Oxidative decarboxylation of tris-(p-carboxyltetrathiaaryl)methyl radical EPR probes by peroxidases and related hemeproteins: Intermediate formation and characterization of the corresponding cations

Tris(p-carboxyltetrathiaaryl)methyl radicals (TAM) are good EPR probes for measurement of dioxygen concentration in biological systems and for EPR imaging. It has been previously reported that these radicals are efficiently oxidized by superoxide, O₂⁻, or alkylperoxyl radicals, ROO, and by liver microsomes via an oxidative decarboxylation mechanism leading to the corresponding quinone-methides (QM). This article shows that peroxidases, such as horseradish peroxidase (HRP), lactoperoxidase (LPO) and prostaglandin synthase (PGHS), and other hemeproteins, such as methemoglobin (metHb), metmyoglobin (metMb) and catalase, also efficiently catalyze the oxidation of TAM radicals to QM by H₂O₂ or alkylhydroperoxides. These reactions involve the intermediate formation of the corresponding cations TAM⁺ that have also been cleanly generated by K₂Ir(IV)Cl₆ and characterized by UV-Visible spectroscopy and mass spectrometry, and through their reactions with ascorbate or H₂O₂. Labelling experiments on HRP-catalyzed oxidation of TAM to QM using H₂¹⁸O or ¹⁸O₂ in the presence of glucose and glucose oxidase (GOX) showed that the oxygen atom incorporated into QM came both from O₂ and from H₂O. Mechanisms for these reactions in agreement with those data were proposed. Oxidative decarboxylation of TAM to QM is a new reaction catalyzed by peroxidases. Such reactions should be considered when using TAM as EPR oximetry probes invivo or in vitro in complex biological media.     

Non-aromatic stabilised form of 3,4-difluoropyrrole at triosmium clusters: N-H and C-H versus C-F activation

Reaction of 3,4-difluoropyrrole with the labile triosmium cluster [Os₃(CO)₁₀(CH₃CN)₂] affords products in which C-H, N-H and C-F bonds are cleaved under mild conditions. C-H and N-H bonds are cleaved to give [Os₃H(NCCFCFCH₂)(CO)₁₀] (1) a non-aromatic stabilised form of 3,4-difluoropyrrole. Thermolysis of 1 affords in moderate yields the compounds [Os₃H₂(CCCFCHNH)(CO)₉] (2) and [Os₃H₂(NCHCFCFC)(CO)₉] (3). For compound 3, C-H and N-H bonds are cleaved with concomitant migration of H atoms to the metal framework. In contrast, for compound 2 activation of C-H and C-F bonds leads to coordination of the ligand through the carbon atoms, acting as a four-electron donating species.     

The formation of peroxynitrite in the applied physiology of mitochondrial nitric oxide

Mitochondria require nitric oxide (NO) to exert a delicate control of metabolic rate as well as to regulate life functions, cell cycle activation and arrest, and apoptosis. All activities depend on the matrical NO steady state concentration as provided by mitochondrial (mtNOS) and cytosolic sources (eNOS) and reduced by forming superoxide anion and H₂O₂ and a low peroxynirite (ONOO⁻) yield. We review herein the biochemical pathways involved in the control of NO mitochondrial level and its biological and physiological significance in hormone effects and aging. At high NO, the cost of this physiological regulation is that ONOO⁻ excess will lead to nitrosation/nitration and oxidization of mitochondrial and cell proteins and lipids. The disruption of NO modulation of mitochondrial respiration supports then, a platform for prevalent neurodegenerative and metabolic diseases.     

Reaction of N-hydroxyguanidine with the ferrous-oxy state of a heme peroxidase cavity mutant: A model for the reactions of nitric oxide synthase

Yeast cytochrome c peroxidase was used to construct a model for the reactions catalyzed by the second cycle of nitric oxide synthase. The R48A/W191F mutant introduced a binding site for N-hydroxyguanidine near the distal heme face and removed the redox active Trp-191 radical site. Both the R48A and R48A/W191F mutants catalyzed the H₂O₂ dependent conversion of N-hydroxyguanidine to N-nitrosoguanidine. It is proposed that these reactions proceed by direct one-electron oxidation of NHG by the Fe⁺⁴O center of either Compound I (Fe⁺⁴O, porph⁺) or Compound ES (Fe⁺⁴O, Trp⁺). R48A/W191F formed a Fe⁺²O₂ complex upon photolysis of Fe⁺²CO in the presence of O₂, and N-hydroxyguanidine was observed to react with this species to produce products, distinct from N-nitrosoguanidine, that gave a positive Griess reaction for nitrate + nitrite, a positive Berthelot reaction for urea, and no evidence for formation of NO. It is proposed that HNO and urea are produced in analogy with reactions of nitric oxide synthase in the pterin-free state.     

