-ray crystallography and Li-7 and Na-23 NMR spectroscopy, Li+ and Na+, the counterions for 1a and 2a, respectively, occupy internal sites of the capsule. This study of the counterion transport phenomenon shows that, while Li+ ions can be replaced to a large extent by Na+ and K+ ions and completely by Ca2+ ions added to a solution of 1a, external Li+ ions do not replace the incorporated Na+ ions of 2a in an analogous experiment. In this context, related properties of the capsules and especially of their flexible channels, in connection with the complex pathways of cation uptake, are discussed briefly. The relevance of these investigations for lithium-based therapies is also addressed.
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CHEMISTRY-AN ASIAN JOURNAL
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1
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1-2
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76-81
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Rehder D, Haupt ETK, Bögge H, Müller A. Countereation transport modeled by porous spherical molybdenum oxide based nanocapsules. CHEMISTRY-AN ASIAN JOURNAL. 2006;1(1-2):76-81.
Rehder, D., Haupt, E. T. K., Bögge, H., & Müller, A. (2006). Countereation transport modeled by porous spherical molybdenum oxide based nanocapsules. CHEMISTRY-AN ASIAN JOURNAL, 1(1-2), 76-81. doi:10.1002/asia.200600035
Rehder, D., Haupt, E. T. K., Bögge, H., and Müller, A. (2006). Countereation transport modeled by porous spherical molybdenum oxide based nanocapsules. CHEMISTRY-AN ASIAN JOURNAL 1, 76-81.
Rehder, D., et al., 2006. Countereation transport modeled by porous spherical molybdenum oxide based nanocapsules. CHEMISTRY-AN ASIAN JOURNAL, 1(1-2), p 76-81.
D. Rehder, et al., “Countereation transport modeled by porous spherical molybdenum oxide based nanocapsules”, CHEMISTRY-AN ASIAN JOURNAL, vol. 1, 2006, pp. 76-81.
Rehder, D., Haupt, E.T.K., Bögge, H., Müller, A.: Countereation transport modeled by porous spherical molybdenum oxide based nanocapsules. CHEMISTRY-AN ASIAN JOURNAL. 1, 76-81 (2006).
Rehder, Dieter, Haupt, Erhard T. K., Bögge, Hartmut, and Müller, Achim. “Countereation transport modeled by porous spherical molybdenum oxide based nanocapsules”. CHEMISTRY-AN ASIAN JOURNAL 1.1-2 (2006): 76-81.

9 Zitationen in Europe PMC

Daten bereitgestellt von Europe PubMed Central.

Guests on different internal capsule sites exchange with each other and with the outside.
Petina O, Rehder D, Haupt ET, Grego A, Weinstock IA, Merca A, Bögge H, Szakács J, Müller A., Angew Chem Int Ed Engl 50(2), 2011
PMID: 21132826
Hydrophobic interactions and clustering in a porous capsule: option to remove hydrophobic materials from water.
Schäffer C, Todea AM, Bögge H, Petina OA, Rehder D, Haupt ET, Müller A., Chemistry 17(35), 2011
PMID: 21748814
Unprecedented replacement of bridging oxygen atoms in polyoxometalates with organic imido ligands.
Hao J, Xia Y, Wang L, Ruhlmann L, Zhu Y, Li Q, Yin P, Wei Y, Guo H., Angew Chem Int Ed Engl 47(14), 2008
PMID: 18297664
Confinement and step-wise reopening of channels in an artificial cell/inorganic capsule: a 7Li NMR study.
Haupt ET, Wontorra C, Rehder D, Merca A, Müller A., Chemistry 14(29), 2008
PMID: 18773407
Towards biological supramolecular chemistry: a variety of pocket-templated, individual metal oxide cluster nucleations in the cavity of a mo/w-storage protein.
Schemberg J, Schneider K, Demmer U, Warkentin E, Müller A, Ermler U., Angew Chem Int Ed Engl 46(14), 2007
PMID: 17304608
Reactions inside a porous nanocapsule/artificial cell: encapsulates' structuring directed by internal surface deprotonations.
Müller A, Toma L, Bögge H, Henry M, Haupt ET, Mix A, Sousa FL., Chem Commun (Camb) (32), 2006
PMID: 16896473

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