Your search keyword '"Ryabov AD"' showing total 64 results

1. The Mechanism of Formation of Active Fe-TAMLs Using HClO Enlightens Design for Maximizing Catalytic Activity at Environmentally Optimal, Circumneutral pH.

Author

Pal P, Schafer MC, Hendrich MP, Ryabov AD, and Collins TJ

Abstract

Fe-TAML/peroxide catalysis provides simple, powerful, ultradilute approaches for removing micropollutants from water. The typically rate-determining interactions of H 2 O 2 with Fe-TAMLs (rate constant k I ) are sharply pH-sensitive with rate maxima in the pH 9-10 window. Fe-TAML design or process design that shifts the maximum rates to the pH 6-8 window of most wastewaters would make micropollutant eliminations even more powerful. Here, we show how the different pH dependencies of the interactions of Fe-TAMLs with peroxide or hypochlorite to form active Fe-TAMLs ( k I step) illuminate why moving from H 2 O 2 (p K a , ca. 11.6) to hypochlorite (p K a , 7.5) shifts the pH of the fastest catalysis to as low as 8.2. At pH 7, hypochlorite catalysis is 100-1000 times faster than H 2 O 2 catalysis. The pH of maximum catalytic activity is also moderated by the p K a 's of the Fe-TAML axial water ligands, 8.8, 9.3, and 10.3, respectively, for [Fe{4-NO 2 C 6 H 3 -1,2-(NCOCMe 2 NSO 2 ) 2 CHMe}(H 2 O) n ] - ( 2 ) [ n = 1-2], [Fe{4-NO 2 C 6 H 3 -1,2-(NCOCMe 2 NCO) 2 CF 2 }(H 2 O) n ] - ( 1b ), and [Fe{C 6 H 4 -1,2-(NCOCMe 2 NCO) 2 CMe 2 }(H 2 O) n ] - ( 1a ). The new bis(sulfonamido)-bis(carbonamido)-ligated 2 exhibits the lowest p K a and delivers the largest hypochlorite over peroxide catalytic rate advantage. The fast Fe-TAML/hypochlorite catalysis is accompanied by slow noncatalytic oxidations of Orange II.

Published

2023

2. On TAML Catalyst Resting State Lifetimes: Kinetic, Mechanistic, and Theoretical Insight into Phosphate-Induced Demetalation of an Iron(III) Bis(sulfonamido)bis(amido)-TAML Catalyst.

Author

Frame HC, Shen LQ, Ryabov AD, and Collins TJ

Subjects

Oxidation-Reduction, Kinetics, Catalysis, Iron chemistry, Phosphates

Abstract

At ambient temperatures, neutral pH and ultralow concentrations (low nM), the bis(sulfonamido)bis(amido) oxidation catalyst [Fe{4-NO 2 C 6 H 3 -1,2-( N COCMe 2 N SO 2 ) 2 CHMe}(OH 2 )] - ( 1 ) has been shown to catalyze the addition of an oxygen atom to microcystin-LR. This persistent bacterial toxin can contaminate surface waters and render drinking water sources unusable when nutrient concentrations favor cyanobacterial blooms. In mechanistic studies of this oxidation, while the pH was controlled with phosphate buffers, it became apparent that iron ejection from 1 becomes increasingly problematic with increasing [phosphate] (0.3-1.0 M); 1 is not noticeably impacted at low concentrations (0.01 M). At pH < 6.5 and [phosphate] ≥ 1.0 M, 1 decays quickly, losing iron from the macrocycle. Iron ejection is surprisingly mechanistically complex; the pseudo-first-order rate constant k obs has an unusual dependence on the total phosphate concentration ([P t ]), k obs = k 1 [P t ] + k 2 [P t ] 2 , indicating two parallel pathways that are first and second order in [phosphate], respectively. The pH profiles in the 5.5-8.3 range for k 1 and k 2 are different: bell-shaped with a maximum of around pH 7 for k 1 and sigmoidal for k 2 with higher values at lower pH. Mechanistic proposals for the k 1 and k 2 pathways are detailed based on both the kinetic data and density functional theory analysis. The major difference between k 1 and k 2 is the involvement of different phosphate species, i.e., HPO 4 2- ( k 1 ) and H 2 PO 4 - ( k 2 ); HPO 4 2- is less acidic but more nucleophilic, which favors intramolecular rate-limiting Fe-N bond cleavage. Instead, H 2 PO 4 - acts intermolecularly, where the kinetics suggest that [H 4 P 2 O 8 ] 2- drives degradation.

Published

2023

3. Cyclometalated Osmium Compounds and beyond: Synthesis, Properties, Applications.

Author

Cerón-Camacho R, Roque-Ramires MA, Ryabov AD, and Le Lagadec R

Abstract

The synthesis of cyclometalated osmium complexes is usually more complicated than of other transition metals such as Ni, Pd, Pt, Rh, where cyclometalation reactions readily occur via direct activation of C-H bonds. It differs also from their ruthenium analogs. Cyclometalation for osmium usually occurs under more severe conditions, in polar solvents, using specific precursors, stronger acids, or bases. Such requirements expand reaction mechanisms to electrophilic activation, transmetalation, and oxidative addition, often involving C-H bond activations. Osmacycles exhibit specific applications in homogeneous catalysis, photophysics, bioelectrocatalysis and are studied as anticancer agents. This review describes major synthetic pathways to osmacycles and related compounds and discusses their practical applications.

Published

2021

4. The Exchange of Cyclometalated Ligands.

Author

Ryabov AD

Subjects

Ligands, Molecular Structure, Metals chemistry, Organometallic Compounds chemical synthesis, Organometallic Compounds chemistry

Abstract

Reactions of cyclometalated compounds are numerous. This account is focused on one of such reactions, the exchange of cyclometalated ligands, a reaction between a cyclometalated compound and an incoming ligand that replaces a previously cyclometalated ligand to form a new metalacycle: + H-C*~Z ⇄ + H-C~Y. Originally discovered for Pd II complexes with Y/Z = N, P, S, the exchange appeared to be a mechanistically challenging, simple, and convenient routine for the synthesis of cyclopalladated complexes. Over four decades it was expanded to cyclometalated derivatives of platinum, ruthenium, manganese, rhodium, and iridium. The exchange, which is also questionably referred to as transcyclometalation, offers attractive synthetic possibilities and assists in disclosing key mechanistic pathways associated with the C-H bond activation by transition metal complexes and C-M bond cleavage. Both synthetic and mechanistic aspects of the exchange are reviewed and discussed.

Published

2021

5. Quantifying evolving toxicity in the TAML/peroxide mineralization of propranolol.

Author

Somasundar Y, Burton AE, Mills MR, Zhang DZ, Ryabov AD, and Collins TJ

Abstract

Oxidative water purification of micropollutants (MPs) can proceed via toxic intermediates calling for procedures for connecting degrading chemical mixtures to evolving toxicity. Herein, we introduce a method for projecting evolving toxicity onto composite changing pollutant and intermediate concentrations illustrated through the TAML/H 2 O 2 mineralization of the common drug and MP, propranolol. The approach consists of identifying the key intermediates along the decomposition pathway (UPLC/GCMS/NMR/UV-Vis), determining for each by simulation and experiment the rate constants for both catalytic and noncatalytic oxidations and converting the resulting predicted concentration versus time profiles to evolving composite toxicity exemplified using zebrafish lethality data. For propranolol, toxicity grows substantially from the outset, even after propranolol is undetectable, echoing that intermediate chemical and toxicity behaviors are key elements of the environmental safety of MP degradation processes. As TAML/H 2 O 2 mimics mechanistically the main steps of peroxidase catalytic cycles, the findings may be relevant to propranolol degradation in environmental waters., Competing Interests: Y.S. and T.J.C. are coinventors on a patent for the latest generation TAML catalysts, allowed in the United States and pending elsewhere—the connection to this work is remote. T.J.C. is the Creator Founder and a Board member of Sudoc, LLC, formed to commercialize applications of the latest generation TAML catalysts. T.J.C.'s Irrevocable Family Trust is an owner of significant holdings in Sudoc, LLC—the vast majority of the Trust's future income is directed to supporting research and education in sustainability science, especially to advancing the rational handling of endocrine disrupting chemicals in our global civilization., (© 2020 The Author(s).)

Published

2020

6. Predicting Properties of Iron(III) TAML Activators of Peroxides from Their III/IV and IV/V Reduction Potentials or a Lost Battle to Peroxidase.

Author

Somasundar Y, Shen LQ, Hoane AG, Kaaret EZ, Warner GR, Ryabov AD, and Collins TJ

Subjects

Hydrogen Peroxide, Oxidation-Reduction, Iron, Peroxidases chemistry, Peroxides

Abstract

A cyclic voltammetry study of a series of iron(III) TAML activators of peroxides of several generations in acetonitrile as solvent reveals reversible or quasireversible Fe III/IV and Fe IV/V anodic transitions, the formal reduction potentials (E°') for which are observed in the ranges 0.4-1.2 and 1.4-1.6 V, respectively, versus Ag/AgCl. The slope of 0.33 for a linear E°'(IV/V) against E°'(III/IV) plot suggests that the TAML ligand system plays a bigger role in the Fe III/IV transition, whereas the second electron transfer is to a larger extent an iron-centered phenomenon. The reduction potentials appear to be a convenient tool for analysis of various properties of iron TAML activators in terms of linear free energy relationships (LFERs). The values of E°'(III/IV) and E°'(IV V -1 ) correlate 1) with the pK a values of the axial aqua ligand of iron(III) TAMLs with slopes of 0.28 and 0.06 V, respectively; 2) with the Stern-Volmer constants K SV for the quenching of fluorescence of propranolol, a micropollutant of broad concern; 3) with the calculated ionization potentials of Fe III and Fe IV TAMLs; and 4) with rate constants k I and k II for the oxidation of the resting iron(III) TAML state by H 2 O 2 and reactions of the active forms of TAMLs formed with donors of electrons S, respectively. Interestingly, slopes of log k II versus E°'(III/IV) plots are lower for fast-to-oxidize S than for slow-to-oxidize S. The log k I versus E°'(III/IV) plot suggests that the manmade TAML catalyst can never be as reactive toward H 2 O 2 as a horseradish peroxidase enzyme., (© 2020 Wiley-VCH GmbH.)

Published

2020

7. TAML- and Buffer-Catalyzed Oxidation of Picric Acid by H 2 O 2 : Products, Kinetics, DFT, and the Mechanism of Dual Catalysis.

Author

Kundu S, Shen LQ, Somasundar Y, Annavajhala M, Ryabov AD, and Collins TJ

Abstract

Studies of the oxidative degradation of picric acid (2,4,6-trinitrophenol) by H 2 O 2 catalyzed by a fluorine-tailed tetraamido macrocyclic ligand (TAML) activator of peroxides [Fe III {4,5-Cl 2 C 6 H 2 -1,2-( N COCMe 2 N CO) 2 CF 2 }(OH 2 )] - ( 2 ) in neutral and mildly basic solutions revealed that oxidative degradation of this explosive demands components of phosphate or carbonate buffers and is not oxidized in their absence. The TAML- and buffer-catalyzed oxidation is subject to severe substrate inhibition, which results in at least 1000-fold retardation of the interaction between the iron(III) resting state of 2 and H 2 O 2 . The inhibition accounts for a unique pH profile for the TAML catalysis with the highest activity at pH 7. Less aggressive TAMLs such as [Fe III {C 6 H 4 -1,2-( N COCMe 2 N CO) 2 CMe 2 }(OH 2 )] - are catalytically inactive. The roles of buffer components in modulating catalysis have been clarified through detailed kinetic investigations of the degradation process, which is first order in the concentration of 2 and shows ascending hyperbolic dependencies in the concentrations of all three participants, i.e., H 2 O 2 , picrate, and phosphate/carbonate. The reactivity trends are consistent with a mechanism involving the formation of double ([LFe III -Q] 2- ) and triple ([LFe III -{Q-H 2 PO 4 }] 3- ) associates, which are unreactive and reactive toward H 2 O 2 , respectively. The binding of phosphate converts [LFe III -Q] 2- to the reactive triple associate. Density functional theory suggests that the stability of the double associate is achieved via both Fe-O phenol binding and π-π stacking. The triple associate is an outer-sphere complex where phosphate binding occurs noncovalently through hydrogen bonds. A linear free energy relationship analysis of the reactivity of the mono-, di-, and trinitro phenols suggests that the rate-limiting step involves an electron transfer from phenolate to an oxidized ironoxo intermediate, giving phenoxy radicals that undergo further rapid oxidation that lead to eventual mineralization.