H2O2 and (.)NO scavenging by Mycobacterium leprae truncated hemoglobin O

Kinetics of ferric Mycobacterium leprae truncated hemoglobin O (trHbOFe(III)) oxidation by H₂O₂ and of trHbOFe(IV)O reduction by NO and NO₂⁻ are reported. The value of the second-order rate constant for H₂O₂-mediated oxidation of trHbOFe(III) is 2.4 × 10³ M⁻¹ s⁻¹. The value of the second-order rate constant for NO-mediated reduction of trHbOFe(IV)O is 7.8 × 10⁶ M⁻¹ s⁻¹. The value of the first-order rate constant for trHbOFe(III)ONO decay to the resting form trHbOFe(III) is 2.1 × 10¹ s⁻¹. The value of the second-order rate constant for NO₂⁻-mediated reduction of trHbOFe(IV)O is 3.1 × 10³ M⁻¹ s⁻¹. As a whole, trHbOFe(IV)O, generated upon reaction with H₂O₂, catalyzes NO reduction to NO₂⁻. In turn, NO and NO₂⁻ act as antioxidants of trHbOFe(IV)O, which could be responsible for the oxidative damage of the mycobacterium. Therefore, Mycobacterium leprae trHbO could be involved in both H₂O₂ and NO scavenging, protecting from nitrosative and oxidative stress, and sustaining mycobacterial respiration.     

Acrolein toxicity: Comparison with reactive oxygen species

The toxicity of acrolein was compared with that of reactive oxygen species using a mouse mammary carcinoma FM3A cell culture system. Complete inhibition of cell growth was accomplished with 10 μM acrolein, 100 μM H₂O₂, and 20 μM H₂O₂ plus 1 mM vitamin C, which produce OH, suggesting that toxicity of acrolein is more severe than H₂O₂ and nearly equal to that of OH, when these compounds were added extracellularly. Acrolein toxicity was prevented by N-acetyl-l-cysteine and N-benzylhydroxylamine, and attenuated by putrescine and spermidine. Toxicity of H₂O₂ was prevented by glutathione peroxidase plus N-acetyl-l-cysteine, pyruvate, catalase, and reduced by polyphenol, and toxicity of OH was prevented by glutathione peroxidase plus N-acetyl-l-cysteine, pyruvate, catalase and reduced by N-acetyl-l-cysteine. The results indicate that prevention of cell toxicity by N-acetyl-l-cysteine was more effective with acrolein than with OH. Protein and DNA synthesis was damaged primarily by acrolein and reactive oxygen species, respectively.     

Organometallic π-tweezers incorporating pyrazine- and pyridine-based bridging units

Pyrazine- and pyridine-based π-conjugated σ-donor molecules, such as 4,4′-bipyridine, 1,2-di(4-pyridyl)ethylene, 3,5-dipyridyl-1,2,4-triazole, N,N′-bis(4-pyridylmethylidene)benzene-1,4-diamine, 2,5-di(pyridylmethylidene)cyclopentanone, 2,6-di(4-pyridylmethylidene)cyclohexanone (LL, 2a-2g) can successfully be used to span heterobimetallic π-tweezer units of the type [{[Ti](μ-σ,π-CCSiMe₃)₂}M]⁺ ([Ti] = (η⁵-C₅H₄SiMe₃)₂Ti; M = Cu, Ag). The thus accessible di-cationic species [{[Ti](μ-σ,π-CCSiMe₃)₂}MLLM{(Me₃SiCC-μ-σ,π)₂[Ti]}]²⁺ (4), which are formed via the formation of [{[Ti](μ-σ,π-CCSiMe₃)₂}MLL]⁺ (3) complexes, can be isolated in yields between 66% and 99%.However, when C₅H₄NCHCHC₆H₄CHCHNC₅H₄ (5a) and C₅H₄NCHNC₆H₄CHCHNC₅H₄ (5b), respectively, are reacted with {[Ti](μ-σ,π-CCSiMe₃)₂}AgBF₄(1c) in a 1:1 molar ratio, then the silver(I) ion is released from the organometallic π-tweezer 1c and coordination polymers [AgBF₄ · 5a]_n (6a) and [AgBF₄ · 5b]_n (6b) along with [Ti](CCSiMe₃)₂ (7) are formed in quantitative yield.     

