Reactivity of Polyynes: Complex Molecules from Simple Carbon Rods

Pigulski, Bartłomiej; Gulia, Nurbey; Szafert, Sławomir

doi:10.1002/ejoc.201801350

Cited by 27 publications

(14 citation statements)

References 186 publications

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“…Metal alkynyl complexes have been an attractive target for both synthetic and material chemists since the pioneering work of Nast and subsequent development in polymerization by Hagihara . Exploration of novel alkynyl complexes based on transition metals has remained topical as evidenced by many comprehensive reviews that have appeared during the ensuing decades. − Both the extended conjugation and structural rigidity of metal-oligoynes render them appealing candidates for opto-electronic materials, − molecular wires, − and active species for molecular devices. − It is noteworthy that many of the efforts mentioned above have been based on 4 d and 5 d metals such as Ru, Re, Ir, and Pt, which are rare and precious metals. To transform these interesting properties and functions into technological applications, surrogates based on earth abundant elements are desired.…”

Section: Introductionmentioning

confidence: 99%

A Series of Mono- and Bis-Alkynyl Co(III) Complexes Supported by a Tetra-imine Macrocyclic Ligand (TIM)

et al. 2021

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Reported herein is the synthesis and characterization of a series of monoand bis-alkynyl Co III (TIM) complexes, where TIM is 2,3,9,10-tetramethyl-1,4,8,11tetraazacyclotetradeca-1,3,8,10-tetraene. The trans-[Co(TIM)(C 2 Ar)Cl] + type complexes (Ar = phenyl (Ph, 1a), naphthalene (Np, 1b), and -C 6 F 5 (1c)) were prepared by the addition of HC 2 Ar to trans-[Co(TIM)Cl 2 ]PF 6 in the presence of Et 3 N. Treatment of the mono-alkynyl complexes with AgOTf in MeCN resulted in the trans-[Co(TIM)(C 2 Ar)-(NCMe)](OTf) 2 complexes (Ar = Ph (2a), Np (2b), and -C 6 F 5 (2c)). Complexes 2a and 2b react with the respective HC 2 Ar ligand in the presence of Et 3 N to afford the symmetrical bis-alkynyl complexes trans-[Co(TIM)(C 2 Ar) 2 ] + (Ar = Ph (3a) and Np (3b)). trans-[Co(TIM)(C 2 C 6 F 5 ) 2 ] + (3c) was obtained directly from the prolonged reaction of trans-[Co(TIM)Cl 2 ]PF 6 with HC 2 C 6 F 5 . Furthermore, the addition of HC 2 Ph to 2c in the presence of a weak base yielded the unsymmetrical bis-alkynyl complex trans-[Co(TIM)(C 2 C 6 F 5 )(C 2 Ph)]OTf (4). Molecular structures of complexes 1a/b, 2a/b, [3a]PF 6 , 3b, and 4 were established through single crystal X-ray diffraction. The absorption spectra for 1−4 display d−d bands between 380 and 470 nm. Complexes 1b−3b exhibited Np-based fluorescence. Electrochemical studies revealed that all complexes display an irreversible reduction characteristic of the Co III center, as well as up to two irreversible reduction(s) localized on the TIM macrocycle.

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Section: Introductionmentioning

confidence: 99%

A Series of Mono- and Bis-Alkynyl Co(III) Complexes Supported by a Tetra-imine Macrocyclic Ligand (TIM)

et al. 2021

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“…Moreover, the Au@LCCs 2.6:1 showed a significantly higher anti-inflammatory activity than the 1:1 dispersion ( Figure 10 ). Although not well characterized and understood at the cellular and molecular level, the biological activity of Au NPs has been reported by several authors [ 74 ], conversely, there is no evidence of potential bioproperties of inorganic graphene-derived LCCs [ 75 ]. So the observed anti-inflammatory effects need to be ascribed to Au NPs contained in the hybrid Au@LCC colloid.…”

Section: Resultsmentioning

confidence: 99%

Nano-Hybrid Au@LCCs Systems Displaying Anti-Inflammatory Activity

et al. 2022

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Gold nanoparticles (Au NPs) have received great attention owing to their biocompatible nature, environmental, and widespread biomedical applications. Au NPs are known as capable to regulate inflammatory responses in several tissues and organs; interestingly, lower toxicity in conjunction with anti-inflammatory effects was reported to occur with Au NPs treatment. Several variables drive this benefit-risk balance, including Au NPs physicochemical properties such as their morphology, surface chemistry, and charge. In our research we prepared hybrid Au@LCC nanocolloids by the Pulsed Laser Ablation, which emerged as a suitable chemically clean technique to produce ligand-free or functionalized nanomaterials, with tight control on their properties (product purity, crystal structure selectivity, particle size distribution). Here, for the first time to our knowledge, we have investigated the bioproperties of Au@LCCs. When tested in vitro on intestinal epithelial cells exposed to TNF-α, Au@LCCs sample at the ratio of 2.6:1 showed a significantly reduced TNF gene expression and induced antioxidant heme oxygenase-1 gene expression better than the 1:1 dispersion. Although deeper investigations are needed, these findings indicate that the functionalization with LCCs allows a better interaction of Au NPs with targets involved in the cell redox status and inflammatory signaling.

