The kinetics and stereochemistry of base hydrolysis of the seven isomers of [Co(dien)(ampy)Cl] and [Co(dien)(ibn)Cl]

The kinetics and stereochemistry for the base catalysed substitution reactions of all seven isomers (4 mer and 3 fac) of both [Co(dien)(ibn)Cl]²⁺ and [Co(dien)(ampy)Cl]²⁺ have been studied in detail, for water and azide ion as entering groups. The stereochemistry for the azide ion anation of some of the [Co(dien)(diamine)OH]²⁺ species have also been investigated. The mer isomers are of comparable reactivity and amongst the fastest reacting pentaaminechlorocobalt(III) complexes known. They are also much faster to hydrolyse than the fac species. In both the ibn and ampy systems, a common product stereochemistry is observed for the four reactant mer isomers (the product is a mixture of all four mer configurations), for both azide ion and water as nucleophiles, but not for the three fac reactants (H₂O as nucleophile). The kinetic and equilibrium distributions are quite different. For the mer isomer reactions, a common trigonal bipyramidal five-coordinate intermediate deprotonated at the sec-NH of the dien is overwhelmingly implicated. The substitution mechanisms are argued in detail. Other data reported include isomerisation rates and equilibrium distributions for some mer-hydroxo and a mer-aqua complex of exceptional reactivity, equilibrium distributions for the mer-phosphato complexes in the ampy system under different pH conditions, the crystal structure for the isolated m1-[Co(dien)(ampy)OP(OH)₃]Cl₃ · 2H₂O species, and a rationale for its predominance at neutral pH based on internal H-bonding.     

Reactions of the Tridentate and Tetradentate Amine Ligands di-(2-picolyl)(N-ethyl)amine and 2,5-Bis-(2-pyridylmethyl)-2,5 diazohexane with Technetium Nitrosyl Complexes

The reaction of the Tc(II) nitrosyl complex (Bu₄N)[Tc(NO)Cl₄] with di-(2-picolyl)(NEt)amine in methanol yields the neutral complex [Tc(NO)Cl(py-N(Et)-py)]. The reaction of the Tc(I) nitrosyl complex [Tc(NO)Cl₂(HOMe)(PPh₃)₂] with this tridentate ligand yields cationic [Tc(NO)Cl(py-N(Et)-py)(PPh₃)]Cl. These two complexes have been structurally characterized. The reaction of [Tc(NO)Cl₂(HOMe)(PPh₃)₂] with the tetradentate ligand 1,4-bis-(2-pyridylmethyl)-1,4-diazobutane yields a mixture of products including cationic [Tc(NO)Cl(py-NH-NH-py)]Cl and cationic [Tc(NO)Cl(PPh₃)(py-NH-NH∼py)]Cl, with a pyridyl terminus left dangling.     

A structural study of late transition metal diethylenetriamine complexes

The synthesis and X-ray crystal structures of u-fac-[Ni(dien)₂](NO₃)₂, s-fac-[Ni(dien)₂](tos)₂, fac-fac-[(H₂O)(dien)Ni(μ-Cl)₂(dien)(H₂O)]Cl₂, s-fac-[Ni(dien)₂][ZnCl₄], mer-[Ni(dien)₂][CdCl₄] · H₂O, fac-[Ni(dien)(H₂O)₃](tos)₂ · (H₂O), mer-[Cu(dien)(H₂O)](tos)₂, fac-[Zn(dien)(H₂O)₂](tos)₂ (dien = bis(2-aminoethyl)amine = diethylenetriamine; tos = p-toluenesulfonate) are described. The mode of binding of the tridentate amine is examined in detail.     