Reactivity of alkynyl Pd(II) azido complexes toward organic isocyanides, isothiocyanates, and nitriles

Alkynyl Pd(II) azido complexes of the type [Pd(N₃)(CCR)L₂] (1-3) were obtained by reactions of aqueous NaN₃ with [Pd(Cl)(CCR)L₂] (R = Ph or C(O)OMe). Treating compounds 1-3 with organic isocyanides (R-NC) afforded novel complexes, trans-[Pd(CCPh)(NCNR)(PMe₃)₂] (R = 2,6-Me₂C₆H₃ (4) or 2,6-Et₂C₆H₃ (5)) and trans-[Pd(CCR)(CN₄-t-Bu)L₂] (6: L = PMe₃, R = Ph; 7: L = PEt₃, R = C(O)OMe; 8: L = PMe₃, R = C(O)OMe), which contain either a carbodiimido or a C-coordinated tetrazolato group. Reactions of compounds 1 and 2 with R-NCS (R = 2,6-Me₂C₆H₃ or CH₂CH₃) and 1,4-phenylene diisothiocyanate (C₆H₄(NCS)₂) smoothly proceeded to give tetrazole-thiolato complexes, trans-[Pd(CCPh)(SCN₄-R)L₂] (L = PMe₃, R = Et (9) or 2,6-Me₂C₆H₃ (10); L = PEt₃, R = 2,6-Me₂C₆H₃ (11)), and a phenylene-bridged dinuclear Pd(II) tetrazole-thiolato complex, [(PEt₃)₂(CCPh)Pd(SCN₄-(μ-C₆H₄)-SCN₄)Pd(CCPh)(PEt₃)₂] (12), respectively. Complexes 9-12 contain the Pd-S bond that is formed by the dipolar cycloaddition of the organic isothiocyanate to the Pd-azido bond. In contrast, the corresponding reactions of compounds 1and 2 with C₆F₅CN and Me₃SiCN (organic nitriles, R-CN) gave an N-coordinated Pd(II)-tetrazolato compound {trans-[Pd(CCPh)(N₄C-C₆F₅)(PMe₃)₂] (13)} and a mixture of Pd(II)-cyano complexes {trans-[Pd(CCPh)(CN)(PEt₃)₂] (14) and [Pd(CN)₂(PEt₃)₂] (15)}, respectively. Bis(phosphine) bis(cyano) complexes of Pd and Ni, [M(CN)₂L₂] (L = PEt₃, PMe₃; L₂ = DEPE), could be obtained independently by the reactions of [M(N₃)₂L₂] with excess Me₃SiCN in organic solvents.     

Ruthenium hydride and vinyl complexes supported by nitrogen-oxygen mixed-donor ligands

The Schiff base, 2-chlorophenylsalicylaldimine (HL₁), is formed readily from salicylaldehyde and 2-chloroaniline. After deprotonation, this ligand is found to react as a bidentate mixed-donor chelate with the complexes [RuRCl(CO)(BTD)(PPh₃)₂] (R = H, CHCHC₆H₅, CHCHC₆H₄Me-4, CHCH^tBu, CCCPhCHPh; BTD = 2,1,3-benzothiadiazole) to form the compounds [RuR(L₁)(CO)(PPh₃)₂] through displacement of the chloride and BTD ligands. An analogous reaction occurs with the osmium complex [OsHCl(CO)(BTD)(PPh₃)₂] to provide [OsH(L₁)(CO)(PPh₃)₂]. The compound [Ru(CHCHC₆H₄Me-4)(L₂)(CO)(PPh₃)₂] is formed through reaction of salicylaldehyde (HL₂) with [Ru(CHCHC₆H₄Me-4)Cl(CO)(BTD)(PPh₃)₂] in the presence of base. Two further ligands were investigated to extend the study to encompass 5- and 4-membered chelates; 8-hydroxyquinoline (HL₃) and 2-hydroxy-4-methylquinoline (HL₄) react with [Ru(CHCHPh)Cl(CO)(BTD)(PPh₃)₂] and [Ru(CHCHC₆H₄Me-4)Cl(CO)(BTD)(PPh₃)₂] in the presence of base to yield the complexes [Ru(CHCHPh)(L₃)(CO)(PPh₃)₂] and [Ru(CHCHC₆H₄Me-4)(L₄)(CO)(PPh₃)₂], respectively. The crystal structure of [Ru(CHCHC₆H₄Me-4)(L₁)(CO)(PPh₃)₂] is reported.     

