Photoinduced Nitric Oxide and Singlet Oxygen Release from ZnPC Liposome Vehicle Associated with the Nitrosyl Ruthenium Complex: Synergistic Effects in Photodynamic Therapy Application

Under continuous photolysis at 675 nm, liposomal zinc phthalocyanine associated with nitrosyl ruthenium complex [Ru(NH.NHq)(tpy)NO]³⁺ showed the detection and quantification of nitric oxide (NO) and singlet oxygen (¹O₂) release. Photophysical and photochemical results demonstrated that the interaction between the nitrosyl ruthenium complex and the photosensitizer can enable an electron transfer process from the photosensitizer to the nitrosyl ruthenium complex which leads to NO release. Synergistic action of both photosensitizers and the nitrosyl ruthenium complex results in the production of reactive oxygen species and reactive nitrogen species, which is a potent oxidizing agent to many biological tissues, in particular neoplastic cells.     

Reaction mechanism of NO with hydrolysates of NAMI-A: an MD simulation by combining the QM/MM(ABEEM) with the MD-FEP method

Nitrosylation reaction mechanisms of the hydrolysates of NAMI-A and hydrolysis reactions of ruthenium nitrosyl complexes were investigated in the triplet state and the singlet state. Activation free energies were calculated by combining the QM/MM(ABEEM) method with free energy perturbation theory, and the explicit solvent environment was simulated by an ABEEMσπ polarizable force field. Our results demonstrate that nitrosylation reactions of the hydrolysates of NAMI-A occur in both the triplet and the singlet states. The Ru-N-O angle of the triplet ruthenium nitrosyl complexes is in the range of 132.0°–138.2°. However, all the ruthenium nitrosyl complexes at the singlet state show an almost linear Ru-N-O angle. The nitrosylation reaction happens prior to the hydrolysis reaction for the first-step hydrolysates. The activation free energies of the nitrosylation reactions show that the H₂O-NO exchange reaction of [RuCl₄(Im)(H₂O)] in the singlet spin sate is the most likely one. Comparing with the activation free energies of the hydrolysis reactions of the ruthenium nitrosyl complexes, the results indicate that the rate of the DMSO–H₂O exchange reaction of [RuCl₃(NO)(Im)(DMSO)] is faster than that of [RuCl₃(H₂O)(Im)(DMSO)] in both the triplet spin state and the singlet spin state. © 2018 Wiley Periodicals, Inc.     

Ruthenium(salen)-catalyzed aerobic oxidative desymmetrization of meso-diols and its kinetics

Chiral (nitrosyl)ruthenium(salen) complexes were found to be efficient catalysts for aerobic oxidative desymmetrization of meso-diols under photoirradiation to give optically active lactols. The scope of the applicability of this reaction ranges widely from acyclic diols to mono-cyclic diols, although fine ligand-tuning of the ruthenium(salen) complexes was required to attain high enantioselectivity (up to 93% ee). In particular, the nature of the apical ligand was found to affect not only enantioselectivity but also kinetics of the desymmetrization reaction. Spectroscopic analysis of the oxidation disclosed that irradiation of visible light is indispensable not only for dissociation of the nitrosyl ligand but also for single electron transfer from the alcohol-bound ruthenium ion to dioxygen.     

Sensitization of NO‐Releasing Ruthenium Complexes to Visible Light

We report a combined spectroscopical–theoretical investigation on the photosensitization of transition metal nitrosyl complexes. For this purpose, ruthenium nitrosyl complexes based on tetradentate biscarboxamide ligands were synthesized. A crystal structure analysis of a lithium‐based ligand intermediate is described. The Ru complexes have been characterized regarding their photophysical and nitric oxide (NO) releasing properties. Quantum chemical calculations have been performed to unravel the influence of the biscarboxamide ligand frame with respect to the molecular electronic properties of the NO‐releasing pathway. A quantitative measure for the ligand design within photosensitized Ru complexes is introduced and evaluated spectroscopically and theoretically by using time‐dependent density functional theory.     

PHOTOCHEMISTRY OF RUTHENIUM NITROSYL COMPLEXES IN SOLIDS AND SOLUTIONS AND ITS POTENTIAL APPLICATIONS

Journal of Structural Chemistry - The review is devoted to photochemical transformations of ruthenium nitrosyl complexes in various media and their potential applications in the context of these...     