Influence of ligands on the fac⇌Δhνmer isomerization in [RuCl3(NO)(P–P)] complexes, [P–P = R2P(CH2)nPR2 (n = 1–3) and R2P(CH2)POR2, PR2–CHCH–PR2, R = Ph and (C6H11)2P-(CH2)2-P(C6H11)2]

[RuCl₃(NO)(P–P)], [P–P = R₂P(CH₂)_nPR₂ (n = 1–3) and R₂P(CH₂)POR₂, PR₂–CHCH–PR₂, R = Ph and (C₆H₁₁)₂P-(CH₂)₂-P(C₆H₁₁)₂] were obtained and characterized by ³¹P {¹H} NMR, IR spectroscopies and cyclic voltammetry. The structures of fac-[RuCl₃(NO)(P–P)], P–P = dppm (1), dppe (2), c-dppen (3) and dppp (4), mer-[RuCl₃(NO)(dcpe)] (6a) and mer-[RuCl₃(NO)(dppmO)] (7) have been determined by X-ray diffraction. Photochemical isomerization of fac- to mer-[RuCl₃(NO)(P–P)] was observed under white light in a CH₂Cl₂ solution and in solid state. The isomerization processes were followed by IR and ³¹P {¹H} spectra. The mer-[RuCl₃(¹⁵NO)(dppb)] isomer was used for the definition of the phosphorus atoms in the structure of the complex in solution. The electrochemical study shows that the oxidation/reduction processes observed in these complexes are dependent on both the isomer (fac or mer) and the solvent. In CH₂Cl₂, the NO⁺ reduction potentials are less negative for the mer-isomers than for the fac ones, while in CH₃CN solvent these potentials are, in general, very close for both isomers.     

Geometrical and optical isomers of diethylenetriaminemonoacetato(ethylene-diamine)cobalt(III) ion and their isomerism

Two isomers of the complex ion in the title were obtained and each isomer was resolved chromatographically into its antipodes. The two isomers with their isomer proportion of 27.9 and 72.1% in the equilibrium mixture were assigned to α and β(mer-N) isomers, respectively, of three possible geometrical isomers, from the measurements of their absorption, circular dichroism, and NMR spectra.Preference of the β(mer-N) to the isomer and very poor yield of an expected β(fac-N) isomer were confirmed by conformational analyses carried out for each structure of the isomers of Λ configuration, with possible configurations around nitrogen atoms and conformations of chelate rings. They gave minimized total strain energies of 43.13, 44.24, and 52.63 kJ/mol for the Λ-R,R(en:λ) structure of a β(mer-N) isomer, the Λ-S,R(δ,δ) structure of an α isomer, and a Λ-R,S(λ,λ) structure of a β(fac-N) isomer, respectively.From the results, configurations and conformations of the enantiomers of the resolved β(mer-N) and its isomers were deduced. An unfound isomer, β(fac-N) isomer, is thought to be very unstable; it would exist as less than 2% of the amount of β(mer- N) isomer, even if it were present in the reaction mixture.     

The synthesis and characterization of a cationic technetium nitrosyl complex: The X-ray crystal structure of [TcCl(NO)(DPPE)2](PF6) · CH2Cl2

The reaction of the ammonium pertechnetate with a stochiometric excess of hydroxylamine hydrochloride in methanol yields a nitrosyl containing intermediate which can subsequently be reacted with reducing ligands to form nitrosyl complexes in various oxidation states. The reaction with a sixfold excess of diphenyl-phosphinoethane (DPPE) yields the Tc(I) cation [TcCl(NO)(DPPE)₂]⁺ which can be precipitated cleanly with tetraphenylborate. The infrared spectrum displays an absorption at 1728 cm⁻¹ which corresponds to the nitrosyl group. The ESI(+) mass spectrum displays the parent ion [TcCl(NO)(DPPE)₂]⁺ as the only signal at 960 m/z.The X-ray crystal structure of the hexafluorophosphate salt shows a mutually trans arrangement of the nitrosyl and chloride ligands with the two bidentate phosphine ligands coordinated in the equatorial plane. The nitrosyl and chloride ligands display the usual site disorder which makes discussion of bond lengths tenuous. However, the Tc-N-O bond angle of 179.0(2)° reflects the sp hybridization of the nitrosyl nitrogen atom. The Tc-P bonds are somewhat elongated at 2.3810(6), 2.3947(6), 2.4096(5) and 2.4321(6) Å, due to the steric congestion around the metal ion. The Tc-Cl bond is unexceptional at 2.3262(7) Å. The coordination geometry of this complex is best described as a distorted octahedron.     