Alkoxy-substituted group 6 allenylidene complexes - Synthesis and properties

Bis(alkoxy)allenylidene complexes, [(CO)₅MCCC(OR′)OR], as well as mono(alkoxy)allenylidene complexes, [(CO)₅MCCC(OR′)Ph], of chromium and tungsten are accessible from propynones [HCCC(O)Ph] or propynoic acid esters [HCCC(O)OR; R = Et, (−)-menthyl, endo-bornyl] by the following reaction sequence: (a) deprotonation of the alkynes, (b) reaction with [(CO)₅M-THF] (M = Cr, W), and (c) alkylation of the resulting alkynyl metallate, [(CO)₅MCCC(O)R], with Meerwein salts. Vinylidene complexes, [(CO)₅MCC(R′)C(O)OR], are formed as a by-product by C_β-alkylation of the alkynyl metallate. Dimethylamine displaces one alkoxy substituent of the bis(alkoxy)allenylidene complexes to give dimethylamino(alkoxy)allenylidene complexes, [(CO)₅MCCC(OR)NMe₂]. The analogous reaction of dimethylamine with a mono(alkoxy)-substituted allenylidene complex affords the aminoallenylidene complex [(CO)₅CrCCC(NMe₂)Ph]. When the amine is used in large excess, the α,β-unsaturated aminocarbene complex [(CO)₅CrC(NMe₂)C(H)C(NMe₂)Ph] is additionally formed by addition of the amine across the C_αC_β-bond of the allenylidene ligand. The reaction of [(CO)₅MCCC(OEt)₂] with dimethyl ethylenediamine offers access to bis(amino)allenylidene complexes, in which C_γ is part of a five-membered heterocycle. Photolysis of bis(alkoxy)allenylidene complexes in the presence of triphenylphosphine yields tetracarbonyl- and tricarbonyl{bis(phosphine)}allenylidene complexes. Diethylaminopropyne inserts into the C_βC_γ bond of [(CO)₅MCCC(OEt)OMethyl] to give alkenylallenylidene complexes. Subsequent acid-catalyzed intramolecular cyclization affords a pyranylidene complex.     

Synthesis and reactivity of gold(III) complexes containing cycloaurated iminophosphorane ligands

Transmetallation reactions of ortho-mercurated iminophosphoranes (2-ClHgC₆H₄)Ph₂PNR with [AuCl₄]⁻ gives new cycloaurated iminophosphorane complexes of gold(III) (2-Cl₂AuC₆H₄)Ph₂PNR [R = (R,S)- or (S)-CHMePh, p-C₆H₄F, ^tBu], characterised by NMR and IR spectroscopies, ESI mass spectrometry and an X-ray structure determination on the chiral derivative R = (S)-CHMePh. The chloride ligands of these complexes can be readily replaced by the chelating ligands thiosalicylate and catecholate; the resulting derivatives show markedly higher anti-tumour activity versus P388 murine leukaemia cells compared to the parent chloride complexes. Reaction of (2-Cl₂AuC₆H₄)Ph₂PNPh with PPh₃ results in displacement of a chloride ligand giving the cationic complex [(2-Cl(PPh₃)AuC₆H₄)Ph₂PNPh]⁺, indicating that the PN donor is strongly bonded to the gold centre.     