Published

2020

8. Zero-Order Catalysis in TAML-Catalyzed Oxidation of Imidacloprid, a Neonicotinoid Pesticide.

Author

Warner GR, Somasundar Y, Weng C, Akin MH, Ryabov AD, and Collins TJ

Subjects

Amides chemistry, Catalysis, Kinetics, Oxidation-Reduction, Pesticides, Coordination Complexes chemistry, Iron chemistry, Neonicotinoids chemistry, Nitro Compounds chemistry, Sulfonamides chemistry

Abstract

Bis-sulfonamide bis-amide TAML activator [Fe{4-NO 2 C 6 H 3 -1,2-(NCOCMe 2 NSO 2 ) 2 CHMe}] - (2) catalyzes oxidative degradation of the oxidation-resistant neonicotinoid insecticide, imidacloprid (IMI), by H 2 O 2 at pH 7 and 25 °C, whereas the tetrakis-amide TAML [Fe{4-NO 2 C 6 H 3 -1,2-(NCOCMe 2 NCO) 2 CF 2 }] - (1), previously regarded as the most catalytically active TAML, is inactive under the same conditions. At ultra-low concentrations of both imidacloprid and 2, 62 % of the insecticide was oxidized in 2 h, at which time the catalyst is inactivated; oxidation resumes on addition of a succeeding aliquot of 2. Acetate and oxamate were detected by ion chromatography, suggesting deep oxidation of imidacloprid. Explored at concentrations [2]≥[IMI], the reaction kinetics revealed unusually low kinetic order in 2 (0.164±0.006), which is observed alongside the first order in imidacloprid and an ascending hyperbolic dependence in [H 2 O 2 ]. Actual independence of the reaction rate on the catalyst concentration is accounted for in terms of a reversible noncovalent binding between a substrate and a catalyst, which usually results in substrate inhibition when [catalyst]≪[substrate] but explains the zero order in the catalyst when [2]>[IMI]. A plausible mechanism of the TAML-catalyzed oxidations of imidacloprid is briefly discussed. Similar zero-order catalysis is presented for the oxidation of 3-methyl-4-nitrophenol by H 2 O 2 , catalyzed by the TAML analogue of 1 without a NO 2 -group in the aromatic ring., (© 2020 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2020

9. Oxidative Catalysis by TAMLs: Obtaining Rate Constants for Non-Absorbing Targets by UV-Vis Spectroscopy.

Author

Somasundar Y, Lu IC, Mills MR, Qian LY, Olivares X, Ryabov AD, and Collins TJ

Abstract

Understanding the catalysis of oxidative reactions by TAML activators of peroxides, i. e. iron(III) complexes of tetraamide macrocyclic ligands, advocated a spectrophotometric procedure for quantifying the catalytic activity of TAMLs for colorless targets (k II ', M -1  s -1 ), which is incomparably more advantageous in terms of time, cost, energy, and ecology than NMR, HPLC, UPLC, GC-MS and other similar techniques. Dyes Orange II or Safranin O (S) are catalytically bleached by non-excessive amount of H 2 O 2 in the presence of colorless substrates (S 1 ) according to the rate law: -d[S]/dt=k I k II [H 2 O 2 ][S][TAML]/(k I [H 2 O 2 ]+k II [S]+k II '[S 1 ]). The bleaching rate is thus a descending hyperbolic function of S 1  : v=ab/(b+[S 1 ]). Values of k II ' found from a and b for phenol and propranolol with commonly used TAML [Fe III {o,o'-C 6 H 4 (NCONMe 2 CO) 2 CMe 2 } 2 (OH 2 )] + are consistent with those for S 1 (phenol, propranolol) obtained directly by UPLC. The study sends vital messages to enzymologists and environmentalists., (© 2020 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2020

10. A Synthetically Generated LFe IV OH n Complex.

Author

Weitz AC, Mills MR, Ryabov AD, Collins TJ, Guo Y, Bominaar EL, and Hendrich MP

Abstract

High-valent Fe-OH species are important intermediates in hydroxylation chemistry. Such complexes have been implicated in mechanisms of oxygen-activating enzymes and have thus far been observed in Compound II of sulfur-ligated heme enzymes like cytochrome P450. Attempts to synthetically model such species have thus far seen relatively little success. Here, the first synthetic Fe IV OH n complex has been generated and spectroscopically characterized as either [LFe IV OH] - or [LFe IV OH 2 ] 0 , where H 4 L = Me 4 C 2 (NHCOCMe 2 NHCO) 2 CMe 2 is a variant of a tetra-amido macrocyclic ligand (TAML). The steric bulk provided by the replacement of the aryl group with the -CMe 2 CMe 2 - unit in this TAML variant prevents dimerization in all oxidation states over a wide pH range, thus allowing the generation of Fe IV OH n in near quantitative yield from oxidation of the [LFe III OH 2 ] - precursor.

Published

2019

11. Structural, Mechanistic, and Ultradilute Catalysis Portrayal of Substrate Inhibition in the TAML-Hydrogen Peroxide Catalytic Oxidation of the Persistent Drug and Micropollutant, Propranolol.

Author

Somasundar Y, Shen LQ, Hoane AG, Tang LL, Mills MR, Burton AE, Ryabov AD, and Collins TJ

Subjects

Adrenergic beta-Antagonists chemistry, Catalysis, Density Functional Theory, Fluorescence, Iron chemistry, Kinetics, Models, Chemical, Oxidation-Reduction, Peroxidases chemistry, Biomimetic Materials chemistry, Coordination Complexes chemistry, Hydrogen Peroxide chemistry, Propranolol chemistry, Water Pollutants, Chemical chemistry

Abstract

TAML activators enable unprecedented, rapid, ultradilute oxidation catalysis where substrate inhibitions might seem improbable. Nevertheless, while TAML/H 2 O 2 rapidly degrades the drug propranolol, a micropollutant (MP) of broad concern, propranolol is shown to inhibit its own destruction under concentration conditions amenable to kinetics studies ([propranolol] = 50 μM). Substrate inhibition manifests as a decrease in the second-order rate constant k I for H 2 O 2 oxidation of the resting Fe III -TAML (RC) to the activated catalyst (AC), while the second-order rate constant k II for attack of AC on propranolol is unaffected. This kinetics signature has been utilized to develop a general approach for quantifying substrate inhibitions. Fragile adducts [propranolol, TAML] have been isolated and subjected to ESI-MS, florescence, UV-vis, FTIR, 1 H NMR, and IC examination and DFT calculations. Propranolol binds to Fe III -TAMLs via combinations of noncovalent hydrophobic, coordinative, hydrogen bonding, and Coulombic interactions. Across four studied TAMLs under like conditions, propranolol reduced k I 4-32-fold (pH 7, 25 °C) indicating that substrate inhibition is controllable by TAML design. However, based on the measured k I and calculated equilibrium constant K for propranolol-TAML binding, it is possible to project the impact on k I of reducing [propranolol] from 50 μM to the ultradilute regime typical of MP contaminated waters (≤2 ppb, ≤7 nM for propranolol) where inhibition nearly vanishes. Projecting from 50 μM to higher concentrations, propranolol completely inhibits its own oxidation before reaching mM concentrations. This study is consistent with prior experimental findings that substrate inhibition does not impede TAML/H 2 O 2 destruction of propranolol in London wastewater while giving a substrate inhibition assessment tool for use in the new field of ultradilute oxidation catalysis.

Published

2018

12. Bis phenylene flattened 13-membered tetraamide macrocyclic ligand (TAML) for square planar cobalt(III).

Author

Ellis WC, Ryabov AD, Fischer A, Hayden JA, Shen LQ, Bominaar EL, Hendrich MP, and Collins TJ

Abstract

The preparation, characterization, and evaluation of a cobalt(III) complex with 13-membered tetraamide macrocyclic ligand (TAML) is described. This is a square-planar (X-ray) S = 1 paramagnetic ( 1 H NMR) compound, which becomes an S = 0 diamagnetic octahedral species in excess d 5 -pyridine. Its one-electron oxidation at an electrode is fully reversible with the lowest E 1/2 value (0.66 V vs SCE) among all investigated Co III TAML complexes. The oxidation results in a neutral blue species which is consistent with a Co III /radical-cation ligand. The ease of oxidation is likely due to the two benzene rings incorporated in the ligand structure (whereas there is just one in many other Co III TAMLs). The oxidized neutral species are unexpectedly EPR silent, presumably due to the π-stacking aggregation. However, they display eight-line hyperfine patterns in the presence of excess of 4- tert -butylpyridine or 4- tert -butyl isonitrile. The EPR spectra are more consistent with the Co III /radical-cation ligand formulation rather than with a Co IV complex. Attempts to synthesize a similar vanadium complex under the same conditions as for cobalt using [V V O(OCHMe 2 ) 3 ] were not successful. TAML-free decavanadate was isolated instead., Competing Interests: Disclosure statement No potential conflict of interest was reported by the authors.

Published

2018

13. Iron(III) Ejection from a "Beheaded" TAML Activator: Catalytically Relevant Mechanistic Insight into the Deceleration of Electrophilic Processes by Electron Donors.

Author

Mills MR, Shen LQ, Zhang DZ, Ryabov AD, and Collins TJ

Abstract

Kinetic studies of the acid-induced ejection of iron(III) show that the more electron-rich tetra-amido-N macrocyclic ligand (TAML) activator [Fe III {(Me 2 CNCOCMe 2 NCO) 2 CMe 2 }OH 2 ] - (4), which does not have a benzene ring in its head component ("beheaded" TAML), is up to 1 × 10 4 times more resistant than much less electron-rich [Fe III {1,2-C 6 H 4 (NCOCMe 2 NCO) 2 CMe 2 }OH 2 ] - (1a) to the electrophilic attack. This counterintuitive increased resistance is seen in both the specific acid (k obs = k 1 [H + ]/(K + [H + ])) and phosphate general acid (k II = (k di K a1 + k tri [H + ])/(K a1 +[H + ])) demetalation pathways. Insight into this reactivity puzzle was obtained from coupling kinetic data with theoretical density functional theory modeling. First, although 1a and related complexes are six-coordinate in water, 4 has a strong tendency to repel the second aqua ligand favoring [LFe(OH 2 )] - and making appropriate the comparison of monoaqua-4 with diaqua-1a in the demetalation process. Second, dearomatization exerts a strong effect on the highest occupied molecular orbital (HOMO) energy of five-coordinate monoaqua-4, the presumed target in proton-induced demetalation, stabilizing it by ca. 51 kJ mol -1 compared with monoaqua-1a. Third, the monoaqua-4 HOMO is localized over the N-p π system of all four N donors in contrast with monoaqua-1a, where N-p π contributions from the head amides only mix with the aromatic ring π system. Fourth, addition of a second water ligand to monoaqua-1a giving [LFe(OH 2 ) 2 ] - reshapes the monoaqua-1a HOMO by shifting its entire locus from the head to the tail diamido-N section-this HOMO is by 54 kJ mol -1 less stable than the monoaqua-4 HOMO. These features provide the foundations for mechanistic conclusions concerning demetalation that (i) axial water ligands enable a favored path in the six-coordinate case of 1a, where a proton "slides" toward the Fe-N bond and (ii) early and late transition states are realized for 4 and 1a, respectively, with a larger free energy of activation for the beheaded TAML activator 4.

