Draft:Supramolecular Coordination Complexes
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Comment: Maybe notable, but another editor would need to look, thank you Ozzie10aaaa (talk) 16:12, 10 May 2025 (UTC)
Supramolecular coordination complexes (SCCs) are discrete self-assembled constructs formed through highly directional and stoichiometric metal-ligand coordination bonds.[1] They are also referred to as coordination-driven self-assemblies[2] and belong to the class of supramolecular structures called metal-organic complexes (MOC). Transition metal ions serve as Lewis-acceptor units with preferred coordination geometries, and labile or rigid ligands serve as Lewis-donor molecules that spontaneously assemble with specific directionality, leading to different types of well-defined geometries. The different coordination-driven discrete topological architecture of SCCs is categorized as two-dimensional (2D) metallacycles and three-dimensional (3D) metallacages. SCCs allow design flexibility with precision through careful selection of the structure of metal and ligand components, along with the coordination angle to obtain a range of sizes, shapes, and topologies with different physicochemical properties. Among metallacycles triangles, rectangles, hexagons, trigonal prisms, hexagonal prisms, rhomboids, and cubes, design geometries have been reported. Whereas in 3D systems, trigonal pyramids, trigonal prisms, truncated and snub cubes, truncated tetrahedra, cuboctahedra, double squares, adamantanoids, dodecahedra are among the variety of cage geometries reported.[1][3][4] Several design strategies or approaches have been identified and studied for the synthesis of metallacycles and metallacages, and are summarized in several reviews on SCCs.[4]
Distinctive features and uses
[edit]The distinctive feature of the SCCs is imparted by the predictable nature of metal-ligand coordination spheres and moderate bond strength, allowing dynamic flexibility or reversibility of weak non-covalent bonds and relative stability or rigidity of stronger covalent bonds, which dictate the coordination kinetics of the self-assembly process.[4][5] The metal-ligand bonds have energies of (15-50 kcal/mol)[4][6]compared to organic covalent bonds (approx. 60-120 kcal/mol) and the weak interactions (ca. 0.5 10 kcal/mol). The feature of kinetic reversibility due to substitutional lability of metal-ligand bonds and reactive intermediates endows the coordination-driven self-assembled architectures ability to "self-correct" to the most thermodynamically favorable product.[2][4] In simpler words, transition metals have their preferred geometry (of acceptor sites), so if a rigid or flexible donor ligand coordinates in an improper orientation, the thermodynamically favored structure or closed geometry is not formed (kinetic intermediates are formed). Then the metal-ligand bonds can dissociate and reassociate "correctly" to transform into the target thermodynamic product. To ensure SCCs are free from kinetic impurities, the synthetic conditions for self-assembly must allow easy reconstruction of reactive intermediates (avoid precipitation, insolubility, or sluggishness in rectifying) en route to the energetically minimum product.[2]
Supramolecular structures assembled through covalent bonds are hard to design procedurally, requiring step-wise addition, time-consuming to synthesize, and suffer from fairly low yields.[3][7] Moderate metal-ligand bonds with carefully selected components offer greater designability and control over such synthetic self-assembly. Likewise, SCCs also overcome several challenges of supramolecular structures formed through the collection of weak non-covalent forces (H-bonding, ion-ion or ion-dipole, donor acceptor, π-π stacking, van der Waals, and hydrophilic and hydrophobic, etc., interactions) like the absence of stability to avoid disassembly in multiple environments, the absence of defect-free final structures, and the lack of directionality control to make highly complex, symmetrical or specific well-defined architectures.[4][8][9] SCCs provide convenient, quantitative, and precise discrete structures ranging from only a few nm to several thousand cubic mm, afforded by a bottom-up synthesis strategy tunable for different applications.[10] Such advantages of SCCs were recognized, reported, and popularized by researchers like Lehn[11], Raymond[12], Stang[13], Fujita[14], Nitschke, and several others.[4] Among several SCC applications explored are use as molecular flasks or reaction vessels for unusual chemistries unachievable in conventional mediums, use for molecular or guest recognition, supramolecular catalysis, separation, host-guest chemistry, cavity-dictated reactions, drug delivery, diagnostic and therapeutic agents, sensing, stimuli-responsive properties, and several other applications.[1][5][6][9][15][16][17][18][19][20]
References
[edit]- ^ a b c Yin, Changfeng; Du, Jiaxing; Olenyuk, Bogdan; Stang, Peter; Sun, Yan (2023-01-22). "The Applications of Metallacycles and Metallacages". Inorganics. 11 (2): 54. doi:10.3390/inorganics11020054. ISSN 2304-6740.
