Explorations in synthetic ion channel research: metal-ligand self-assembly and dissipative assembly

dc.contributor.authorDambenieks, Andrew Krisjanis
dc.contributor.supervisorFyles, Thomas M.
dc.date.accessioned2013-04-18T22:38:24Z
dc.date.available2013-04-18T22:38:24Z
dc.date.copyright2013en_US
dc.date.issued2013-04-18
dc.degree.departmentDept. of Chemistryen_US
dc.degree.levelDoctor of Philosophy Ph.D.en_US
dc.description.abstractThis thesis explores fundamental design strategies in the field of synthetic ion channel research from two different perspectives. In the first part the synthesis of complex, shape persistent and thermodynamically stable structures based on metal-ligand self-assembly is explored. The second part examines transport systems with dynamic transport behavior in response to chemical inputs which more closely mimic the dissipative assembly of Natural ion channels. In part one, two model systems, the ethylenediamine palladium(II) - 4,4’-bipyridine squares of Fujita and the trimeric bis(terpyridine) - iron(II) hexagonal macrocycles of Newkome, were targeted for structural modification towards becoming transport competent systems via improving the membrane partitioning characteristics of the final coordination compounds by increasing their lipophilicity. Modifications of the Fujita system involved the generation of two lipophilic 4,4’-bipyridines with addition of lipophilic groups of 13 and 17 carbon long alkyl chains respectively at the 3 and 3’ positions. After pursuing multiple unsuccessful synthetic routes the successful syntheses afforded the final lipophilic 4,4’-bipyridines in overall yields of 19 to 21% over two synthetic steps. Mixtures of the newly generated lipophilic 4,4’-bipyridines with a known lipophilic ethylenediamine palladium(II) “corner” exhibited evidence of self-assembly from NMR spectroscopy experiments however attempts at further characterization by ESI-MS and X-ray crystallography were unproductive. The putative self-assembled structures were inactive in HPTS vesicle assays but showed erratic conductance activity in bilayer clamp experiments. However, the magnitude of the conductance observed was not indicative of the passage of ions through the internal pore of the square complex. Modifications to the Newkome hexagons were aimed at generating overall neutral assemblies with external lipophilic groups. These modifications involved imparting a net -2 charge to the ligand via modifications to the terminal tridentate ligands so that upon coordination to octahedral metal centers in the +2 oxidation state the overall hexagonal complex would be neutrally charged. Two bis-polydentate ligands were generated; a dissymmetric molecule comprising one terpyridine and one dipicolinate tridentate ligand (TERPY-DPA) and a symmetrical molecule comprising two 2,2’-bipyridine-6-carboxylate tridentate ligands (BIPYA-BIPYA). The successful syntheses provided the desired trimethylsilylethyl ester protected compounds in yields of 9.2 and 7.5 % over 6 and 8 total synthetic steps for TERPY-DPA and BIPYA-BIPYA respectively. A new approach to metal-ligand complex formation by concomitant fluoride deprotection and assembly was demonstrated with a monomeric complex. Polymetallic complexes formed with a variety of transition metals based on colorimetric changes but the products were very intractable and resisted full structural or transport characterization. Part two develops a system potentially capable of exhibiting dissipative assembly of active transporters. A library of six thioester containing compounds structurally related to known active oligoester compounds was synthesized. The successful syntheses provided the desired compounds in overall yields of 1.0 to 17.7% over 11 to 13 total synthetic steps. The intramolecular cyclization - truncation and thioester exchange reactions central to the dissipative assembly strategy were explored using a model compound. The full length compounds showed transport activity via the HPTS vesicle assay that was significantly below that of the lead compound. Bilayer clamp experiments however, revealed significant transport activity for both the full length as well as the truncated thiol molecules. In the case of the latter the transport events had exceedingly high conductivity for such a small molecule. This unexpected activity for both the full length and truncated compounds, although different, prevented a full implementation of dissipative assembly of transport.en_US
dc.description.proquestcode0490en_US
dc.description.proquestcode0485en_US
dc.description.proquestcode0494en_US
dc.description.scholarlevelGraduateen_US
dc.identifier.urihttp://hdl.handle.net/1828/4531
dc.languageEnglisheng
dc.language.isoenen_US
dc.rights.tempAvailable to the World Wide Weben_US
dc.subjectSelf-Assemblyen_US
dc.subjectMetal-Liganden_US
dc.subjectDissipativeen_US
dc.subjectSynthetic Ion Channelsen_US
dc.titleExplorations in synthetic ion channel research: metal-ligand self-assembly and dissipative assemblyen_US
dc.typeThesisen_US

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