Published

2017

14. Targeting of High-Valent Iron-TAML Activators at Hydrocarbons and Beyond.

Author

Collins TJ and Ryabov AD

Abstract

TAML activators of peroxides are iron(III) complexes. The ligation by four deprotonated amide nitrogens in macrocyclic motifs is the signature of TAMLs where the macrocyclic structures vary considerably. TAML activators are exceptional functional replicas of the peroxidases and cytochrome P450 oxidizing enzymes. In water, they catalyze peroxide oxidation of a broad spectrum of compounds, many of which are micropollutants, compounds that produce undesired effects at low concentrations-as with the enzymes, peroxide is typically activated with near-quantitative efficiency. In nonaqueous solvents such as organic nitriles, the prototype TAML activator gave the structurally authenticated reactive iron(V)oxo units (Fe V O), wherein the iron atom is two oxidation equivalents above the Fe III resting state. The iron(V) state can be achieved through the intermediacy of iron(IV) species, which are usually μ-oxo-bridged dimers (Fe IV Fe IV ), and this allows for the reactivity of this potent reactive intermediate to be studied in stoichiometric processes. The present review is primarily focused at the mechanistic features of the oxidation by Fe V O of hydrocarbons including cyclohexane. The main topic is preceded by a description of mechanisms of oxidation of thioanisoles by Fe V O, because the associated studies provide valuable insight into the ability of Fe V O to oxidize organic molecules. The review is opened by a summary of the interconversions between Fe III , Fe IV Fe IV , and Fe V O species, since this information is crucial for interpreting the kinetic data. The highest reactivity in both reaction classes described belongs to Fe V O. The resting state Fe III is unreactive oxidatively. Intermediate reactivity is typically found for Fe IV Fe IV ; therefore, kinetic features for these species in interchange and oxidation processes are also reviewed. Examples of using TAML activators for C-H bond cleavage applied to fine organic synthesis conclude the review.

Published

2017

15. A "Beheaded" TAML Activator: A Compromised Catalyst that Emphasizes the Linearity between Catalytic Activity and pK a .

Author

Mills MR, Weitz AC, Zhang DZ, Hendrich MP, Ryabov AD, and Collins TJ

Abstract

Studies of the new tetra-amido macrocyclic ligand (TAML) activator [Fe III {(Me 2 CNCOCMe 2 NCO) 2 CMe 2 }OH 2 ] - (4) in water in the pH range of 2-13 suggest its pseudo-octahedral geometry with two nonequivalent axial H 2 O ligands and revealed (i) the anticipated basic drift of the first pK a of water to 11.38 due to four electron-donating methyl groups alongside (ii) its counterintuitive enhanced resistance to acid-induced iron(III) ejection from the macrocycle. The catalytic activity of 4 in the oxidation of Orange II (S) by H 2 O 2 in the pH range of 7-12 is significantly lower than that of previously reported TAML activators, though it follows the common rate law (v/[Fe III ] = k I k II [H 2 O 2 ][S]/(k I [H 2 O 2 ] + k II [S]) and typical pH profiles for k I and k II . At pH 7 and 25 °C the rate constants k I and k II equal 0.63 ± 0.02 and 1.19 ± 0.03 M -1 s -1 , respectively. With these new values for pK a , k I and k II establishing new high and low limits, respectively, the rate constants k I and k II were correlated with pK a values of all TAML activators. The relations log k = log k 0 + α × pK a were established with log k 0 = 13 ± 2 and 20 ± 4 and α = -1.1 ± 0.2 and -1.8 ± 0.4 for k I and k II , respectively. Thus, the reactivity of TAML activators across four generations of catalysts is predictable through their pK a values.

Published

2016

16. NaClO-Generated Iron(IV)oxo and Iron(V)oxo TAMLs in Pure Water.

Author

Mills MR, Weitz AC, Hendrich MP, Ryabov AD, and Collins TJ

Abstract

The unique properties of entirely aliphatic TAML activator [Fe III {(Me 2 CNCOCMe 2 NCO) 2 CMe 2 }OH 2 ] - (3), namely the increased steric bulk of the ligand and the unmatched resistance to the acid-induced demetalation, enables the generation of high-valent iron derivatives in pure water at any pH. An iron(V)oxo species is readily produced with NaClO at pH values from 2 to 10.6 without any observable intermediate. This is the first reported example of iron(V)oxo formed in pure water. At pH 13, iron(V)oxo is not formed and NaClO oxidizes 3 to an iron(IV)oxo derivative.

Published

2016

17. Impact of cyclometalated ruthenium(II) complexes on lactate dehydrogenase activity and cytotoxicity in gastric and colon cancer cells.

Author

Rico Bautista H, Saavedra Díaz RO, Shen LQ, Orvain C, Gaiddon C, Le Lagadec R, and Ryabov AD

Subjects

Cell Line, Tumor, Colonic Neoplasms enzymology, Colonic Neoplasms pathology, Drug Screening Assays, Antitumor, Humans, L-Lactate Dehydrogenase metabolism, Neoplasm Proteins metabolism, Stomach Neoplasms enzymology, Stomach Neoplasms pathology, Antineoplastic Agents chemical synthesis, Antineoplastic Agents chemistry, Antineoplastic Agents pharmacology, Colonic Neoplasms drug therapy, Cytotoxins chemical synthesis, Cytotoxins chemistry, Cytotoxins pharmacology, Enzyme Inhibitors chemical synthesis, Enzyme Inhibitors chemistry, Enzyme Inhibitors pharmacology, L-Lactate Dehydrogenase antagonists & inhibitors, Neoplasm Proteins antagonists & inhibitors, Ruthenium chemistry, Ruthenium pharmacology, Stomach Neoplasms drug therapy

Abstract

Lactate dehydrogenase (LDH) is a redox enzyme often overexpressed in cancer cells allowing their survival in stressful metabolic tumor environment. Ruthenium(II) complexes have been shown to impact on the activity of purified horseradish peroxidase and glucose oxidase but the physiological relevance remains unclear. In this study we investigated how ruthenium complexes impact on the activity of LDH in vitro and in cancer cells and performed a comparative study using polypyridine ruthenium(II) complex [Ru(bpy) 3 ] 2+ (1) and its structurally related cyclometalated 2-phenylpyridinato counterpart [Ru(phpy)(bpy) 2 ] + (2) (bpy=2,2'-bipyridine, phpyH=2-phenylpyridine). We show that the cytotoxicity in gastric and colon cancer cells induced by 2 is significantly higher compared to 1. The kinetic inhibition mechanisms on purified LDH and the corresponding inhibition constants K i or i 0.5 values were calculated. Though complexes 1 and 2 are structurally very similar (one Ru-C bond in 2 replaces one Ru-N bond in 1), their inhibition modes are different. Cyclometalated complex 2 behaves exclusively as a non-competitive inhibitor of LDH from rabbit muscle (LDH rm) , strongly suggesting that 2 does not interact with LDH in the vicinities of either lactate/pyruvate or NAD + /NADH binding sites. Sites of interaction of 1 and 2 with LDH rm were revealed theoretically through computational molecular docking. Inhibition of LDH activity by 2 was confirmed in cancer cells. Altogether, these results revealed an inhibition of LDH activity by ruthenium complex through a direct interaction structurally tuned by a Ru-C bond., (Copyright © 2016 Elsevier Inc. All rights reserved.)

Published

2016

18. Unifying Evaluation of the Technical Performances of Iron-Tetra-amido Macrocyclic Ligand Oxidation Catalysts.

Author

DeNardo MA, Mills MR, Ryabov AD, and Collins TJ

Abstract

The main features of iron-tetra-amido macrocyclic ligand complex (a sub-branch of TAML) catalysis of peroxide oxidations are rationalized by a two-step mechanism: Fe(III) + H2O2 → Active catalyst (Ac) (kI), and Ac + Substrate (S) → Fe(III) + Product (kII). TAML activators also undergo inactivation under catalytic conditions: Ac → Inactive catalyst (ki). The recently developed relationship, ln(S0/S∞) = (kII/ki)[Fe(III)]tot, where S0 and S∞ are [S] at time t = 0 and ∞, respectively, gives access to ki under any conditions. Analysis of the rate constants kI, kII, and ki at the environmentally significant pH of 7 for a broad series of TAML activators has revealed a 6 orders of magnitude reactivity differential in both kII and ki and 3 orders differential in kI. Linear free energy relationships linking kII with ki and kI reveal that the reactivity toward substrates is related to the instability of the active TAML intermediates and suggest that the reactivity in all three processes derives from a common electronic origin. The reactivities of TAML activators and the horseradish peroxidase enzyme are critically compared.

Published

2016

19. Activation of Dioxygen by a TAML Activator in Reverse Micelles: Characterization of an Fe(III)Fe(IV) Dimer and Associated Catalytic Chemistry.

Author

Tang LL, Gunderson WA, Weitz AC, Hendrich MP, Ryabov AD, and Collins TJ

Subjects

Catalysis, Electron Spin Resonance Spectroscopy, Hydrogen Peroxide chemistry, Molecular Structure, NAD chemistry, Oxidation-Reduction, Spectrophotometry, Ultraviolet, Spectroscopy, Mossbauer, Dimerization, Iron Compounds chemistry, Macrocyclic Compounds chemistry, Micelles, Oxygen chemistry

Abstract

Iron TAML activators of peroxides are functional catalase-peroxidase mimics. Switching from hydrogen peroxide (H2O2) to dioxygen (O2) as the primary oxidant was achieved by using a system of reverse micelles of Aerosol OT (AOT) in n-octane. Hydrophilic TAML activators are localized in the aqueous microreactors of reverse micelles where water is present in much lower abundance than in bulk water. n-Octane serves as a proximate reservoir supplying O2 to result in partial oxidation of Fe(III) to Fe(IV)-containing species, mostly the Fe(III)Fe(IV) (major) and Fe(IV)Fe(IV) (minor) dimers which coexist with the Fe(III) TAML monomeric species. The speciation depends on the pH and the degree of hydration w0, viz., the amount of water in the reverse micelles. The previously unknown Fe(III)Fe(IV) dimer has been characterized by UV-vis, EPR, and Mössbauer spectroscopies. Reactive electron donors such as NADH, pinacyanol chloride, and hydroquinone undergo the TAML-catalyzed oxidation by O2. The oxidation of NADH, studied in most detail, is much faster at the lowest degree of hydration w0 (in "drier micelles") and is accelerated by light through NADH photochemistry. Dyes that are more resistant to oxidation than pinacyanol chloride (Orange II, Safranine O) are not oxidized in the reverse micellar media. Despite the limitation of low reactivity, the new systems highlight an encouraging step in replacing TAML peroxidase-like chemistry with more attractive dioxygen-activation chemistry., Competing Interests: Notes The authors declare no competing financial interest.

Published

2015

20. Reactivity and operational stability of N-Tailed TAMLs through kinetic studies of the catalyzed oxidation of orange II by H2 O2 : synthesis and X-ray structure of an N-phenyl TAML.

Author

Warner GR, Mills MR, Enslin C, Pattanayak S, Panda C, Panda TK, Gupta SS, Ryabov AD, and Collins TJ

Abstract

Invited for the cover of this issue are Terrence J. Collins and co-workers at Carnegie Mellon University (USA) and the National Chemical Laboratory (India). The image depicts five generations of tetraamido macrocyclic ligand (TAML) activators, which are small molecule, full-functional mimics of oxidizing enzymes that arguably outperform the peroxidase enzymes they mimic. Read the full text of the article at 10.1002/chem.201406061., (© 2015 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2015

21. Reactivity and operational stability of N-tailed TAMLs through kinetic studies of the catalyzed oxidation of orange II by H2 O2 : synthesis and X-ray structure of an N-phenyl TAML.