Modulation of trans-to-cis photoisomerization and photoluminescence of 1,2-bis(4-pyridyl)ethylene or 4-styrylpyridine coordinated to fac-tricarbonyl(5-chloro-1,10-phenathroline)rhenium(I)

Photochemical and photophysical properties of fac-[Re(CO)₃(Clphen)(trans-L)]⁺ complexes, Clphen = 5-chloro-1,10-phenathroline and L = 1,2-bis(4-pyridyl)ethylene, bpe, or 4-styrylpyridine, stpy, were investigated to complement the understanding of intramolecular energy transfer process in tricarbonyl rhenium(I) complexes having an electron withdrawing group attached to polypyridyl ligands. These new compounds were synthesized, characterized and the photoisomerization quantum yields were accurately determined by ¹H NMR spectroscopy. The true quantum yields for fac-[Re(CO)₃(Clphen)(trans-bpe)]⁺ were constant (Φ = 0.55) at all investigated irradiation wavelengths. However, for fac-[Re(CO)₃(Clphen)(trans-stpy)]⁺, similar true quantum yields were observed only at higher energy irradiation (Φ_{313 nm} = 0.53 and Φ_{365 nm} = 0.57), but it decreased significantly at 404 nm (Φ = 0.41). These results indicated different deactivation pathways for the trans-stpy complex photoisomerization. Quantum yields decreased as the ³IL_trans-L and ³MLCT_Re→NN excited states become closer and the behavior was discussed in terms of the excited state energy gaps. Additionally, luminescence properties of photoproducts, fac-[Re(CO)₃(Clphen)(cis-L)]⁺, were also investigated in different environments to analyze the relative energy of the ³MLCT_Re→Clphen excited state for each compound.     

Synthesis, cellular uptake and structure-activity relationships for potent cytotoxic trichloridoiridium(III) polypyridyl complexes

The complexes fac-[IrCl₃(DMSO)(pp)] 1a-5a may be prepared by stepwise reaction of IrCl₃ · 3H₂O with the appropriate polypyridyl ligand (pp = bpy, phen, dpq, dppz, dppn) and DMSO in CH₃OH solution in the dark. The fac isomers of 1a-5a are stable in light-protected CD₂Cl₂ solution but, with the exception of 5a, isomerize rapidly to a mixture of the fac and mer isomers in the presence of light. In contrast, solutions of the fac isomers in the polar solvents D₂O and CD₃OD are stable under such conditions. The isomer mer-[IrCl₃(DMSO-κS)(phen)] 2b was, however, isolated by slow evaporation of an H₂O/CH₃OH solution of 2a and characterized by X-ray structural analysis. UV/Vis and CD studies of the interaction of 1a-5a with calf thymus DNA are in accordance with an effective absence of intercalation. ¹H NMR studies indicate that the complexes react slowly with compounds containing soft S donor atoms (e. g. N-acetylmethionine) but do not react with the guanine base of 5′-GMP²⁻. The complexes 2a-5a are potent in vitro cytotoxic agents toward the human cell lines MCF-7 and HT-29 and their IC₅₀ values are dependent on the size of the polypyridyl ligand in the order phen, dpq > dppz > dppn. For instance IC₅₀ values of 5.5 (0.9), 0.8 (0.3) and 0.21 (0.11) μM were established for 3a-5a against MCF-7 cells and 6.1 (0.7), 1.5 (0.2) and 1.3 (0.4) μM against HT-29 cells. These values correlate with the cellular uptake efficiency which, on exposure to 10 μM solutions, reaches its highest levels (19.3(0.8) and 37.4(8.9) ng Ir/mg protein for MCF-7 and HT-29, respectively) for the dppn compound 5a.     