Nitric oxide release from a photoactive water-soluble ruthenium nitrosyl. Biological effects

Abstract

This research presents the synthesis and characterization of the photochemical nitric oxide (NO) precursor Ru(salenCO₂H)(NO)Cl (1, salenCO₂H = N,N’-ethylenebis(3,3’-bis-carboxylsalicylideneiminato). This water-soluble ruthenium nitrosyl releases NO upon photolysis with a quantum yield that is pH dependent owing to the nitrosyl to nitrite conversion of that axial ligand at higher pH. Also described are the water, oxygen, and thermal stability of 1 and the cytotoxicity and the vascular relaxivity properties of 1 in the dark and under photolysis.     

Determination of traces of ruthenium by addition of cerium(IV) and atomic absorption spectrometry

The sensitivity of the determination of ruthenium by flame atomic absorption spectrometry is increased 60 times by adding 1 × 10^?2 M cerium(IV). Calibration is linear over the range of 0.05–5 μg ml^?1 ruthenium. A method applicable to nitrosylruthenium complexes is described. The increased sensitivity results from formation of ruthenium tetroxide.     

Interaction of aryldiazonium salts with some schiff-base complexes of cobalt and ruthenium

The interaction of aryldiazonium ions with some Schiff-base complexes of cobalt and ruthenium have been studied. With cobalt, one-electron oxidation of [Co(II)Salen] occurred; with [Co(I)Salen] the corresponding Co(III)-aryl complexes were isolated. In the case of ruthenium oxidation also occurs, [Ru(Salen)(CO)py] gave the corresponding monocation. The results, especially for ruthenium, are in contrast to the stabilisation of both nitrosyl and aryldiazonium adducts in analogous porphyrin complexes.     

氢还原重量法测定亚硝酰硝酸钌溶液中的钌含量

采用盐酸前处理样品,干燥后通氢还原纯化,建立了氢还原重量法测定亚硝酰硝酸钌溶液中的钌含量的方法。结果表明,在称样量为4.0g、盐酸加入量3mL,程序升温750℃,保温90min条件下,测定结果最好。测定钌含量为5.50%、10.89%的两种样品,两种样品钌含量分析结果的极差分别为0.11%、0.16%,相对标准偏差(RSD,n=7)分别为0.66%、0.52%,与其他标准分析方法相比,测定结果的准确度和精密度更好。     

A trinuclear bis(dioximate)(chloro)(nitrosyl)ruthenium(II) complex containing two (2,2′-bipyridine)copper(II) groups

A trinuclear bis(cyclohexanedioximate)(chloro)(nitrosyl)ruthenium(II) complex containing two (2,2-bipyridine)-copper(II) groups has been synthesized and its electronic and electrochemical properties investigated. According to ZINDO/S calculations, the electronic structure of the ruthenium(dioximate)(nitrosyl) moiety is strongly delocalized. The electrochemical behavior has been interpreted with the aid of spectroelectrochemical measurements. In the trinuclear complex, it has been shown that the copper(II) ions can promote the oxidation of the NO species generated electrochemically, and also mediate the redox reactions of the complex, under a dioxygen atmosphere.     

A multinuclear magnetic resonance study of transformations of ruthenium(II) nitrosyl chloride complexes in aqueous solutions

Aqueous solutions of ruthenium nitrosyl chloride complexes have been studied by¹⁴N, ¹⁵N, ¹⁷O, ⁹⁹Ru, and ³⁵Cl NMR. Individual complex species have been identified and the corresponding chemical shifts have been determined. The primary aquation product of the pentachloronitrosylruthenate ion is the cis-[RuNO(H₂O)Cl₄]^? complex, which subsequently undergoes isomerization. The equilibrium constants of interconversions of ruthenium nitrosyl chloride complexes in an aqueous solution at room temperature have been estimated.     

Improvements in the sample preparation for the determination of ruthenium in catalysts by different spectrometric techniques

The sample preparation steps of two analytical methods for the determination of ruthenium in carbon supported catalysts with flame atomic absorption spectrometry (FAAS) or UV-vis spectrophotometry, were carefully optimised. As a first step, the carbon support is ignited in air at 450 degrees C then the residue is fused with potassium hydroxide and potassium nitrate to convert ruthenium into ruthenate anion RuO4(2-). The melt is dissolved in water with potassium persulphate and potassium hydroxide as stabilisers. Ruthenium may be directly estimated by measuring the UV-vis molecular absorption of ruthenate at the isosbestic point of the ruthenate-perruthenate mixture or by FAAS. In the latter case, an aliquot of the sample solution is added to the concentrated hydrochloric acid to obtain hexachlororuthenate RuCl6(2-), that is nebulized into the flame after proper dilution. This novel procedure allows to determination of ruthenium without the sensitivity loss (-66%) which occurs in the alkaline media resulting from the fusion. The relative standard deviation is 1.1% for FAAS and 1.3% for UV-vis, at 5% Ru (n = 7). The detection limit (3sB) is 0.07% Ru for FAAS and 0.02% Ru for UV-vis. Both methods were applied to the analysis of a commercial sample and a statistical comparison was carried out.     