Author

Warner GR, Mills MR, Enslin C, Pattanayak S, Panda C, Panda TK, Gupta SS, Ryabov AD, and Collins TJ

Subjects

Catalysis, Crystallography, X-Ray, Kinetics, Ligands, Models, Molecular, Oxidation-Reduction, Amides chemistry, Azo Compounds chemistry, Benzenesulfonates chemistry, Hydrogen Peroxide chemistry, Macrocyclic Compounds chemistry

Abstract

The catalytic activity of the N-tailed ("biuret") TAML (tetraamido macrocyclic ligand) activators [Fe{4-XC6 H3 -1,2-(NCOCMe2 NCO)2 NR}Cl](2-) (3; N atoms in boldface are coordinated to the central iron atom; the same nomenclature is used in for compounds 1 and 2 below), [X, R=H, Me (a); NO2 , Me (b); H, Ph (c)] in the oxidative bleaching of Orange II dye by H2 O2 in aqueous solution is mechanistically compared with the previously investigated activator [Fe{4-XC6 H3 -1,2-(NCOCMe2 NCO)2 CMe2 }OH2 ](-) (1) and the more aggressive analogue [Fe(Me2 C{CON(1,2-C6 H3 -4-X)NCO}2 )OH2 ](-) (2). Catalysis by 3 of the reaction between H2 O2 and Orange II (S) occurs according to the rate law found generally for TAML activators (v=kI kII [Fe(III) ][S][H2 O2 ]/(kI [H2 O2 ]+kII [S]) and the rate constants kI and kII at pH 7 both decrease within the series 3 b>3 a>3 c. The pH dependency of kI and kII was investigated for 3 a. As with all TAML activators studied to-date, bell-shaped profiles were found for both rate constants. For kI , the maximal activity was found at pH 10.7 marking it as having similar reactivity to 1 a. For kII , the broad bell pH profile exhibits a maximum at pH about 10.5. The condition kI ≪kII holds across the entire pH range studied. Activator 3 b exhibits pronounced activity in neutral to slightly basic aqueous solutions making it worthy of consideration on a technical performance basis for water treatment. The rate constants ki for suicidal inactivation of the active forms of complexes 3 a-c were calculated using the general formula ln([S0 ]/[S∞ ])=(kII /ki )[Fe(III) ]; here [Fe(III) ], [S0 ], and [S∞ ] are the total catalyst concentration and substrate concentration at time zero and infinity, respectively. The synthesis and X-ray characterization of 3 c are also described., (© 2015 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2015

22. Activation parameters as mechanistic probes in the TAML iron(V)-oxo oxidations of hydrocarbons.

Author

Kundu S, Thompson JV, Shen LQ, Mills MR, Bominaar EL, Ryabov AD, and Collins TJ

Subjects

Anthracenes chemistry, Kinetics, Oxidation-Reduction, Thermodynamics, Hydrocarbons chemistry, Iron chemistry

Abstract

The results of low-temperature investigations of the oxidations of 9,10-dihydroanthracene, cumene, ethylbenzene, [D10]ethylbenzene, cyclooctane, and cyclohexane by an iron(V)-oxo TAML complex (2; see Figure 1) are presented, including product identification and determination of the second-order rate constants k2 in the range 233-243 K and the activation parameters (ΔH(≠) and ΔS(≠)). Statistically normalized k2 values (log k2') correlate linearly with the C-H bond dissociation energies DC-H, but ΔH(≠) does not. The point for 9,10-dihydroanthracene for the ΔH(≠) vs. DC-H correlation lies markedly off a common straight line of best fit for all other hydrocarbons, suggesting it proceeds via an alternate mechanism than the rate-limiting C-H bond homolysis promoted by 2. Contribution from an electron-transfer pathway may be substantial for 9,10-dihydroanthracene. Low-temperature kinetic measurements with ethylbenzene and [D10]ethylbenzene reveal a kinetic isotope effect of 26, indicating tunneling. The tunnel effect is drastically reduced at 0 °C and above, although it is an important feature of the reactivity of TAML activators at lower temperatures. The diiron(IV) μ-oxo dimer that is often a common component of the reaction medium involving 2 also oxidizes 9,10-dihydroanthracene, although its reactivity is three orders of magnitude lower than that of 2., (© 2015 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2015

23. A glance at the reactivity of osma(II)cycles [Os(C-N)x(bpy)3-x](m+) (x=0-3) Covering a 1.8 V potential range toward peroxidase through Monte Carlo Simulations ((-)C-N=o-2-phenylpyridinato, bpy=2,2'-bipyridine).

Author

Cerón-Camacho R, Le Lagadec R, Kurnikov IV, and Ryabov AD

Subjects

Coordination Complexes chemical synthesis, Electrochemical Techniques, Electron Transport, Kinetics, Models, Molecular, Monte Carlo Method, Oxidation-Reduction, 2,2'-Dipyridyl chemistry, Coordination Complexes chemistry, Electrons, Horseradish Peroxidase chemistry, Osmium chemistry, Plant Proteins chemistry

Abstract

Three cyclometalated and one coordination compounds [Os(C-N)x(bpy)3-x](m) (x/m=0/2+ (4); 1/1+ (3); 2/1+ (2); 3/0 (1); (-)C-N=2-phenylpyridinato, bpy=2,2'-bipyridine) with drastically different reduction potentials have been used for analyzing the second-order rate constants for one-electron, metal-based osmium(II) to osmium(III) oxidation of the complexes by compound I (k2) and compound II (k3) of horseradish peroxidase. Previously unknown k2 and k3 have been determined by digital simulation of cyclic voltammograms measured in phosphate buffer of pH7.6 and 21 ± 1°C. Osmium(II) species derived from osmium(III) complexes 1 and 2 were generated electrochemically in situ. Under the conditions used the reduction potentials for the Os(III/II) feature equal -0.90, -0.095, 0.23 and 0.85V versus NHE (normal hydrogen electrode) for 1-4, respectively. The rate constants k2 equal ~5 × 10(7), 6 × 10(8), 2 × 10(6) and 1 × 10(5)M(-1)s(-1) and the rate constants k3 equal ~9 × 10(6), 4× 10(7), 1 ×10(6) and 1 × 10(5)M(-1)s(-1) for complexes 1-4, respectively. Both rate constants k2 and k3 first increase with increasing the reaction driving force on going from 4 to 2 but then both decrease on going to complex 1 though the reaction driving force is the highest in this case. The system described has been explored theoretically using docking Monte Carlo simulations., (Copyright © 2014 Elsevier Inc. All rights reserved.)

Published

2014

24. 2-Phenylpyridine ruthenacycles as effectors of glucose oxidase activity: inhibition by Ru(II) and activation by Ru(III).

Author

Saavedra Díaz RO, Le Lagadec R, and Ryabov AD

Subjects

Enzyme Activation, Molecular Structure, Ruthenium pharmacology, Glucose Oxidase metabolism, Pyridines chemistry, Ruthenium chemistry

Abstract

Cyclometalated Ru(II) derivatives of 2-phenylpyridine (Hphpy) [Ru(phpy)(bpy)2]Cl (1a) and [Ru(phpy)(phen)2]Cl (1b) (bpy is 2,2'-bipyridine, phen is 1,10-phenanthroline) behave as noncompetitive inhibitors of glucose oxidase from Aspergillus niger in the enzyme-catalyzed oxidation of D-glucose by O2 into the corresponding lactone at pH 5.0 and 25 °C. The enzymatic activity has been measured by monitoring the O2 consumption. The inhibition constants K i are 0.036 and 0.017 M for 1a and 1b, respectively, indicating that 1b inhibits the enzymatic activity more efficiently than 1a. The well-known coordination compound [Ru(bpy)3]Cl2 (2) behaves, in contrast, as a competitive inhibitor, with K i = 0.018 M under the same conditions. The monophasic consumption of O2 in the case of 1a, 1b, and 2 is replaced by a distinct two-phase kinetics in the presence of the cyclometalated Ru(III) compound [Ru(phpy)(bpy)2]Cl2 (3), which was obtained from 1a in the presence of a large excess of H2O2 and the iron TAML activator. Interestingly, the rates of the first and the second phases are influenced by 3 in a different way. The rate of the first phase is noticeably higher in the presence of Ru(III), although the dependence is nonmonotonic and maximal acceleration is observed at the lowest loadings of 3. The rate of the second phase decreases monotonically on increasing the concentration of the ruthenium complex in solution. The nonmonotonic action of 3 was confirmed by using the doubly cyclometalated Ru(III) derivative [Ru(phpy)2(bpy)]Cl. The diverse rate variations induced by 3 accounted for acceleration by Ru(III) of the O2 reduction by the reduced form of glucose oxidase during the first phase, which ceases after the enzymatic reduction of Ru(III) to the Ru(II) species, the latter behaving similarly to 1a as the inhibitor of the enzyme.

Published

2013

25. TAML activator/peroxide-catalyzed facile oxidative degradation of the persistent explosives trinitrotoluene and trinitrobenzene in micellar solutions.

Author

Kundu S, Chanda A, Khetan SK, Ryabov AD, and Collins TJ

Subjects

Catalysis, Hydrolysis, Oxidation-Reduction, Solutions, Surface-Active Agents chemistry, Explosive Agents chemistry, Micelles, Peroxides chemistry, Trinitrobenzenes chemistry, Trinitrotoluene chemistry

Abstract

TAML activators are well-known for their ability to activate hydrogen peroxide to oxidize persistent pollutants in water. The trinitroaromatic explosives, 2,4,6-trinitrotoluene (TNT) and 1,3,5-trinitrobenzene (TNB), are often encountered together as persistent, toxic pollutants. Here we show that an aggressive TAML activator with peroxides boosts the effectiveness of the known surfactant/base promoted breakdown of TNT and transforms the surfactant induced nondestructive binding of base to TNB into an extensive multistep degradation process. Treatment of basic cationic surfactant solutions of either TNT or TNB with TAML/peroxide (hydrogen peroxide and tert-butylhydroperoxide, TBHP) gave complete pollutant removal for both in <1 h with >75% of the nitrogen and ≥20% of the carbon converted to nitrite/nitrate and formate, respectively. For TNT, the TAML advantage is to advance the process toward mineralization. Basic surfactant solutions of TNB gave the colored solutions typical of known Meisenheimer complexes which did not progress to degradation products over many hours. However with added TAML activator, the color was bleached quickly and the TNB starting compound was degraded extensively toward minerals within an hour. A slower surfactant-free TAML activator/peroxide process also degrades TNT/TNB effectively. Thus, TAML/peroxide amplification effectively advances TNT and TNB water treatment giving reason to explore the environmental applicability of the approach.

Published

2013

26. TAML activator-based amperometric analytical devices as alternatives to peroxidase biosensors.

Author

Ryabov AD, Cerón-Camacho R, Saavedra-Díaz O, Denardo MA, Ghosh A, Le Lagadec R, and Collins TJ

Subjects

Models, Molecular, Molecular Conformation, Osmium chemistry, Ruthenium chemistry, Biosensing Techniques instrumentation, Electrochemistry instrumentation, Ferric Compounds chemistry, Horseradish Peroxidase metabolism

Abstract

The ferric TAML catalysts [Fe{C(6)H(2)-1,2-( NCOCMe(2)NCO)(2)CMe(2)}(OH(2))](-) (1) with counterions Na(+) (a) and PPh(4)(+) (b) function similar to horseradish peroxidase in the mediated electron transfer relays, which constitute a basis for amperometric biosensors. The mediators are mono- and bis-cyclometalated Ru and Os compounds of the type of [M(C∼N)(x)(N∼N)(3-x)](m+) with x = 1 and 2 (N∼N = 2,2'-bipyridine, (-)C∼N = 2-phenylpyridinato). Cyclic voltammograms of the Ru and Os compounds are not affected by 1a though cathodic currents increase drastically in the presence of hydrogen peroxide. The reduction potentials of [M(C∼N)(x)(N∼N)(3-x)](m+) complexes vary with both the nature of metal (Ru or Os) and the number of cyclometalated ligands x (1 or 2) and therefore the potential of working electrode can be set in the range of from -0.1 to +0.6 V versus the normal hydrogen electrode (NHE). A prototype of a biosensor for H(2)O(2) is described, in which the 1b catalyst and [Os(C∼N)(2)(N∼N)](+) mediator were coimmobilized on the surface of the glassy carbon electrode using a polymeric coating.

Published

2012

27. Experimental and theoretical evidence for multiple Fe(IV) reactive intermediates in TAML-activator catalysis: rationalizing a counterintuitive reactivity order.