Preparation and structure of [Ru2(O2CMe)4]2[Fe(CN)5NO] and magnetically ordered Hx[Ru2(O2CMe)4]3−x[Cr(CN)5NO] possessing interpenetrating lattices

Reaction of [Ru₂(O₂CMe)₄]Cl with K₃[Cr(CN)₅NO] in water forms H_x[Ru^II/III₂(O₂CMe)₄]_3−x-[Cr(CN)₅NO]·zH₂O (x = 0.2) that magnetically orders at 4.0 K and possesses an interpenetrating body centered cubic [a = 13.2509(2) Å] structure with random locations of the bridging nitrosyl ligands, and x/3 vacant cation sites. Similarly, the aqueous reaction of [Ru₂(O₂CMe)₄]Cl with Na₂[Fe(CN)₅NO] forms paramagnetic [Ru₂(O₂CMe)₄]₂[Fe(CN)₅NO]·H₂O, which has a similar tetragonal interpenetrating structure [a = 13.0186(1) Å, c = 13.0699(2) Å] where the NO ligands are presumably nonbridging and 1/3 of the expected cation sites are unoccupied. The presence of uncoordinated NO sites in addition to missing neighboring [Ru₂(O₂CMe)₄]⁺ units, results in significant vacancies (or holes) in the lattice.     

Mono- and trichloride clathrochelate iron (II) chloroglyoximates and their functionalization: The effect of the substituents in the clathrochelate framework on the reactivity of the chlorine-containing fragments in nucleophilic substitution reactions

The direct template macrocyclization of the three chloroglyoxime molecules with boron-containing Lewis acids on the iron (II) ion matrix led to the formation of a mixture of fac- and mer-isomers of clathrochelate complexes in the 1:3 ratio, which is equal to a statistical one. The yields of tris-chloroglyoximate precursors (25-40%) were practically the same as those for their earlier-studied chloromethylglyoximate analogs, whereas the reactivity of the former complex has proved to be markedly higher than that of the latter clathrochelates: the triamine clathrochelates were the major products in the reaction of (mer + fac)-Fe(ClHGm)₃(BC₆H₅)₂ and (mer + fac)-Fe(ClHGm)₃(BF)₂ complexes with n-butylamine, whereas for (mer + fac)-Fe(ClCH₃Gm)₃(BC₆H₅)₂ clathrochelate an analogs reaction produced the diamine complex only. The mixture of the diamine clathrochelate isomers was obtained in both cases with less reactive cyclohexylamine. The reaction of the trichloride precursors with alkyl- and arylthiols in the presence of triethylamine has proceeded more readily and led to the formation of trisulfide clathrochelates.The monochloride FeBd₂(ClHGm)(BF)₂ complex, obtained by the condensation of the macrocyclic bis-dioximate [FeBd₂(BF₂)₂ (CH₃CN)₂] with chloroglyoxime, readily underwent the nucleophilic substitution of the reactive chlorine atom with amines and thiol-containing functionalizing agents. The clathrochelate complexes with pendant substituents, containing reactive terminal HO-, H₂N- and HS-groups, were obtained. Thiolate FeBd₂(H(HSCH₂CH₂S)Gm)(BF)₂ clathrochelate underwent the intramolecular elimination of ethylene sulfide in basic media to yield the clathrochelate with attached HS-group. Clathrochelates obtained have been characterized using elemental analysis, PD and MALDI-TOF mass, IR, UV-Vis, ⁵⁷Fe Mössbauer and ¹H, ¹³C and ¹¹B NMR spectroscopies, and X-ray crystallography (for the fac-Fe(ClHGm)₃(BC₆H₅)₂ and FeBd₂{H(CH₃S)Gm}(BF)₂ · 2C₆H₆ complexes). X-ray structure of a fac-isomer of clathrochelate complex was solved for the first time in this study. Configurations intermediate between trigonal prismatic and trigonal antiprismatic have been deduced for the low-spin iron (II) ion coordination polyhedra of all clathrochelates obtained using ⁵⁷Fe Mössbauer parameters.     