- ^ a b c Cook, Timothy R.; Zheng, Yao-Rong; Stang, Peter J. (2013-01-09). "Metal–Organic Frameworks and Self-Assembled Supramolecular Coordination Complexes: Comparing and Contrasting the Design, Synthesis, and Functionality of Metal–Organic Materials". Chemical Reviews. 113 (1): 734–777. doi:10.1021/cr3002824. ISSN 0009-2665. PMC 3764682. PMID 23121121.
- ^ a b Seidel, S. Russell; Stang, Peter J. (2002-11-01). "High-Symmetry Coordination Cages via Self-Assembly". Accounts of Chemical Research. 35 (11): 972–983. doi:10.1021/ar010142d. ISSN 0001-4842. PMID 12437322.
- ^ a b c d e f g Chakrabarty, Rajesh; Mukherjee, Partha Sarathi; Stang, Peter J. (2011-11-09). "Supramolecular Coordination: Self-Assembly of Finite Two- and Three-Dimensional Ensembles". Chemical Reviews. 111 (11): 6810–6918. doi:10.1021/cr200077m. ISSN 0009-2665. PMC 3212633. PMID 21863792.
- ^ a b Xu, Dongdong; Li, Yang; Yin, Shouchun; Huang, Feihe (2024). "Strategies to address key challenges of metallacycle/metallacage-based supramolecular coordination complexes in biomedical applications". Chemical Society Reviews. 53 (6): 3167–3204. doi:10.1039/D3CS00926B. ISSN 0306-0012. PMID 38385584.
- ^ a b Zhang, Ruoqian; Li, Rongrong; Huang, Feihe; Zhang, Mingming (2023). "Metallacycle/metallacage-cored supramolecular networks". Progress in Polymer Science. 141: 101680. doi:10.1016/j.progpolymsci.2023.101680.
- ^ Hu, Yi-Xiong; Zhang, Xiangyi; Xu, Lin; Yang, Hai-Bo (2019). "Coordination-Driven Self-Assembly of Functionalized Supramolecular Metallacycles: Highlighted Research during 2010–2018". Israel Journal of Chemistry. 59 (3–4): 184–196. doi:10.1002/ijch.201800102. ISSN 0021-2148.
- ^ Cook, Timothy R.; Stang, Peter J. (2015-08-12). "Recent Developments in the Preparation and Chemistry of Metallacycles and Metallacages via Coordination". Chemical Reviews. 115 (15): 7001–7045. doi:10.1021/cr5005666. ISSN 0009-2665. PMID 25813093.
- ^ a b Yoshizawa, Michito; Fujita, Makoto (2010-06-15). "Development of Unique Chemical Phenomena within Nanometer-Sized, Self-Assembled Coordination Hosts". Bulletin of the Chemical Society of Japan. 83 (6): 609–618. doi:10.1246/bcsj.20100035. ISSN 0009-2673.
- ^ Fujita, Daishi; Ueda, Yoshihiro; Sato, Sota; Mizuno, Nobuhiro; Kumasaka, Takashi; Fujita, Makoto (2016). "Self-assembly of tetravalent Goldberg polyhedra from 144 small components". Nature. 540 (7634): 563–566. Bibcode:2016Natur.540..563F. doi:10.1038/nature20771. ISSN 0028-0836. PMID 30905932.