Formation of (η-R5C5)Ru(NO)X2 by the nitrosylation of (η-R5C5)Ru(CO)2X under irradiation

The ruthenium(II) complexes (η-R₅C₅)Ru(CO)₂X with R = H, CH₃ and X = Cl, Br, I undergo a facile reaction with nitric oxide under UV irradiation to afford ruthenium(IV) nitrosyl derivatives of the general type (η-R₅C₅)Ru(NO)X₂.     

Trennung der einkernigen kationischen Rutheniumnitrosylnitratokomplexe mittels tr?gerfreier Capillarisotachophorese

Zusammenfassung Mit der trägerfreien Capillarisotachophorese gelingt die Isolierung von neun Rutheniumnitrosylnitratokomplexen, darunter drei Paare von cis-trans-Isomeren. Die besten Trennungen erhält man mit einem Neun-Komponenten-Spacer, bestehend aus anorganischen und einfachen organischen Kationen. Aufgrund der Ergebnisse bietet sich die trägerfreie Durchflußisotachophorese zur präparativen Gewinnung dieser Rutheniumkomplexe an.

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Separation of the mononuclear cationic ruthenium nitrosyl nitrato complexes by carrier-free capillary isotachophoresis

Summary By carrier-free capillary isotachophoresis it is possible to isolate nine ruthenium nitrosyl nitrato complexes, among which are three pairs of cis-trans-isomers. The best separations are achieved by using a spacer containing nine components and consisting of inorganic and simple organic cations. Based on these results, carrier-free through-flow isotachophoresis is suggested for the preparative isolation of these complexes.

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Herrn Prof. Dr. H. Weisz zum 60. Geburtstag gewidmet     

Unexpected nitrosyl-group bending in six-coordinate [M(NO)](6) sigma-bonded aryl(iron) and -(ruthenium) porphyrins.

The six-coordinate nitrosyl sigma-bonded aryl(iron) and -(ruthenium) porphyrin complexes (OEP)Fe(NO)(p-C(6)H(4)F) and (OEP)Ru(NO)(p-C(6)H(4)F) (OEP = octaethylporphyrinato dianion) have been synthesized and characterized. Single-crystal X-ray structure determinations reveal an unprecedented bending and tilting of the MNO group for both [MNO](6) species as well as significant lengthening of trans axial bond distances. In (OEP)Fe(NO)(p-C(6)H(4)F) the Fe-N-O angle is 157.4(2) degrees, the nitrosyl nitrogen atom is tilted off of the normal to the heme plane by 9.2 degrees, Fe-N(NO) = 1.728(2) A, and Fe-C(aryl) = 2.040(3) A. In (OEP)Ru(NO)(p-C(6)H(4)F) the Ru-N-O angle is 154.9(3) degrees, the nitrosyl nitrogen atom is tilted off of the heme normal by 10.8 degrees, Ru-N(NO) = 1.807(3) A, and Ru-C(aryl) = 2.111(3) A. We show that these structural features are intrinsic to the molecules and are imposed by the strongly sigma-donating aryl ligand trans to the nitrosyl. Density functional-based calculations reproduce the structural distortions observed in the parent (OEP)Fe(NO)(p-C(6)H(4)F) and, combined with the results of extended Hückel calculations, show that the observed bending and tilting of the FeNO group indeed represent a low-energy conformation. We have identified specific orbital interactions that favor the unexpected bending and tilting of the FeNO group. The aryl ligand also affects the Fe-NO pi-bonding as measured by infrared and (57)Fe M?ssbauer spectroscopies. The solid-state nitrosyl stretching frequencies for the iron complex (1791 cm(-)(1)) and the ruthenium complex (1773 cm(-)(1)) are significantly reduced compared to their respective [MNO](6) counterparts. The M?ssbauer data for (OEP)Fe(NO)(p-C(6)H(4)F) yield the quadrupole splitting parameter +0.57 mm/s and the isomer shift 0.14 mm/s at 4.2 K. The results of our study show, for the first time, that bent Fe-N-O linkages are possible in formally ferric nitrosyl porphyrins.     