fac-/mer-[RuCl3(NO)(P-N)] (P-N = [o-(N,N-dimethylamino)phenyl]diphenylphosphine): Synthesis, characterization and DFT calculations

Complex fac-[RuCl₃(NO)(P-N)] (1) was synthesized from the reaction of [RuCl₃(H₂O)₂(NO)] and the P-N ligand, o-[(N,N-dimethylamino)phenyl]diphenylphosphine) in refluxing methanol solution, while complex mer,trans-[RuCl₃(NO)(P-N)] (2) was obtained by photochemical isomerization of (1) in dichloromethane solution. The third possible isomer mer,cis-[RuCl₃(NO)(P-N)] (3) was never observed in direct synthesis as well as in photo- or thermal-isomerization reactions. When refluxing a methanol solution of complex (2) a thermally induced isomerization occurs and complex (1) is regenerated.The complexes were characterized by NMR (³¹P{¹H}, ¹⁵N{¹H} and ¹H), cyclic voltammetry, FTIR, UV-Vis, elemental analysis and X-ray diffraction structure determination. The ³¹P{¹H} NMR revealed the presence of singlet at 35.6 for (1) and 28.3 ppm for (2). The ¹H NMR spectrum for (1) presented two singlets for the methyl hydrogens at 3.81 and 3.13 ppm, while for (2) was observed only one singlet at 3.29 ppm. FTIR Ru-NO stretching in KBr pellets or CH₂Cl₂ solution presented 1866 and 1872 cm⁻¹ for (1) and 1841 and 1860 cm⁻¹ for (2). Electrochemical analysis revealed a irreversible reduction attributed to Ru^II-NO⁺ → Ru^II-NO⁰ at −0.81 V and −0.62 V, for (1) and (2), respectively; the process Ru^II → Ru^III, as expected, is only observed around 2.0 V, for both complexes.Studies were conducted using ¹⁵NO and both complexes were isolated with ¹⁵N-enriched NO. Upon irradiation, the complex fac-[RuCl₃(NO)(P-N)] (1) does not exchange ¹⁴NO by ¹⁵NO, while complex mer,trans-[RuCl₃(NO)(P-N)] (2) does. Complex mer,trans-[RuCl₃(¹⁵NO)(P-N)] (2′) was obtained by direct reaction of mer,trans-[RuCl₃(NO)(P-N)] (2) with ¹⁵NO and the complex fac-[RuCl₃(¹⁵NO)(P-N)] (1′) was obtained by thermal-isomerization of mer,trans-[RuCl₃(¹⁵NO)(P-N)] (2′).DFT calculation on isomer energies, electronic spectra and electronic configuration were done. For complex (1) the HOMO orbital is essentially Ru (46.6%) and Cl (42.5%), for (2) Ru (57.4%) and Cl (39.0%) while LUMO orbital for (1) is based on NO (52.9%) and is less extent on Ru (38.4%), for (2) NO (58.2%) and Ru (31.5%).     

Synthesis and structural characterization of zwitterionic oxorhenium(V) complexes with 2-hydroxypyridine

[ReOX₃(PPh₃)₂] complexes (X = Cl and Br) react with equivalent amounts of 2-hydroxypyridine (Hhp) under formation of the mono-substituted, zwitterionic complexes mer-[ReOCl₃(Hhp)(PPh₃)] (1) and mer-[ReOBr₃(Hhp)(PPh₃)] (2). Crystal structure determinations of 1 · CH₂Cl₂ and 2 revealed the Cl and Br ligands adopt a mer arrangement. The Hhp ligands coordinate neutral and monodentate via their exocyclic oxygen atoms in axial positions, trans to the oxo groups. The distorted octahedral coordination sphere of the rhenium(V) complexes is completed by the phosphorus atom of the remaining PPh₃ ligand.     