Author

Kundu S, Annavajhala M, Kurnikov IV, Ryabov AD, and Collins TJ

Subjects

Acid-Base Equilibrium, Catalysis, Kinetics, Ligands, Oxidation-Reduction, Quantum Theory, Iron chemistry, Macrocyclic Compounds chemistry, Organometallic Compounds chemistry

Published

2012

28. On the reactivity of mononuclear iron(V)oxo complexes.

Author

Kundu S, Thompson JV, Ryabov AD, and Collins TJ

Subjects

Kinetics, Molecular Structure, Oxidation-Reduction, Iron chemistry, Organometallic Compounds chemistry, Oxygen chemistry

Abstract

Ferric tetraamido macrocyclic ligand (TAML)-based catalysts [Fe{C(6)H(4)-1,2-(NCOCMe(2)NCO)(2)CR(2)}(OH(2))]PPh(4) [1; R = Me (a), Et (b)] are oxidized by m-chloroperoxybenzoic acid at -40 °C in acetonitrile containing trace water in two steps to form Fe(V)oxo complexes (2a,b). These uniquely authenticated Fe(V)(O) species comproportionate with the Fe(III) starting materials 1a,b to give μ-oxo-(Fe(IV))(2) dimers. The comproportionation of 1a-2a is faster and that of 1b-2b is slower than the oxidation by 2a,b of sulfides (p-XC(6)H(4)SMe) to sulfoxides, highlighting a remarkable steric control of the dynamics. Sulfide oxidation follows saturation kinetics in [p-XC(6)H(4)SMe] with electron-rich substrates (X = Me, H), but changes to linear kinetics with electron-poor substrates (X = Cl, CN) as the sulfide affinity for iron decreases. As the sulfide becomes less basic, the Fe(IV)/Fe(III) ratio at the end of reaction for 2b suggests a decreasing contribution of concerted oxygen-atom transfer (Fe(V) → Fe(III)) concomitant with increasing electron transfer oxidation (Fe(V) → Fe(IV)). Fe(V) is more reactive toward PhSMe than Fe(IV) by 4 orders of magnitude, a gap even larger than that known for peroxidase Compounds I and II. The findings reinforce prior work typecasting TAML activators as faithful peroxidase mimics.

Published

2011

29. Cyclometalated [Os(C-N)x(N-N)(3-x)]m+ mimetics of tris(2,2'-bipyridine)osmium(II): covering a 2 V potential range by known (x = 0, 1) and new (x = 2, 3) species (C-N = o-2-phenylpyridinato).

Author

Cerón-Camacho R, Hernández S, Le Lagadec R, and Ryabov AD

Abstract

Electrochemical studies of [Os(C-N)(x)(N-N)(3-x)](m+) (1) consisting of known Os(II) species with x = 0 (a) and 1 (b) and crystallographically characterized new Os(III) bis- and tris-metalacycles with x = 2 (c) and 3 (d) (N-N = 2,2'-bipyridine, (-)C-N = 2-phenylpyridinato) revealed a Nernstian behavior in MeCN. A stepwise replacement of neutral N-N ligands by three anionic C-N donors covers a 2 V potential range from -1 to +1 V vs. Ag/AgCl for the Os(III)/Os(II) feature.

Published

2011

30. Thermodynamic, electrochemical, high-pressure kinetic, and mechanistic studies of the formation of oxo Fe(IV)-TAML species in water.

Author

Popescu DL, Vrabel M, Brausam A, Madsen P, Lente G, Fabian I, Ryabov AD, van Eldik R, and Collins TJ

Subjects

Catalysis, Kinetics, Potentiometry, Spectrophotometry, Ultraviolet, Thermodynamics, Ferric Compounds chemistry, Hydrogen Peroxide chemistry, Iron Compounds chemistry, Macrocyclic Compounds chemistry, Metalloporphyrins chemistry

Abstract

Stopped-flow kinetic studies of the oxidation of Fe(III)-TAML catalysts, [ F e{1,2-X(2)C(6)H(2)-4,5-( NCOCMe(2) NCO)(2)CMe(2)}(OH(2))](-) (1), by t-BuOOH and H(2)O(2) in water affording Fe(IV) species has helped to clarify the mechanism of the interaction of 1 with primary oxidants. The data collected for substituted Fe(III)-TAMLs at pH 6.0-13.8 and 17-45 °C has confirmed that the reaction is first order both in 1 and in peroxides. Bell-shaped pH profiles of the effective second-order rate constants k(I) have maximum values in the pH range of 10.5-12.5 depending on the nature of 1 and the selected peroxide. The "acidic" part is governed by the deprotonation of the diaqua form of 1 and therefore electron-withdrawing groups move the lower pH limit of the reactivity toward neutral pH, although the rate constants k(I) do not change much. The dissection of k(I) into individual intrinsic rate constants k(1) ([FeL(OH(2))(2)](-) + ROOH), k(2) ([FeL(OH(2))OH)](2-) + ROOH), k(3) ([FeL(OH(2))(2)](-) + ROO(-)), and k(4) ([FeL(OH(2))OH)](2-) + ROO(-)) provides a model for understanding the bell-shaped pH-profiles. Analysis of the pressure and substituent effects on the reaction kinetics suggest that the k(2) pathway is (i) more probable than the kinetically indistinguishable k(3) pathway, and (ii) presumably mechanistically similar to the induced cleavage of the peroxide O-O bond postulated for cytochrome P450 enzymes. The redox titration of 1 by Ir(IV) and electrochemical data suggest that under basic conditions the reduction potential for the half-reaction [Fe(IV)L(=O)(OH(2))](2-) + e(-) + H(2)O → [Fe(III)L(OH)(OH(2))](2-) + OH(-) is close to 0.87 V (vs NHE).

Published

2010

31. Designing green oxidation catalysts for purifying environmental waters.

Author

Ellis WC, Tran CT, Roy R, Rusten M, Fischer A, Ryabov AD, Blumberg B, and Collins TJ

Subjects

Animals, COS Cells, Catalysis, Chlorocebus aethiops, Kinetics, Magnetic Resonance Spectroscopy, Models, Molecular, Oxidation-Reduction, Spectrophotometry, Ultraviolet, Spectroscopy, Near-Infrared, Environmental Restoration and Remediation methods, Water Pollutants isolation & purification

Abstract

We describe the synthesis, characterization, aqueous behavior, and catalytic activity of a new generation of Fe(III)-TAML (tetraamido macrocycle ligand) activators of peroxides (2), variants of [Fe{(OC)(2)(o,o'-NC(6)H(4)NCO)(2)CMe(2)}(OH(2))(-)] (2d), which have been designed to be especially suitable for purifying water of recalcitrant oxidizable pollutants. Activation of H(2)O(2) by 2 (k(I)) as a function of pH was analyzed via kinetic studies of Orange II bleaching. This was compared with the known behavior of the first generation of Fe(III)-TAMLs (1). Novel reactivity features impact the potential for oxidant activation for water purification by 2d and its aromatic ring-substituted dinitro (2e) and tetrachloro (2f) derivatives. Thus, the maximum activity for 2e occurs at pH 9, the closest yet to the EPA guidelines for drinking water (6.5-8.5), allowing 2e to rapidly activate H(2)O(2) at pH 7.7. In water, 2e has two axial water ligands with pK(a)'s of 8.4 and 10.0 (25 degrees C). The former is the lowest for all Fe(III)-TAMLs developed to date and is key to 2e's exceptional catalytic activity in neutral and slightly basic solutions. Below pH 7, 2d was found to be quite sensitive to demetalation in phosphate buffers. This was overcome by iterative design to give 2e (hydrolysis rate 2d > 100 x 2e). Mechanistic studies highlight 2e's increased stability by establishing that to demetalate 2e at a comparable rate to which H(2)PO(4)(-) demetalates 2d, H(3)PO(4) is required. A critical criterion for green catalysts for water purification is the avoidance of endocrine disruptors, which can impair aquatic life. Fe(III)-TAMLs do not alter transcription mediated by mammalian thyroid, androgen, or estrogen hormone receptors, suggesting that 2 do not bind to the receptors and reducing concerns that the catalysts might have endocrine disrupting activity.

Published

2010

32. Design of more powerful iron-TAML peroxidase enzyme mimics.

Author

Ellis WC, Tran CT, Denardo MA, Fischer A, Ryabov AD, and Collins TJ

Subjects

Azo Compounds chemistry, Benzenesulfonates chemistry, Catalysis, Hydrogen-Ion Concentration, Iron Compounds chemical synthesis, Macrocyclic Compounds chemical synthesis, Models, Chemical, Models, Molecular, Oxidation-Reduction, Water Pollutants, Chemical chemistry, Water Purification, Biomimetics, Hydrogen Peroxide chemistry, Iron Compounds chemistry, Macrocyclic Compounds chemistry, Peroxidase chemistry

Abstract

Environmentally useful, small molecule mimics of the peroxidase enzymes must exhibit very high reactivity in water near neutral pH. Here we describe the design and structural and kinetic characterization of a second generation of iron(III)-TAML activators with unprecedented peroxidase-mimicking abilities. Iterative design has been used to remove the fluorine that led to the best performers in first-generation iron-TAMLs. The result is a superior catalyst that meets a green chemistry objective by being comprised exclusively of biochemically common elements. The rate constants for bleaching at pH 7, 9, and 11 of the model substrate, Orange II, shows that the new Fe(III)-TAML has the fastest reactivity at pH's closer to neutral of any TAML activator to date. Under appropriate conditions, the new catalyst can decolorize Orange II without loss of activity for at least 10 half-lives, attesting to its exceptional properties as an oxidizing enzyme mimic.

Published

2009

33. The impact of surfactants on Fe(III)-TAML-catalyzed oxidations by peroxides: accelerations, decelerations, and loss of activity.

Author

Banerjee D, Apollo FM, Ryabov AD, and Collins TJ

Abstract

Iron(III) complexes of tetraamidato macrocyclic ligands (TAMLs), [Fe{4-XC(6)H(3)-1,2-(NCOCMe(2)NCO)(2)CR(2)}(OH(2))](-), 1 (1 a: X = H, R = Me; 1 b: X = COOH, R = Me); 1 c: X = CONH(CH(2))(2)COOH, R = Me; 1 d: CONH(CH(2))(2)NMe(2), R = Me; 1 e: X = CONH(CH(2))(2)NMe(3) (+), R = Me; 1 f: X = H, R = F), have been tested as catalysts for the oxidative decolorization of Orange II and Sudan III dyes by hydrogen peroxide and tert-butyl hydroperoxide in the presence of micelles that are neutral (Triton X-100), positively charged (cetyltrimethylammonium bromide, CTAB), and negatively charged (sodium dodecyl sulfate, SDS). The previously reported mechanism of catalysis involves the formation of an oxidized intermediate from 1 and ROOH (k(I)) followed by dye bleaching (k(II)). The micellar effects on k(I) and k(II) have been separately studied and analyzed by using the Berezin pseudophase model of micellar catalysis. The largest micellar acceleration in terms of k(I) occurs for the 1 a-tBuOOH-CTAB system. At pH 9.0-10.5 the rate constant k(I) increased by approximately five times with increasing CTAB concentration and then gradually decreased. There was no acceleration at higher pH, presumably owing to the deprotonation of the axial water ligand of 1 a in this pH range. The k(I) value was only slightly affected by SDS (in the oxidation of Orange II), but was strongly decelerated by Triton X-100. No oxidation of the water-insoluble, hydrophobic dye Sudan III was observed in the presence of the SDS micelles. The k(II) value was accelerated by cationic CTAB micelles when the hydrophobic primary oxidant tert-butyl hydroperoxide was used. It is hypothesized that tBuOOH may affect the CTAB micelles and increase the binding of the oxidized catalysts. The tBuOOH-CTAB combination accelerated both of the catalysis steps k(I) and k(II).

Published

2009

34. Kinetic and theoretical comprehension of diverse rate laws and reactivity gaps in Coriolus hirsutus laccase-catalyzed oxidation of acido and cyclometalated Ru(II) complexes.