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“…They are also used intensively as building blocks for materials and in supramolecular chemistry . Investigations of the stability of polyynes reveal that the reactivity regarding their dimerization and decomposition increases with growing chain length . Therefore, it is necessary for the synthesis of higher polyynes to attach large, sterically demanding end‐capping groups in order to prevent decomposition of the polyyne .…”

Section: Methodsmentioning

confidence: 99%

“…The energy,w hich is necessary to bend the acetylenic chain, decreases with the increasing number of acetylene units. [4] Therefore, it is necessary for the synthesis of higherp olyynest oa ttach large, sterically demanding end-capping groups in order to preventd ecomposition of the polyyne. However,t here is still no possibility to measure the extent of the nonlinearity in solution.…”

mentioning

confidence: 99%

“…[1] They are also used intensively as building blocks for materials and in supramolecular chemistry. [4] Therefore, it is necessary for the synthesis of higherp olyynest oa ttach large, sterically demanding end-capping groups in order to preventd ecomposition of the polyyne. [4] Therefore, it is necessary for the synthesis of higherp olyynest oa ttach large, sterically demanding end-capping groups in order to preventd ecomposition of the polyyne.…”

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confidence: 99%

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Linear Relationship between ¹³C NMR Chemical Shifts and the Bending of sp‐Carbon Chains

Kreuzahler

Adam

Haberhauer

2019

Chemistry A European J

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Polyynes show as trictly linear relationship between the energy impact and the bending of the polyyne chain. The energy,w hich is necessary to bend the acetylenic chain, decreases with the increasing number of acetylene units. Ad eviation from linearity in polyynes can be realizedi ns olution by violation of the mutual-exclusion principle betweenI Ra nd Raman spectra. However,t here is still no possibility to measure the extent of the nonlinearity in solution. Herein, we show that the 13 CNMR spectroscopy represents an appropriate tool for this as we found an almost perfect linear relationship between the bendingo ft he alkyne chain and the change of the chemical shift of the outer acetylenic carbon atoms. By using molecular bows in which the alkyne chain can be bent by switching the azobenzene unit, this correlation can be proved experimentally.I nt he future, this correlation should enablet he determination of the extent of the bendinga nd the strain energyi np olyynes. Consequently, polyynes could be employed as probesf or measuring further molecular forces.Polyynes consisting of alternate single and triple bonds can be found in interstellar space, in plants,m ushrooms,a nd in marine organisms. [1] They are also used intensively as building blocks for materials and in supramolecular chemistry. [2] Investigationso ft he stabilityo fp olyynes revealt hat the reactivity regardingt heir dimerization [3] and decomposition increases with growingc hain length. [4] Therefore, it is necessary for the synthesis of higherp olyynest oa ttach large, sterically demanding end-capping groups in order to preventd ecomposition of the polyyne. [5] Using this strategy the synthesis and isolationo fa polyyne with 22 conjugatedt riple bonds wasachieved. [6] With increasing number of acetylene units, the energy of the bending vibration along the molecular axis decreases and, therefore, ad eviation from the linearityo ft he molecular struc-

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Reactivity of Polyynes: Complex Molecules from Simple Carbon Rods

Cited by 27 publications

References 186 publications

A Series of Mono- and Bis-Alkynyl Co(III) Complexes Supported by a Tetra-imine Macrocyclic Ligand (TIM)

A Series of Mono- and Bis-Alkynyl Co(III) Complexes Supported by a Tetra-imine Macrocyclic Ligand (TIM)

Nano-Hybrid Au@LCCs Systems Displaying Anti-Inflammatory Activity

Linear Relationship between ¹³C NMR Chemical Shifts and the Bending of sp‐Carbon Chains

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Reactivity of Polyynes: Complex Molecules from Simple Carbon Rods

Cited by 27 publications

References 186 publications

A Series of Mono- and Bis-Alkynyl Co(III) Complexes Supported by a Tetra-imine Macrocyclic Ligand (TIM)

A Series of Mono- and Bis-Alkynyl Co(III) Complexes Supported by a Tetra-imine Macrocyclic Ligand (TIM)

Nano-Hybrid Au@LCCs Systems Displaying Anti-Inflammatory Activity

Linear Relationship between 13C NMR Chemical Shifts and the Bending of sp‐Carbon Chains

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Linear Relationship between ¹³C NMR Chemical Shifts and the Bending of sp‐Carbon Chains