Ultrafast excited-state dynamics of photoisomerizing complexes fac-[Re(Cl)(CO)3(papy)2] and fac-[Re(papy)(CO)3(bpy)] (papy = trans-4-phenylazopyridine)

The character and dynamics of low-lying electronic excited states of the complexes fac-[Re(Cl)(CO)₃(papy)₂] and fac-[Re(papy)(CO)₃(bpy)]⁺ (papy = trans-4-phenylazopyridine) were investigated using stationary (UV-Vis absorption, resonance Raman) and ultrafast time-resolved (visible, IR absorption) spectroscopic methods. Excitation of [Re(Cl)(CO)₃(papy)₂] at 400 nm is directed to ¹ππ^∗(papy) and Re → papy ¹MLCT excited states. Ultrafast (?1.4 ps) intersystem crossing (ISC) to ³nπ^∗(papy) follows. Excitation of [Re(papy)(CO)₃(bpy)]⁺ is directed to ¹ππ^∗(papy), ¹MLCT(papy) and ¹MLCT(bpy). The states ³nπ^∗(papy) and ³MLCT(bpy) are then populated simultaneously in less then 0.8 ps. The ³MLCT(bpy) state decays to ³nπ^∗(papy) with a 3 ps time constant. ³nπ^∗(papy) is the lowest excited state for both complexes. It undergoes vibrational cooling and partial rotation around the -NN- bond, to form an intermediate with a nonplanar papy ligand in less than 40 ps. This species then undergoes ISC to the ground state potential energy surface, on which the trans and cis isomers are formed by reverse and forward intraligand papy rotation, respectively. This process occurs with a time constant of 120 and 100 ps for [Re(Cl)(CO)₃(papy)₂] and [Re(papy)(CO)₃(bpy)]⁺, respectively. It is concluded that coordination of papy to the Re center accelerates the ISC, switching the photochemistry from singlet to triplet excited states. Comparison with analogous 4-styrylpyridine complexes (M. Busby, P. Matousek, M. Towrie, A. Vl?ek Jr., J. Phys. Chem. A 109 (2005) 3000) reveals similarities of the decay mechanism of excited states of Re complexes with ligands containing -NN- and -CC- bonds. Both involve sub-picosecond ISC to triplets, partial rotation around the double bond and slower ISC to the trans or cis ground state. This process is about 200 times faster for the -NN- bonded papy ligand. The intramolecular energy transfer from the ³MLCT-excited ^∗Re(CO)₃(bpy) chromophore to the intraligand state of the axial ligand occurs for both L = stpy and papy with a comparable rate of a few ps.     

Chiral spin crossover iron(II) complex, fac-Λ-[Fe(HL)3](ClO4)2·EtOH (HL = 2-methylimidazol-4-yl-methylideneamino-R-(+)-1-methylphenyl)

A chiral spin crossover iron(II) complex, fac-Λ-[Fe^II(HL^R)₃](ClO₄)₂·EtOH was synthesized and its crystal structures in both the high-spin (HS) and low-spin (LS) states were determined, where HL^R denotes 2-methylimidazol-4-yl-methylideneamino-R-(+)-1-methylphenyl. The complex assumes octahedral coordination geometry of N₆ donor atoms by three bidentate ligands HL^R. The complex exists as the facial-Λ-isomer of fac-Λ-[Fe^II(HL^R)₃]²⁺ of the possible geometrical fac- and mer-isomers and the Δ- and Λ-enantiomorphs. The X-ray structural analyses revealed that the R-form of the ligand (HL^R) induces the fac-Λ-isomer of fac-Λ-[Fe^II(HL^R)₃]²⁺ and the S-form of the ligand (HL^S) induces the fac-Δ-isomer of fac-Δ-[Fe(HL^S)₃]²⁺. The complex fac-Λ-[Fe^II(HL^R)₃](ClO₄)₂·EtOH shows a complete steep spin crossover between the HS and the LS states at T_1/2 = 195 K.     