Author

Kurzeev SA, Vilesov AS, Fedorova TV, Stepanova EV, Koroleva OV, Bukh C, Bjerrum MJ, Kurnikov IV, and Ryabov AD

Subjects

Catalytic Domain, Kinetics, Laccase chemistry, Molecular Conformation, Monte Carlo Method, Organometallic Compounds chemistry, Oxidation-Reduction, Biocatalysis, Laccase metabolism, Models, Molecular, Organometallic Compounds metabolism, Ruthenium chemistry, Ruthenium metabolism, Trametes enzymology

Abstract

The reactivity of the acido Ru(II) complexes cis-[RuCl(2)(LL)(2)], [RuCO(3)(LL)(2)], cis-[RuCO(3)-(bquin)(2)] (LL = 2,2'-bipyridine (bpy) and 1,10-phenanthroline (phen); bquin = 2,2'-biquinoline) and cyclometalated Ru(II) derivatives of 2-phenylpyridine and 4-(2-tolyl)pyridine [Ru(o-C(6)H(4)-2-py)(phen)(2)]PF(6) (1), [Ru(o-C(6)H(3)-p-R-2-py)(bpy)(MeCN)(2)]PF(6) (2), and [Ru(o-C(6)H(3)-p-R-2-py)(phen)(MeCN)(2)]PF(6) (3) (R = H (a), Me (b)) toward laccase from Coriolus hirsutus has been investigated by conventional UV-vis spectroscopy at pH 3-7 and 25 degrees C. The acido and cyclometalated complexes are readily oxidized into the corresponding Ru(III) species, but the two types of complexes differ substantially in reactivity and obey different rate laws. The acido complexes are oxidized more slowly and the second-order kinetics, first-order in laccase and Ru(II), holds with the rate constants around 5 x 10(4) M(-1) s(-1) at pH 4.5 and 25 degrees C. The cyclometalated complexes 1-3 react much faster and the hyperbolic Michaelis-Menten kinetics holds. However, it is not due to formation of an enzyme-substrate complex but rather because of the ping-pong mechanism of catalysis, viz. E(ox) + Ru(II) --> E(red) + Ru(III) (k(1)); E(red) + 1/4O(2) --> E(ox) (k(2)), with the rate constants k(1) in the range (2-9) x 10(7) M(-1) s(-1) under the same conditions. The huge values of k(1) move the enzymatic oxidation toward a kinetic regime when the dioxygen half-reaction becomes the rate-limiting step. Cyclometalated compounds 1-3 can therefore be used for routine estimation of k(2), that is, the rate constant for reoxidation for laccases by dioxygen. The mechanism proposed was confirmed by the direct stopped-flow measurements of the k(2) rate constant (8.1 x 10(5) M(-1) s(-1) at 26 degrees C) and supported by the theoretical modeling of interaction between the bpy analogue of 1 and Coriolus hirsutes laccase using Monte Carlo simulations.

Published

2009

35. Catalase-peroxidase activity of iron(III)-TAML activators of hydrogen peroxide.

Author

Ghosh A, Mitchell DA, Chanda A, Ryabov AD, Popescu DL, Upham EC, Collins GJ, and Collins TJ

Subjects

Carbocyanines chemistry, Hydrogen-Ion Concentration, Kinetics, Metalloporphyrins chemistry, Oxidation-Reduction, Ruthenium chemistry, Catalase chemistry, Ferric Compounds chemistry, Hydrogen Peroxide chemistry, Iron Compounds chemistry, Macrocyclic Compounds chemistry, Peroxidase chemistry

Abstract

Exceptionally high peroxidase-like and catalase-like activities of iron(III)-TAML activators of H 2O 2 ( 1: Tetra-Amidato-Macrocyclic-Ligand Fe (III) complexes [ F e{1,2-X 2C 6H 2-4,5-( NCOCMe 2 NCO) 2CR 2}(OH 2)] (-)) are reported from pH 6-12.4 and 25-45 degrees C. Oxidation of the cyclometalated 2-phenylpyridine organometallic complex, [Ru (II)( o-C 6H 4py)(phen) 2]PF 6 ( 2) or "ruthenium dye", occurs via the equation [ Ru II ] + 1/2 H 2 O 2 + H +-->(Fe III - TAML) [ Ru III ] + H 2 O, following a simple rate law rate = k obs (per)[ 1][H 2O 2], that is, the rate is independent of the concentration of 2 at all pHs and temperatures studied. The kinetics of the catalase-like activity (H 2 O 2 -->(Fe III - TAML) H 2 O + 1/2 O 2) obeys a similar rate law: rate = k obs (cat)[ 1][H 2O 2]). The rate constants, k obs (per) and k obs (cat), are strongly and similarly pH dependent, with a maximum around pH 10. Both bell-shaped pH profiles are quantitatively accounted for in terms of a common mechanism based on the known speciation of 1 and H 2O 2 in this pH range. Complexes 1 exist as axial diaqua species [FeL(H 2O) 2] (-) ( 1 aqua) which are deprotonated to afford [FeL(OH)(H 2O)] (2-) ( 1 OH) at pH 9-10. The pathways 1 aqua + H 2O 2 ( k 1), 1 OH + H 2O 2 ( k 2), and 1 OH + HO 2 (-) ( k 4) afford one or more oxidized Fe-TAML species that further rapidly oxidize the dye (peroxidase-like activity) or a second H 2O 2 molecule (catalase-like activity). This mechanism is supported by the observations that (i) the catalase-like activity of 1 is controllably retarded by addition of reducing agents into solution and (ii) second order kinetics in H 2O 2 has been observed when the rate of O 2 evolution was monitored in the presence of added reducing agents. The performances of the 1 complexes in catalyzing H 2O 2 oxidations are shown to compare favorably with the peroxidases further establishing Fe (III)-TAML activators as miniaturized enzyme replicas with the potential to greatly expand the technological utility of hydrogen peroxide.

Published

2008

36. Mechanistically inspired design of Fe(III)-TAML peroxide-activating catalysts.

Author

Popescu DL, Chanda A, Stadler MJ, Mondal S, Tehranchi J, Ryabov AD, and Collins TJ

Subjects

Catalysis, Hydrogen Peroxide chemistry, Hydrogen-Ion Concentration, Kinetics, Models, Molecular, Ferric Compounds chemistry, Lactams, Macrocyclic chemistry, Peroxides chemistry

Abstract

Recent broad-ranging mechanistic studies of FeIII-TAML peroxide activators enable a strategy for designing catalysts with improved (i) hydrolytic and (ii) operational stabilities, (iii) faster activation of H2O2 and other peroxides, and (iv) a pH of highest activity closer to 7. Combining all items of insight leads to [Fe{1-NO2C6H3-3,4-(NCOCMe2NCO)2CF2}(OH2)]- (1a) which exhibits the most desirable technical performance in its class.

Published

2008

37. Easy access to bio-inspired osmium(II) complexes through electrophilic intramolecular C(sp2)-H bond cyclometalation.

Author

Cerón-Camacho R, Morales-Morales D, Hernandez S, Le Lagadec R, and Ryabov AD

Subjects

Aniline Compounds chemistry, Aspergillus niger enzymology, Benzylamines chemistry, Binding Sites, Crystallography, X-Ray, Electrochemistry, Electron Transport, Glucose Oxidase chemistry, Glucose Oxidase metabolism, Hydrogen Bonding, Pyridines chemistry, Carbon chemistry, Electrons, Hydrogen chemistry, Organometallic Compounds chemistry, Osmium chemistry

Abstract

Mild electrophilic C(sp2)-H cyclometalation of 2-phenylpyridine and N,N-dimethylbenzylamine by the chloro-bridged osmium(II) dimer [OsCl(micro-Cl)(eta6-C6H6)]2 in acetonitrile affords cyclometalated pseudotetrahedral OsII complexes [Os(C approximately N)(eta6-C6H6)(NCMe)]PF6 (C approximately N=o-C6H4py-kappa C,N (2) and o-C6H4CH2NMe2-kappa C,N (5), respectively) in good to excellent yields. The cyclometalation reactions are super sensitive to the nature of an external base. Sodium hydroxide is essential for cyclometalation of 2-phenylpyridine, but NaOH retards metalation of N,N-dimethylbenzylamine, the tertiary amine being self-sufficient as a base. Further reactions of compounds 2 and 5 with 1,10-phenanthroline or 2,2'-bipyridine (N approximately N) lead to the substitution of the eta6-bound benzene to produce octahedral species [Os(C approximately N)(N approximately N)(NCMe)2]PF6 or [Os(C approximately N)(N approximately N)2]PF6 in MeCN or MeOH as solvent, respectively. The cis configuration of the MeCN ligands in [Os(C approximately N)(phen)(NCMe)2]PF6 has been confirmed by an X-ray crystallographic study. Electrochemical investigation of the octahedral osma(II)cycles by cyclic voltammetry showed a pseudoreversible MIII/II redox feature at (-50)-(+109) and 190-300 mV versus Ag/AgCl in water and MeCN, respectively. As a possible application of the compounds, a rapid electron exchange between the reduced active site of glucose oxidase enzyme from Aspergillus niger and the electrochemically generated OsIII species has been demonstrated. The corresponding second-order rate constants cover the range (0.7-4.8)x10(6) M(-1) s(-1) at 25 degrees C and pH 7.

Published

2008

38. Attaining control by design over the hydrolytic stability of Fe-TAML oxidation catalysts.

Author

Polshin V, Popescu DL, Fischer A, Chanda A, Horner DC, Beach ES, Henry J, Qian YL, Horwitz CP, Lente G, Fabian I, Münck E, Bominaar EL, Ryabov AD, and Collins TJ

Subjects

Azides chemistry, Carboxylic Acids chemistry, Catalysis, Crystallography, X-Ray, Hydrogen-Ion Concentration, Hydrolysis, Imidazoles chemistry, Kinetics, Ligands, Models, Chemical, Models, Molecular, Molecular Conformation, Oxidation-Reduction, Phosphates chemistry, Pyridines chemistry, Stereoisomerism, Thermodynamics, Water chemistry, Amides chemistry, Ferric Compounds chemical synthesis, Ferric Compounds chemistry, Macrocyclic Compounds chemical synthesis, Macrocyclic Compounds chemistry

Abstract

The iron(III) complexes of tetra amidato macrocyclic ligands (TAMLs) ([Fe{1-X1-2-X2C6H2-4,5-(NCOCMe2NCO)2CR2}(OH2)]- , 1: X1 = X2 = H, R2 = Me2 (a), R2 = (CH2)2 (b); X1 = X2 = Cl, R2 = F2 (c), etc.), which the proton is known to demetalate at pH < 3, are also subject to catalyzed demetalation by Brønsted acid buffer components at pH 4-9 such as H2PO4-, HSO3-, and CH3CO2H, HO2CCH2CO2-. Buffers based on pyridine (py) and tris(hydroxymethyl)aminomethane (TRIS) are catalytically inactive. Where reactions proceed, the products are demetalated TAMLs and iron species of variable composition. Pseudo-first-order rate constants for the demetalation (kobs) are linear functions of the acid concentrations, and the effective second-order rate constants k1,eff have a hyperbolic dependence on [H+] (k1,eff = a1[H+]/(b1+[H+]). The rate of demetalation of 1a in H2PO4-/HPO42- buffer is appreciable, but the kobs values for 1b and 1c are immeasurably low, showing that the rates are strongly affected by the CR2 or "tail" fragments, which are known to potently affect the TAML basicity. The reactivities of 1 depend insignificantly on the aromatic ring or "head" group of 1. The proposed mechanism involves precoordination of the acidic buffer species followed by hydrolysis. The demetalating abilities of buffer species depend on their structures and acidities. Thus, although pyridine-2-carboxylic (picolinic) acid catalyzes the demetalation, its 3- and 4-isomers (nicotinic and isonicotininc acids) are inactive. The difference is rationalized to result from the ability that only coordinated picolinic acid has to deliver a proton to an amidato nitrogen in an intramolecular manner. The reaction order in picolinic acid equals one for 1a and two for 1b. For 1b, "inactive" pyridine and nicotinic acid speed up the demetalation in the presence of picolinic acid, suggesting that the second order arises from the axial binding of two pyridine molecules, one of which must be picolinic acid. The binding of pyridine- and imidazole-type ligands was confirmed by UV/vis equilibrium measurements and X-ray crystallography. The implications of these mechanistic findings for designing superior Fe-TAML oxidation catalysts and catalyst formulations are discussed using the results of DFT calculations.

Published

2008

39. Activity-stability parameterization of homogeneous green oxidation catalysts.

Author

Chanda A, Ryabov AD, Mondal S, Alexandrova L, Ghosh A, Hangun-Balkir Y, Horwitz CP, and Collins TJ

Abstract

Small-molecule synthetic homogeneous-oxidation catalysts are normally poorly protected from self-destruction under operating conditions. Achieving design control over both activity and half-life is important not only in advancing the utility of oxidation catalysts, but also in minimizing hazards associated with their use and disposal. Iron(III)-TAML (tetraamido-macrocyclic ligand) oxidant catalysts rapidly activate H(2)O(2) for numerous significant processes, exhibiting high and differing activity and varying half-lives depending upon the TAML design. A general approach is presented that allows for the simultaneous determination of the second-order rate constant for the oxidation of a targeted substrate by the active catalyst (k(II)) and the rate constant for the intramolecular self-inactivation of the active catalyst (k(i)). The approach is valid if the formation of the active catalyst from its resting state and the primary oxidizing agent, measured by the second-order rate constant k(I), is fast and the catalyst concentration is very low, such that bimolecular inactivation pathways can be neglected. If the oxidation process is monitored spectrophotometrically and is set up to be incomplete, the kinetic trace can be analyzed by using the equation ln(lnA(t))/A(infnity)=ln(k(II)/k(i)[Fe(III)](tot)-k(i)t, from which k(II) and k(i) can be determined. Here, A(t) and A(infinity) are absorbances at time t and at the end of reaction (t=infinity), respectively, and [Fe(III)](tot) is the total catalyst concentration. Several tools were applied to examine the validity of the approach by using a variety of different Fe(III)-TAML catalysts, H(2)O(2) and tBuOOH as oxidizing agents, and the dyes safranine O and orange II as target substrates. Learning how catalyst activities (k(II)) and catalyst half-lives (k(i)) can be controlled by ligand design is an important step in creating green catalysts that will not persist in the environment after they have achieved their purpose.