Upstream reactive oxidative species (ROS) signals in exogenous oxidative stress-induced mitochondrial dysfunction

Exogenous oxidative stress induces cell death, but the upstream molecular mechanisms involved of the process remain relatively unknown. We determined the instant dynamic reactions of intracellular reactive oxygen species (ROS, including hydrogen peroxide (H₂O₂), superoxide radical (O₂⁻), and nitric oxide (NO)) in cells exposed to exogenous oxidative stress by using a confocal laser scanning microscope. Stimulation with extracellular H₂O₂ significantly increased the production of intracellular H₂O₂, O₂⁻, and NO (P < 0.01) through certain mechanisms. Increased levels of intracellular ROS resulted in mitochondrial dysfunction, involving the impairment of mitochondrial activity and the depolarization of mitochondrial membrane potential. Mitochondrial dysfunction significantly inhibited the proliferation of human hepatoblastoma G2 (HepG2) cells and resulted in mitochondrial cytochrome c (cyt c) release. The results indicate that upstream ROS signals play a potential role in exogenous oxidative stress-induced cell death through mitochondrial dysfunction and cyt c release.     

Oxidovanadium(IV) complexes containing ligands derived from dithiocarbazates - Models for the interaction of VO with thiofunctional ligands

The tetragonal-pyramidal VO²⁺ complexes [VO{(RSC-S)N-NX}₂] (1-6) were synthesised by the reactions of VO(OCHMe₂)₃ with the dithiocarbazate ligands RSC(S)-NH-NX, where X = cyclo-pentyl, cyclo-hexyl or 4-Me₂N-C₆H₄-CH, and R = CH₃ or CH₂C₆H₅. The compounds were characterised by elemental analysis, IR- and mass spectrometries, and in cases of compounds 1, 3, 4 and 5, by X-ray diffraction. The chiral compound 4 (X = cyclo-hexyl, R = CH₂C₆H₅) crystallises in the C configuration. In compound 5, the VO moiety is disordered (83.3:16.7%) with respect to the plane spanned by the four equatorial ligand functions.     

Synthesis and characterisation of isomeric cycloaurated complexes derived from the iminophosphorane Ph3PNC(O)Ph

Using different organomercury substrates, two isomeric cycloaurated complexes derived from the stabilised iminophosphorane Ph₃PNC(O)Ph were prepared. Reaction of Ph₃PNC(O)Ph with PhCH₂Mn(CO)₅ gave the manganated precursor (CO)₄Mn(2-C₆H₄C(O)NPPh₃), metallated on the C(O)Ph substituent, which yielded the organomercury complex ClHg(2-C₆H₄C(O)NPPh₃) by reaction with HgCl₂ in methanol. Transmetallation of the mercurated derivative with Me₄N[AuCl₄] gave the cycloaurated iminophosphorane AuCl₂(2-C₆H₄C(O)NPPh₃) with an exo PPh₃ substituent. The endo isomer AuCl₂(2-C₆H₄Ph₂PNC(O)Ph) [aurated on a PPh₃ ring] was obtained by an independent reaction sequence, involving reaction of the diarylmercury precursor Hg(2-C₆H₄P(NC(O)Ph)Ph₂)₂ [prepared from the known compound Hg(2-C₆H₄PPh₂)₂ and PhC(O)N₃] with Me₄N[AuCl₄]. Both of the isomeric iminophosphorane derivatives were structurally characterised, together with the precursors (2-HgClC₆H₄)C(O)NPPh₃ and (CO)₄Mn(2-C₆H₄C(O)NPPh₃). The utility of ³¹P NMR spectroscopy in monitoring reaction chemistry in this system is described.     

Ferrocenyl-substituted allenylidene complexes of chromium, molybdenum and tungsten: Synthesis, structure and reactivity

Bis(ferrocenyl)-substituted allenylidene complexes, [(CO)₅MCCCFc₂] (1a-c, Fc = (C₅H₄)Fe(C₅H₅), M = Cr (a), Mo (b), W (c)) were obtained by sequential reaction of Fc₂CO with Me₃Si-CCH, KF/MeOH, n-BuLi, and [(CO)₅M(THF)]. For the synthesis of related mono(ferrocenyl)allenylidene chromium complexes, [(CO)₅CrCCC(Fc)R] (R = Ph, NMe₂), three different routes were developed: (a) reaction of the deprotonated propargylic alcohol HCCC(Fc)(Ph)OH with [(CO)₅Cr(THF)] followed by desoxygenation with Cl₂CO, (b) Lewis acid induced alcohol elimination from alkenyl(alkoxy)carbene complexes, [(CO)₅CrC(OR)CHC(NMe₂)Fc], and (c) replacement of OMe in [(CO)₅CrCCC(OMe)NMe₂] by Fc. Complex 1a was also formed when the mono(ferrocenyl)allenylidene complex [(CO)₅CrCCC(Fc)NMe₂] was treated first with Li[Fc] and the resulting adduct then with SiO₂. The replacement route (c) was also applied to the synthesis of an allenylidene complex (7a) with a CC spacer in between the ferrocenyl unit and C_γ of the allenylidene ligand, [(CO)₅CrCCC(NMe₂)-CCFc]. The related complex containing a CHCH spacer (9a) was prepared by condensation of [(CO)₅CrCCC(Me)NMe₂] with formylferrocene in the presence of NEt₃. The bis(ferrocenyl)-substituted allenylidene complexes 1a-c added HNMe₂ across the C_α-C_β bond to give alkenyl(dimethylamino)carbene complexes and reacted with diethylaminopropyne by regioselective insertion of the CC bond into the C_β-C_γ bond to afford alkenyl(diethylamino)allenylidene complexes, [(CO)₅MCCC(NEt₂)CMeCFc₂]. The structures of 5a, 7a, and 9a were established by X-ray diffraction studies.     