The nature of Ru-NO bonds in ruthenium tetraazamacrocycle nitrosyl complexes--a computational study

Ruthenium complexes including nitrosyl or nitrite complexes are particularly interesting because they can not only scavenge but also release nitric oxide in a controlled manner, regulating the NO-level in vivo. The judicious choice of ligands attached to the [RuNO] core has been shown to be a suitable strategy to modulate NO reactivity in these complexes. In order to understand the influence of different equatorial ligands on the electronic structure of the Ru-NO chemical bonding, and thus on the reactivity of the coordinated NO, we propose an investigation of the nature of the Ru-NO chemical bond by means of energy decomposition analysis (EDA), considering tetraamine and tetraazamacrocycles as equatorial ligands, prior to and after the reduction of the {RuNO}(6) moiety by one electron. This investigation provides a deep insight into the Ru-NO bonding situation, which is fundamental in designing new ruthenium nitrosyl complexes with potential biological applications.     

Immobilization of the [RuII(edta)NO+] Ion on the surface of functionalized silica gel

The reaction of NO and the immobilized dimer complex (edta)(2)Ru(2)(III(1/2),III(1/2)) on silica gel chemically modified with [3-(2-aminoethyl)aminopropyl]trimethoxysilane (AEATS) produces the corresponding immobilized nitrosyl complex AEATS/Ru(II)NO(+). This compound, a monomer, was obtained by reducing the immobilized ruthenium dimer either electrochemically or with Eu(II) and reacting this species with NO(2)(-) ions. The properties of [Ru(edta)NO](-) in solution and anchored (AEATS/Ru(II)NO(+)) on silica were compared using electrochemical (DPV, CV) and spectroscopic (IR, UV-vis, and ESR) techniques. The results indicate that immobilization does not alter the reactivity of the ruthenium complex and confirm that [Ru(edta)(H(2)O)](2)(-) may be used, either in solution or immobilized, as a catalyst for the conversion of NO(2)(-) to NO(+). Both the anchored nitrosyl complex AEATS/Ru(II)NO(+) and the [Ru(edta)NO](-) species in solution, upon one-electron reduction, liberate NO at comparable rates.     

The uptake of radioisotopes onto clays and other natural materials

The ability of natural and simulated soils to take up radioisotopes of cesium, strontium and ruthenium was examined. Uptakes were assessed by distribution coefficients measured in the presence of different concentrations of Na, Ca, Mg and HN₄ cations, and from synthetic groundwaters. Peat was included in similar studies for comparison purposes. Conclusions were drawn as to the effect of soil and ground water compositions on isotope uptake taking into account the results described in Part 1 of this series¹ which estimated the distribution coefficients for¹³⁷Cs,⁸⁹Sr and¹⁰⁶Ru (as chloride or nitrosyl) shown by illite and montmorillonite clays. These, or similar, clays were soil components in this study.     

Incorporation of a designed ruthenium nitrosyl in PolyHEMA hydrogel and light-activated delivery of NO to myoglobin

A ruthenium nitrosyl with 4-vinylpyridine (4-vpy) as one ligand, namely, [Ru(Me2bpb)(NO)(4-vpy)](BF4) (1), has been synthesized and structurally characterized. This diamagnetic {Ru-NO}6 nitrosyl is photoactive and readily releases NO upon exposure to low-intensity (5-10 mW) UV light (quantum yield at 300 nm = 0.18). Radical-induced copolymerization of 2-hydroxyethyl methacrylate (HEMA) and ethyleneglycol dimethacrylate (EGDMA) in the presence of 1 has afforded a 1-pHEMA, a transparent hydrogel in which 1 is covalently attached to the polymer backbone. Exposure of 1-pHEMA to UV light (5-10 mW) results in rapid release of NO (detected by NO electrode) that can be delivered to biological targets such as myoglobin. The photoactivity of 1-pHEMA is strictly dependent on exposure to UV light.     

Photoactive ruthenium nitrosyls derived from quinoline- and pyridine-based ligands: Accelerated photorelease of NO due to quinoline ligation

The ruthenium nitrosyl [(PaPy₂Q)Ru(NO)](BF₄)₂, derived from the quinoline-based ligand PaPy₂QH (PaPy₂QH = N,N-bis(2-pyridylmethyl)amine-N-ethyl-2-quinaldine-2-carboxamide; H = dissociable proton) has been synthesized and characterized by X-ray crystallography and spectroscopic techniques. This {Ru–NO}⁶ nitrosyl is soluble in aqueous media and stable under physiological conditions at pH 7. [(PaPy₂Q)Ru(NO)]²⁺ releases NO rapidly upon exposure to low-intensity UV light (5 mW/cm²). The NO donor capacity of this nitrosyl (quantum yield = 0.20, λ_irr = 365 nm) is considerably higher than that of analogous nitrosyl derived from a polypyridyl ligand without the quinoline moiety.