Published

2006

40. High-valent iron complexes with tetraamido macrocyclic ligands: structures, Mössbauer spectroscopy, and DFT calculations.

Author

Chanda A, Popescu DL, Tiago de Oliveira F, Bominaar EL, Ryabov AD, Münck E, and Collins TJ

Subjects

Ligands, Models, Chemical, Models, Molecular, Oxidation-Reduction, Spectroscopy, Mossbauer, Structure-Activity Relationship, Iron chemistry, Macrocyclic Compounds chemistry

Abstract

Iron complexes of tetraamido macrocyclic ligands (TAML) are unique synthetic oxidation catalysts. In general, the central Fe(III) ion (S=3/2) is surrounded by four, almost planar, deprotonated amide-N sigma-donors although the full suite with new generation systems includes some substitution of amides with related donor functionalities. Oxidation under different conditions affords a variety of high-valent forms of iron-TAMLs. This review provides a summary and discussion of structural and spectroscopic features of complexes oxidized by one equivalent above the ferric state. These comprise Fe(IV)-TAML high spin (S=2) and intermediate spin (S=1) systems, wherein the oxidation equivalent can be taken from the metal (Fe(IV)) or the ligand (TAML radical-cation Fe(III)), and coupled spin (S=0) systems of mu-oxoiron(IV) dimers. The discussion is principally based on data obtained by X-ray crystallography, Mössbauer spectroscopy, and density functional theory calculations.

Published

2006

41. Kinetic and thermodynamic aspects of the regioselective addition of bifunctional hydroxylaminooxime-type HO-nucleophiles to Pt-complexed nitriles.

Author

Luzyanin KV, Kukushkin VY, Kuznetsov ML, Ryabov AD, Galanski MS, Haukka M, Tretyakov EV, Ovcharenko VI, Kopylovich MN, and Pombeiro AJ

Abstract

The coupling between coordinated propiononitriles in trans-[PtCln(EtCN)2] (n = 2, 4) and the 1,2-hydroxylaminooximes HON(H)CMe2C(R)=NOH (R = Ph 1, Me 2) proceeds smoothly in CHCl(3) at ca. 40-45 degrees C and gives trans-[PtCln{NH=C(Et)ON(H)CMe2C(R)=NOH}2] (n = 2, R = Ph 5, Me 6; n = 4, R = Ph 7, Me 8) in 80-85% isolated yields. The reaction is highly regioselective, and both spectroscopic (IR; FAB+-MS; 1D 1H, 13C{1H}, and 195Pt NMR; and 2D 1H,13C HMQC, 1H,13C HMBC, and 1H,15N HMQC NMR) and X-ray data for 6-8 suggest that the addition proceeds exclusively via the hydroxylamine moiety of the 1,2-hydroxylaminooxime species; the existence of an oxime group remote from the nucleophile was also confirmed. Heating of 6 in air leads to its conversion to the unusual nitrosoalkane complex [PtCl2{HON=C(Me)C(Me)2N=O}] (9), whereas in the case of 5, only the metal-free salt [H3NC(Me)2C(Ph)=NOH]2(NO3)Cl.H2O (10) was isolated. To compare the kinetic aspects and trends in the addition of both types of nucleophiles (oximes and hydroxylamines; for the latter, see our recent work: Inorg. Chem. 2005, 44, 2944) to coordinated nitriles, a kinetic study of the addition of HON=C(CH2Ph)2 to [Ph3PCH2Ph][PtCl5(EtCN)] (11) to give [Ph(3)PCH(2)Ph][PtCl(5){NH=C(Et)ON=C(CH2Ph)2}] (12) was performed. The calculated rate constant k2 of 3.9 x 10(-6) M(-1) s(-1) at -20 degrees C for the addition of the oxime indicates that the hydroxylamine is, by a factor 1.7 x 10(4), more reactive toward the addition to nitriles than the oxime. Results of the synthetic, kinetic, and theoretical (at the B3LYP level of theory) studies have demonstrated that the high regioselectivity of the reactions of the 1,2-hydroxylaminooximes with ligated nitriles is both kinetically and thermodynamically controlled.

Published

2006

42. Kinetic and mechanistic study of the Pt(II) versus Pt(IV) effect in the platinum-mediated nitrile-hydroxylamine coupling.

Author

Luzyanin KV, Kukushkin VY, Ryabov AD, Haukka M, and Pombeiro AJ

Abstract

The metal-mediated coupling between coordinated EtCN in the platinum(II) and platinum(IV) complexes cis- and trans-[PtCl(2)(EtCN)(2)], trans-[PtCl(4)(EtCN)(2)], a mixture of cis/trans-[PtCl(4)(EtCN)(2)] or [Ph(3)PCH(2)Ph][PtCl(n)(EtCN)] (n = 3, 5), and dialkyl- and dibenzylhydroxylamines R(2)NOH (R = Me, Et, CH(2)Ph, CH(2)C(6)H(4)Cl-p) proceeds smoothly in CH(2)Cl(2) at 20-25 degrees C and the subsequent workup allowed the isolation of new imino species [PtCl(n){NH=C(Et)ONR(2)}(2)] (n = 2, R = Me, cis-1 and trans-1; Et, cis-2 and trans-2; CH(2)Ph, cis-3 and trans-3; CH(2)C(6)H(4)Cl-p, cis-4 and trans-4; n = 4, R = Me, trans-9; Et, trans-10; CH(2)Ph, trans-11; CH(2)C(6)H(4)Cl-p, trans-12) or [Ph(3)PCH(2)Ph][PtCl(n){NH=C(Et)ONR(2)}] (n = 3, R = Me, 5; Et, 6; CH(2)Ph, 7; CH(2)C(6)H(4)Cl-p, 8; n = 5, R = Me, 13; Et, 14; CH(2)Ph, 15; CH(2)C(6)H(4)Cl-p, 16) in excellent to good (95-80%) isolated yields. The reduction of the Pt(IV) complexes 9-16 with the ylide Ph(3)P=CHCO(2)Me allows the synthesis of Pt(II) species 1-8. The compounds 1-16 were characterized by elemental analyses (C, H, N), FAB-MS, IR, (1)H, (13)C{(1)H}, and (31)P{(1)H} NMR (the latter for the anionic type complexes 5-8 and 13-16) and by X-ray crystallography for the Pt(II) (cis-1, cis-2, and trans-4) and Pt(IV) (15) species. Kinetic studies of addition of R(2)NOH (R = CH(2)C(6)H(4)Cl-p) to complexes [Ph(3)PCH(2)Ph][Pt(II)Cl(3)(EtCN)] and [Ph(3)PCH(2)Ph][Pt(IV)Cl(5)(EtCN)] by the (1)H NMR technique revealed that both reactions are first order in (p-ClC(6)H(4)CH(2))(2)NOH and Pt(II) or Pt(IV) complex, the second-order rate constant k(2) being three orders of magnitude larger for the Pt(IV) complex. The reactions are intermolecular in nature as proved by the independence of k(2) on the concentrations of added EtC triple bond N and Cl(-). These data and the calculated values of Delta H++ and Delta S++ are consistent with the mechanism involving the rate-limiting nucleophilic attack of the oxygen of (p-ClC(6)H(4)CH(2))(2)NOH at the sp-carbon of the C triple bond N bond followed by a fast proton migration.

Published

2005

43. Synthesis, characterization, and electrochemistry of biorelevant photosensitive low-potential orthometalated ruthenium complexes.

Author

Ryabov AD, Le Lagadec R, Estevez H, Toscano RA, Hernandez S, Alexandrova L, Kurova VS, Fischer A, Sirlin C, and Pfeffer M

Abstract

Redox potentials of photosensitive cyclometalated RuII derivatives of 2-phenylpyridine or 2-(4-tolyl)pyridine are controllably decreased by up to 0.8 V within several minutes. This is achieved by irradiation of the ruthena(II)cycles cis-[Ru(o-X-2-py)(LL)(MeCN)2]PF6 (2, X = C6H4 (a) or 4-MeC6H3 (b), LL = 1,10-phenanthroline or 2,2'-bipyridine). The cis geometry of the MeCN ligands has been confirmed by the X-ray structural studies. The sigma-bound sp2 carbon of the metalated ring is trans to LL nitrogen. Complexes 2 are made from [Ru(o-X-2-py)(MeCN)4]PF6 (1) and LL. This "trivial" ligand substitution is unusual because 1a reacts readily with phen in MeCN as solvent to give cis-[Ru(o-C6H4-2-py)(phen)(MeCN)2]PF6 (2c) in a 83% yield, but bpy does not afford the bpy-containing 2 under the same conditions. cis-[Ru(o-C6H4-2-py)(bpy)(MeCN)2]PF6 (2e) has been prepared in CH2Cl2 (74%). Studies of complexes 2c,e by cyclic voltammetry in MeOH in the dark reveal RuII/III quasy-reversible redox features at 573 and 578 mV (vs Ag/AgCl), respectively. A minute irradiation 2c and 2e converts them into new species with redox potentials of -230 and 270 mV, respectively. An exceptional potential drop for 2c is accounted for in terms of a photosubstitution of both MeCN ligands by methanol. ESR, 1H NMR, and UV-vis data indicate that the primary product of photolysis of 2c is an octahedral monomeric low-spin (S = 1/2) RuIII species, presumably cis-[RuIII(o-C6H4-2-py)(phen)(MeOH)2]2+. The primary photoproduct of bpy complex 2e is cis-[RuII(o-C6H4-2-py)(bpy)(MeCN)(MeOH)]+, and this accounts for a lower decrease in the redox potential. Irradiation of 2c in the presence of added chloride affords [(phen)(o-C6H4-2-py)ClRuIIIORuIVCl(o-C6H4-2-py)(phen)]PF6, a first mu-oxo-bridged mixed valent dimer with a cyclometalated unit. The structure of the dimer has been established by X-ray crystallography.

Published

2005

44. Catalytically active mu-Oxodiiron(IV) oxidants from Iron(III) and dioxygen.

Author

Ghosh A, Tiago de Oliveira F, Yano T, Nishioka T, Beach ES, Kinoshita I, Münck E, Ryabov AD, Horwitz CP, and Collins TJ

Abstract

The reaction between an Fe(III) complex and O(2) to afford a stable catalytically active diiron(IV)-mu-oxo compound is described. Phosphonium salts of orange five-coordinated Fe(III)-TAML complexes with an axial aqua ligand ([PPh(4)]1-H(2)O, tetraamidato macrocyclic Fe(III) species derived from 3,3,6,6,9,9-hexamethyl-3,4,8,9-tetrahydro-1H-1,4,8,11-benzotetraazacyclotridecine-2,5,7,10(6H,11H)-tetraone) react rapidly with O(2) in CH(2)Cl(2) or other weakly coordinating solvents to produce black mu-oxo-bridged diiron(IV) complexes, 2, in high yields. Complexes 2 have been characterized by X-ray crystallography (2 cases), microanalytical data, mass spectrometry, UV/Vis, Mossbauer, and (1)H NMR spectroscopies. Mossbauer data show that the diamagnetic Fe-O-Fe unit contains antiferromagnetically coupled S = 1 Fe(IV) sites; diamagnetic (1)H NMR spectra are observed. The oxidation of PPh(3) to OPPh(3) by 2 was confirmed by UV/Vis and GC-MS. Labeling experiments with (18)O(2) and H(2)(18)O established that the bridging oxygen atom of 2 derives from O(2). Complexes 2 catalyze the selective oxidation of benzylic alcohols into the corresponding aldehydes and bleach rapidly organic dyes, such as Orange II in MeCN-H(2)O mixtures; reactivity evidence suggests that free radical autoxidation is not involved. This work highlights a promising development for the advancement of green oxidation technology, as O(2) is an abundant, clean, and inexpensive oxidizing agent.