Closure of VDAC causes oxidative stress and accelerates the Ca-induced mitochondrial permeability transition in rat liver mitochondria

The electron transport chain of mitochondria is a major source of reactive oxygen species (ROS), which play a critical role in augmenting the Ca²⁺-induced mitochondrial permeability transition (MPT). Mitochondrial release of superoxide anions (O₂⁻) from the intermembrane space (IMS) to the cytosol is mediated by voltage dependent anion channels (VDAC) in the outer membrane. Here, we examined whether closure of VDAC increases intramitochondrial oxidative stress by blocking efflux of O₂⁻ from the IMS and sensitizing to the Ca²⁺-induced MPT. Treatment of isolated rat liver mitochondria with 5 μM G3139, an 18-mer phosphorothioate blocker of VDAC, accelerated onset of the MPT by 6.8 ± 1.4 min within a range of 100-250 μM Ca²⁺. G3139-mediated acceleration of the MPT was reversed by 20 μM butylated hydroxytoluene, a water soluble antioxidant. Pre-treatment of mitochondria with G3139 also increased accumulation of O₂⁻ in mitochondria, as monitored by dihydroethidium fluorescence, and permeabilization of the mitochondrial outer membrane with digitonin reversed the effect of G3139 on O₂⁻ accumulation. Mathematical modeling of generation and turnover of O₂⁻ within the IMS indicated that closure of VDAC produces a 1.55-fold increase in the steady-state level of mitochondrial O₂⁻. In conclusion, closure of VDAC appears to impede the efflux of superoxide anions from the IMS, resulting in an increased steady-state level of O₂⁻, which causes an internal oxidative stress and sensitizes mitochondria toward the Ca²⁺-induced MPT.     

Reactions of [Os3(CO)10(MeCN)2] with ethynyl thiophenes: The formation of linked clusters

The reaction of 2 equiv. of [Os₃(CO)₁₀(MeCN)₂] with R-CC-L-CC-R (R = H, L = (C₄H₂S); R = SiMe₃, L = (C₄H₂S-C₄H₂S), (C₄H₂S-C₄H₂S-C₄H₂S), (C₄H₂S)-(C₁₄H₈)-(C₄H₂S)) affords the series of linked clusters [{Os₃(CO)₁₀}(HCC(C₄H₂S)CCH){Os₃(CO)₁₀}] (1), [{Os₃(CO)₁₀}(Me₃SiCC(C₄H₂S-C₄H₂S)CCSiMe₃){Os₃(CO)₁₀}] (2), [{Os₃(CO)₁₀}(Me₃SiCC(C₄H₂S-C₄H₂S-C₄H₂S)CCSiMe₃){Os₃(CO)₁₀}] (4) and [{Os₃(CO)₁₀}(Me₃SiCC(C₄H₂S)-(C₁₄H₈)-(C₄H₂S)CCSiMe₃){Os₃(CO)₁₀}] (6) as the major products. The complexes have been characterised by a range of spectroscopic methods and, in the case of 1 and 2 by single crystal X-ray crystallography. The alkyne groups cap the osmium triangles in the expected μ₃-η²-||-bonding mode and each triangle is coordinated by nine terminal and one μ₂-carbonyl group. Solution UV-Vis spectra of the complexes were similar to those observed for the free ligands consistent with there being little delocalisation between the cluster units and the thiophene groups.