Synthesis, structure and antitumor activity of [RhCl3(N-N)(DMSO)] polypyridyl complexes

The [RhCl₃(N-N)(DMSO)] complexes, the N-N being 2,2′-bipyridine (1), 1,10-phenanthroline (2), 4,7-diphenyl-1,10-phenanthroline (3), 4,4′-dimethyl-2,2′-bipyridine (4) and 1,10-phenanthroline-5,6-dione (5), have been synthesized and characterized with spectroscopic methods. The compounds 2-5 adopt mer- and complex 1fac-structure. The molecular and electronic structure studies of mer- and fac-complexes with bpy and phen ligands at the DFT B3LYP level with 3-21G^∗∗ basis set showed that mer-isomers are more stable. The cytostatic activity of the [RhCl₃(N-N)(DMSO)] complexes against Caco-2 and A549 tumor cells have been studied. Their antibacterial activity have also been investigated. It has been found that the very promising biological activity show complexes 2, 3 and 4.     

Synthesis and characterization of [Ru(NO)(bpp)Cl · 2H2O] [bpp = N,N′-bis(2-pyridinecarboxamide)-1,3-propane dianion] and [Ru(NO)(bpe)Cl · 2H2O] [bpe = N,N′-bis(2-pyridinecarboxamide)-1,2-ethane dianion]

Two ruthenium nitrosyl bis-pyridyl/biscarboxamido compounds, [Ru(NO)(bpp)Cl · 2H₂O] [bpp = N,N′-bis(2-pyridinecarboxamide)-1,3-propane dianion] and [Ru(NO)(bpe)Cl · 2H₂O] [bpe = N,N′-(bis-2-pyridinecarboxamide)-1,2-ethane dianion] have been characterized by ¹H NMR, ¹³C{¹H} NMR, and IR spectroscopies, electrospray ionizaton mass spectrometry, and X-ray crystallography.     

Benzimidazole derivatives as NSO ligands for the fac-[M(CO)3] (M = Re, Tc)

Two rhenium(I) tricarbonyl complexes with the tridentate monoanionic NSO ligands, 4-(benzimidazol-2-yl)-3-thiabutanoic acid (complex 3) and [1-(11-carboxyundecanyl)-4-(benzimidazol-2-yl)]-3-thiabutanoic acid (complex 4) were synthesized and characterized by spectroscopic methods and elemental analysis. X-ray crystallographic analysis of complex 3 revealed a distorted octahedral geometry around rhenium defined by the three facially bound CO groups and the NSO donor atom set of the tridentate ligand. The analogous technetium-99m complexes (complexes 5 and 6) were also prepared quantitatively by reaction of the NSO ligands with the fac-[^99mTc(H₂O)₃(CO)₃]⁺ synthon and their identity was established by chromatographic comparison to their rhenium congeners. Biodistribution in mice of complex 6 bearing the fatty acid chain showed significant heart uptake (6.26 ± 0.79% ID/g p.i.) at 1 min accompanied, however, with a heart:blood ratio below 1.     