Published

2005

45. Redox mediation and photomechanical oscillations involving photosensitive cyclometalated Ru(II) complexes, glucose oxidase, and peroxidase.

Author

Ryabov AD, Kurova VS, Ivanova EV, Le Lagadec R, and Alexandrova L

Subjects

Biosensing Techniques, Catalysis, Computer Simulation, Electron Transport, Oxidation-Reduction, Photochemistry, Glucose Oxidase metabolism, Horseradish Peroxidase metabolism, Ruthenium Compounds chemistry

Abstract

Intact photosensitive cyclometalated RuII derivatives of 2-phenylpyridine or N,N-dimethylbenzylamine cis-[Ru-(C approximately N)(LL)X2]PF6 [C approximately N = o-C6H4-py or o-C6H4CH2NMe2; LL = 1,10-phenanththroline (phen), 2,2'-bipyridine (bpy), or 4,4'-Me2-2,2'-bipyridine (Me2bpy); X = MeCN or pyridine (py)] are efficient mediators of glucose oxidase (GO) from Aspergillus niger and horseradish peroxidase (HRP). Their redox potentials in an aqueous buffer are in the range 0.15-0.35 V versus SCE, and the rate constants for the oxidation GO(red) (where red indicates reduced) by the electrochemically generated RuIII species equal (1.7-2.5) x 10(6) M(-1) s(-1) at pH 7 and 25 degrees C. The redox potentials of all complexes decrease cathodically by 0.4-0.6 V upon irradiation by visible light because of the photoinduced solvolysis of acetonitrile or py ligands. These in situ generated species display an even better mediating performance with HRP, although their behavior toward GO is different. The loading of a ruthenium unit into the protein interior brings about large catalytic currents in a self-assembled system GO-Ru-D-glucose. The estimated rate constant for intramolecular electron transfer from FADH2 of the active site at RuIII, k(intra), equals 4.4 x 10(3) s(-1). This suggests that the distance between the redox partners is around 19 A. The value of 21 A was obtained through the docking analysis of a possible closest-to-FAD localization of a Ru-containing fragment derived from the irradiated complex cis-[Ru(o-C6H4-py)-(phen)(MeCN)2]PF6. The operational stability of the GO-Ru assemblies depends on the nature of complex used, the highest being observed for cis-[Ru(o-C6H4-py)(Me2-bpy)(MeCN)2]PF6 (2). UV-vis studies of interaction of 2 with GO revealed photomechanical oscillations in the system GO-Ru-D-glucose. When irradiated complex 2 is mixed with GO and D-glucose, the absorbance at 510 nm increases because of the enzymatic reduction of RuIII to RuII. The absorbance drops rapidly and then increases as in the first cycle after shaking the reaction solution. Many cycles are possible, and the rate of absorbance increase does not depend on a cycle number. A plausible mechanism of the oscillations is presented.

Published

2005

46. Wiring of PQQ-dehydrogenases.

Author

Laurinavicius V, Razumiene J, Ramanavicius A, and Ryabov AD

Subjects

Adsorption, Biosensing Techniques instrumentation, Coated Materials, Biocompatible chemistry, Electrochemistry instrumentation, Enzyme Activation, Enzymes, Immobilized chemistry, Glucose 1-Dehydrogenase classification, Hydrogen-Ion Concentration, Materials Testing, Protein Binding, Substrate Specificity, Alcohol Dehydrogenase chemistry, Biosensing Techniques methods, Electrochemistry methods, Glucose analysis, Glucose chemistry, Glucose 1-Dehydrogenase chemistry, PQQ Cofactor chemistry

Abstract

The performance of pyrroloquinoline quinone (PQQ) dependent alcohol dehydrogenase (ADH) and two types of PQQ-glucose dehydrogenases in solution and when immobilized on the carbon paste electrodes modified with ferrocene derivatives is investigated. The immobilization of ADH consisting of PQQ and four hemes improves its stability up to 10 times. Both PQQ and heme moieties are involved in the electron transport from substrate to electrode. The ferrocene derivatives improve the electron transport 10-fold. Membrane-bound alcohol dehydrogenase from Gluconobacter sp. 33, intracellular soluble glucose dehydrogenase from Acinetobacter calcoaceticus L.M.D. 79.41 (s-GDH), and the membrane-bound enzyme (m-GDH) from Erwinia sp. 34-1 were purified and investigated. Soluble and membrane-bound PQQ-glucose dehydrogenases display different behavior during the immobilization on the modified carbon electrodes. The immobilization of s-GDH leads to a decrease in both stability and substrate specificity of the enzyme. This suggests that PQQ dissociates from the enzyme active center and operates as a free-diffusing mediator. The rate-limiting step of the process is likely the loading of PQQ onto the apo-enzyme. The immobilization of m-GDH leads to its substantial stabilization and improves the substrate specificity. The nature of m-GDH binding to the electrode surface is presumably similar to the binding to the cell membrane through its anchor-subunit. The enzyme operates as an enzyme and mediator complex.

Published

2004

47. Pseudo-rotation mechanism for fast olefin exchange and substitution processes at orthometalated C,N-complexes of platinum(II).

Author

Otto S, Samuleev PV, Polyakov VA, Ryabov AD, and Elding LI

Abstract

Bridge splitting in chloroform of the orthometalated chloro-bridged complex [Pt(micro-Cl)(2-Me(2)NCH(2)C(6)H(4))](2)(1), with ethene, cyclooctene, allyl alcohol and phosphine according to 1+ 2L --> 2[PtCl(2-Me(2)NCH(2)C(6)H(4))(L)], where L = C(2)H(4)(3a), C(8)H(14), (3b), CH(2)CHCH(2)OH (3c), and PPh(3)(4a and 4b) gives monomeric species with L coordinated trans or cis to aryl. With olefins the thermodynamically stable isomer with L coordinated cis to aryl is formed directly without an observable intermediate. With phosphine and pyridine, the kinetically controlled trans-product isomerizes slowly to the more stable cis-isomer. Bridge splitting by olefins is slow and first-order in 1 and L, with largely negative DeltaS(++). Substitution of ethene cis to aryl by cyclooctene and allyl alcohol to form 3b and 3c, and substitution of cot from 3b by allyl alcohol to form 3c are first order in olefin and complex, ca. six orders of magnitude faster than bridge cleavage due to a large decrease in DeltaH(++), and with largely negative DeltaS(++). Cyclooctene exchange at 3b is first-order with respect to free cyclooctene and platinum complex. All experimental data for olefin substitution and exchange are compatible with a concerted substitution/isomerization process via a turnstile twist pseudo-rotation in a short-lived labile five-coordinated intermediate, involving initial attack on the labile coordination position trans to the sigma-bonded aryl. Bridge-cleavage reactions of the analogous bridged complexes occur similarly, but are much slower because of their ground-state stabilization and steric hindrance.

Published

2004

48. Dinuclear versus mononuclear ruthenium(II) and osmium(II) complexes as potent mediators of glucose oxidase; crystal structure of [OsCl(4,4'-bpy)(bpy)2]BF4.

Author

Ryabov AD, Roznyatovskaya NV, Suwinska K, Revenco M, and Ershov AY

Subjects

2,2'-Dipyridyl chemical synthesis, 2,2'-Dipyridyl chemistry, Crystallization, Crystallography, X-Ray methods, Dimerization, Osmium Compounds chemical synthesis, Ruthenium Compounds chemical synthesis, Glucose Oxidase chemistry, Osmium Compounds chemistry, Ruthenium Compounds chemistry

Abstract

New and known homo- and heterodinuclear Ru(II) and Os(II) complexes with 4,4'-bipyridine (4,4'-bpy), pyrazine, and 4-pyCH=CHpy-4' as bridging ligands (LL) of the type [Cl(bpy)(2)M(LL)MCl(bpy)(2)]X(2) (bpy=2,2'-bipyridine; X=PF(6) or BF(4)) have been studied in their capacity to exchange electrons with a reduced active site of glucose oxidase (GO) from Aspergillus niger. Cyclic voltammograms (CVs) of the dimers in the aqueous buffered solution, when compared with CVs of the parent monomeric species [MCl(LL)(bpy)(2)]BF(4) and [MCl(2)(bpy)(2)] which could be generated at pH approximately 7, if the dimers undergo monomerization, indicate that the dimers are the dominating species under such conditions. All electrochemically oxidized dinuclear complexes studied show high rates of oxidation of GO reduced by D-glucose and the corresponding observed second-order rate constants are in the range (5-64)x10(5) M(-1) s(-1) at 25 degrees C. However, these values are lower than that for the mononuclear complex [OsCl(4,4'-bpy)(bpy)(2)]BF(4) (1.1x10(7) M(-1) s(-1)), suggesting that potentially two-electron dimeric mediators have no advantage compared with corresponding monomeric complexes of Ru(II) and Os(II). The structure of [OsCl(4,4'-bpy)(bpy)(2)]BF(4) was confirmed by X-ray crystallography. The monodentate 4,4'-bpy ligand is coordinated cis to the chloride. Its higher reactivity toward reduced GO is accounted for in terms of the antenna effect of the monodentate 4,4'-bpy ligand. The antenna length equals 9.2 A and matches the depth of the enzyme active site pocket of ca. 10 A. The mechanism of the antenna effect is discussed.

Published

2003

49. Low-potential cyclometalated osmium(II) mediators of glucose oxidase.

Author

Ryabov AD, Soukharev VS, Alexandrova L, Le Lagadec R, and Pfeffer M

Subjects

Enzyme Inhibitors chemistry, Models, Molecular, Osmium chemistry, Enzyme Inhibitors pharmacology, Glucose Oxidase antagonists & inhibitors, Osmium pharmacology

Abstract

The osma(II)cycles [Os(phpy)(LL)(2)]PF(6) (LL = 1,10-phen (3a) and 4,4'-Me(2)-2,2'-bpy (3b)) are made from [(eta(6)-C(6)H(6))Os(micro-Cl)Cl](2) (1) either via transmetalation using the [Hg(phpy)(2)] organomercurial in MeOH or via the sp(2)-C-H bond cleavage of 2-phenylpyridine (phpyH) in MeCN to afford [(eta(6)-C(6)H(6))Os(phpy)Cl] or [(eta(6)-C(6)H(6))Os(phpy)(MeCN)]PF(6), respectively. The latter two react cleanly with LL to give 3a and 3b, the M(II/III) redox potentials of which equal 30 and -100 mV (vs Ag/AgCl), respectively. The electrochemically made Os(III) species oxidize rapidly reduced glucose oxidase. The second-order rate constant equals 1.1 x 10(7) M(-)(1) s(-)(1) for 3a at 25 degrees C, pH 7.

Published

2003

50. Understanding the mechanism of H(+)-induced demetalation as a design strategy for robust iron(III) peroxide-activating catalysts.

Author

Ghosh A, Ryabov AD, Mayer SM, Horner DC, Prasuhn DE Jr, Sen Gupta S, Vuocolo L, Culver C, Hendrich MP, Rickard CE, Norman RE, Horwitz CP, and Collins TJ

Subjects

Biomimetic Materials chemistry, Biomimetic Materials metabolism, Catalysis, Crystallography, X-Ray, Ferric Compounds metabolism, Hydrogen-Ion Concentration, Kinetics, Oxidation-Reduction, Peroxides metabolism, Protons, Ferric Compounds chemistry, Peroxides chemistry

Abstract

The FeIII-TAML (tetra-amido macrocyclic ligand) activators 1 (Y = Cl) and 2 (Y = H2O), a (R = Me, X = H), b (Me, Cl), c (Me, MeO), d (Et, Cl), e (F, H), f (F, Cl), are five-coordinated in the solid state (X-ray crystallography) but are six-coordinated species in water with two H2O axial ligands. The first pKa's of aqueous ligands are in the range of 9.5-10.5. The acid-induced demetalation of 2 follows the equation kobs = k1*[H+] + k3*[H+]3. The rate constants k1* and k3* vary by 5 and 11 orders of magnitude depending on the nature of substituents R. The highest stabilization against the demetalation is achieved for R = F.

Published

2003