- ^ Lehn, Jean Marie (1978-02-01). "Cryptates: the chemistry of macropolycyclic inclusion complexes". Accounts of Chemical Research. 11 (2): 49–57. doi:10.1021/ar50122a001. ISSN 0001-4842.
- ^ Caulder, Dana L.; Brückner, Christian; Powers, Ryan E.; König, Stefan; Parac, Tatjana N.; Leary, Julie A.; Raymond, Kenneth N. (2001-09-01). "Design, Formation and Properties of Tetrahedral M 4 L 4 and M 4 L 6 Supramolecular Clusters 1". Journal of the American Chemical Society. 123 (37): 8923–8938. Bibcode:2001JAChS.123.8923C. doi:10.1021/ja0104507. ISSN 0002-7863. PMID 11552799.
- ^ Stang, Peter J.; Olenyuk, Bogdan (1997-12-01). "Self-Assembly, Symmetry, and Molecular Architecture: Coordination as the Motif in the Rational Design of Supramolecular Metallacyclic Polygons and Polyhedra". Accounts of Chemical Research. 30 (12): 502–518. doi:10.1021/ar9602011. ISSN 0001-4842.
- ^ Fujita, Makato (2000), Fuiita, Makoto (ed.), "Molecular Paneling Through Metal-Directed Self-Assembly", Molecular Self-Assembly Organic Versus Inorganic Approaches, Structure and Bonding, vol. 96, Berlin, Heidelberg: Springer Berlin Heidelberg, pp. 177–201, doi:10.1007/3-540-46591-x_6, ISBN 978-3-540-66948-7, retrieved 2025-05-10
- ^ Xu, Jiating; Wang, Jun; Ye, Jin; Jiao, Jiao; Liu, Zhiguo; Zhao, Chunjian; Li, Bin; Fu, Yujie (2021). "Metal-Coordinated Supramolecular Self-Assemblies for Cancer Theranostics". Advanced Science. 8 (16): e2101101. doi:10.1002/advs.202101101. ISSN 2198-3844. PMC 8373122. PMID 34145984.
- ^ Li, Rongrong; Zhang, Haixin; Hou, Yali; Gao, Lingyan; Chu, Dake; Zhang, Mingming (2025-03-19). "Metallacage-crosslinked free-standing supramolecular networks via photo-induced copolymerization for photocatalytic water decontamination". Nature Communications. 16 (1): 2733. Bibcode:2025NatCo..16.2733L. doi:10.1038/s41467-025-57822-6. ISSN 2041-1723. PMC 11923137. PMID 40108122.
- ^ Jing, Xu; He, Cheng; Yang, Yang; Duan, Chunying (2015-03-25). "A Metal–Organic Tetrahedron as a Redox Vehicle to Encapsulate Organic Dyes for Photocatalytic Proton Reduction". Journal of the American Chemical Society. 137 (11): 3967–3974. Bibcode:2015JAChS.137.3967J. doi:10.1021/jacs.5b00832. ISSN 0002-7863. PMID 25738748.
- ^ Yu, Guocan; Jiang, Meijuan; Huang, Feihe; Chen, Xiaoyuan (2021). "Supramolecular coordination complexes as diagnostic and therapeutic agents". Current Opinion in Chemical Biology. 61: 19–31. doi:10.1016/j.cbpa.2020.08.007. PMC 8062580. PMID 33147551.
- ^ Lewis, James E. M.; Gavey, Emma L.; Cameron, Scott A.; Crowley, James D. (2012). "Stimuli-responsive Pd 2 L 4 metallosupramolecular cages: towards targeted cisplatin drug delivery". Chem. Sci. 3 (3): 778–784. doi:10.1039/C2SC00899H. ISSN 2041-6520.
- ^ Maurizot, Victor; Yoshizawa, Michito; Kawano, Masaki; Fujita, Makoto (2006). "Control of molecular interactions by the hollow of coordination cages". Dalton Transactions (23): 2750–2756. doi:10.1039/b516548m. ISSN 1477-9226. PMID 16751882.