Phloroglucinol-bridged trinuclear complexes with three paramagnetic octahedral nickel(II) ions: Syntheses, crystal structures, and magnetic properties

Three new C₃-symmetric tritopic ligands with a central phloroglucinol bridging unit have been synthesized and characterized. The ligands are accessible through Schiff-base condensation of 2,4,6-triformylphloroglucinol with 2-aminomethylpyridine (H₃tfpg-ampy), N,N-bis(pyridin-2-ylmethyl)-ethylenediamine (H₃tfpg-unspenp), and benzhydrazide (H₆tfpg-bhy). These ligands differ in nature and number of the donor atoms within the resulting binding pockets. Based on these ligands the synthesis of the first trinuclear phloroglucinol-bridged nickel(II) complexes with three octahedrally coordinated nickel centers is reported. The ligands H₃tfpg-ampy and H₆tfpg-bhy, which provide tridentate binding pockets, react with nickel(II) perchlorate in the presence of bis(pyridin-2-ylethyl)-amine (bpea) as an additional tridentate capping ligand leading to the formation of the trinuclear complexes [Ni₃(tfpg-ampy)(bpea)₃](ClO₄)₃ and [Ni₃(tfpg-bhy)(bpea)₃](ClO₄)₃, respectively. Due to the pentadentate binding pocket in ligand H₃tfpg-unspenp, no additional coligand is needed and a water molecule occupies the sixth coordination site at the nickel(II) ion resulting in the complex [Ni₃(tfpg-unspenp)(H₂O)₃](ClO₄)₃. Temperature-dependent magnetic measurements reveal overall weak antiferromagnetic exchange interactions within the trinuclear complex together with a rather strong zero-field splitting (ZFS) for the nickel(II) ions. The observed isotropic coupling constants for the three complexes are in the range of 0.14 < − J < 0.37 cm⁻¹, whereas for the zero-field splitting parameter ∣D∣ values between 1.8 and 5.5 cm⁻¹ are found. This is indicative for competitive spin-polarization and superexchange mechanisms, with the latter prevailing the interaction between the nickel(II) ions through the meta-phenylene-linkage for the complexes reported.     

Identification of cis/trans isomers of bis(acetylacetonato)nickel(II) complexes in solution based on electronic spectra

Electronic spectra of Ni(acac)₂ were studied in acetone, DMF, and some other solvents for the purpose of identifying the cis/trans isomers from the spectra (acac⁻ = acetylacetonate anion). The spectral components were investigated in the spin-allowed transition bands, and a relationship was found between the spectral pattern and the cis/trans isomers. According to this relationship, it was concluded that the cis isomer was formed in DMF and in N-methylformadide, whereas the trans isomer was formed in acetone and in pyridine. Based on the DFT computation, the cis-[Ni(acac)₂(DMF)₂] was found to be stabilized by intramolecular hydrogen bonds between acetylacetonate and DMF.     

Synthesis, characterization, X-ray molecular structure and catalase-like activity of a non-heme iron complex: Dichloro[N-propanoate-N,N-bis-(2-pyridylmethyl)amine]iron(III)

In this work we present the synthesis and characterization of the complex dichloro[N-propanoate-N,N-bis-(2-pyridylmethyl)amine]iron(III) [Fe^III(PBMPA)Cl₂]. The ligand LiPBMPA was synthesized through the Michael reaction of BMPA with methylacrylate, followed by alkaline hydrolysis. The complex [Fe^III(PBMPA)Cl₂] has been synthesized by the reaction of the ligand with FeCl₃ · H₂O and was mainly characterized by cyclic voltammetry, conductivimetry, and electronic, infrared and Mössbauer spectroscopies, and by X-ray structural analysis, which showed an iron center coordinated by one carboxylate oxygen in a monodentate way, one tertiary amine, two pyridine groups and two chloride ions. It has been proposed that in water the chloride ligands are shifted by the solvent molecules and the species [Fe^III(PBMPA)(H₂O)₂]Cl₂ is predominant. The catalase-like activity of the complex was tested in water, and it proved to be active in the hydrogen peroxide dismutation. Kinetics studies were conducted following the initial rates method. The reaction is first order in relation to both the complex and the hydrogen peroxide. Based on the presence of a lag phase that depends on the initial complex concentration, we propose that the active species that shows in situ catalase-like activity, is a binuclear complex.