Co-reporter:Elaine M. Conner;W. Ewen Smith;I. Jack Zeitlin
BioMetals 2017 Volume 30( Issue 3) pp:423-439
Publication Date(Web):19 April 2017
DOI:10.1007/s10534-017-0016-z
The design, synthesis and activity of polymodal compounds for the treatment of inflammatory bowel disease are reported. The compounds, being based on a metal-Schiff base motif, are designed to degrade during intestinal transit to release the bioactive components in the gut. The compounds have been developed sequential with the biomodal compounds combining copper or zinc with a salicylaldehyde adduct. These compounds were tested in a formalin induced colonic inflammation model in BK:A mice. From these studies a trimodal compound based on a zinc Schiff base analogue of sulfasalazine was designed. This was tested against a trinitrobenzenesulfonic acid (TNB) induced colitic model in Wistar rats. The use of two models allows us to test our compounds in both an acute and a chronic model. The trimodal compound reported is observed to provide anticolitic properties in the chronic TNB induced colitis model commensurate with that of SASP. However, the design of trimodal compound still has the capacity for further development. This the platform reported may offer a route into compounds which can markedly outperform the anti-colitic properties of SASP.
Co-reporter:Abdullahi Mustapha, Graham Steel, John Reglinski, Alan R. Kennedy
Polyhedron 2017 Volume 129(Volume 129) pp:
Publication Date(Web):17 June 2017
DOI:10.1016/j.poly.2017.03.050
The synthesis of the potentially heptadentate ligands, tris-(2-aminobenzylidene)amino-ethylamine (L3) and tris-(o-aminobenzyl)aminoethylamine (L4) are reported. Complexes of L3 with nickel, copper and zinc have been synthesised and characterised. However, the nickel and zinc compounds are observed to re-arrange during the procedures used to produce samples for X-ray diffraction analysis. In both cases aniline groups are found to migrate to give rise to unique but related coordinated polyamine species. A rational route which allows for the reduction of the imine function in L3 is presented giving rise to a heptadentate ligand (L4) which contains primary, secondary and tertiary amines. Having removed the reactive imine function, the synthesized nickel and copper complexes follow the expected synthetic and structural pattern with the nickel complex being observed to be octahedral and the copper(II) complex five coordinate. The zinc complex is in contrast different. As observed for L3, it is possible to generate simple ZnL4 complexes but these are prone to oxidation and intramolecular cyclisation where an aniline nitrogen couples with the secondary amine to form a coordinated indazine.The synthesis of the potentially heptadentate ligands, tris-(2-aminobenzylidene)amino-ethylamine and tris-(o-aminobenzyl)aminoethylamine are reported. Complexes of nickel copper and zinc have been synthesised and characterised. However, some compounds are observed to re-arrange leading to curious coordinated polyamine species.Download high-res image (46KB)Download full-size image
Co-reporter:John Reglinski, Alan R. Kennedy and Graham Steel
New Journal of Chemistry 2015 vol. 39(Issue 4) pp:2437-2439
Publication Date(Web):19 Feb 2015
DOI:10.1039/C4NJ01949K
The structure of (BeSalen)2 is reported. The incompatibility of the geometry of the beryllium with the inflexibility of the Salen ligand gives rise to a rare dimeric bis-didentate motif.
Co-reporter:Lynsey Dunbar;Rebecca J. Sowden;Katherine D. Trotter;Michelle K. Taylor
BioMetals 2015 Volume 28( Issue 5) pp:903-912
Publication Date(Web):2015 October
DOI:10.1007/s10534-015-9875-3
The study reports an advance in designing copper-based redox sensing MRI contrast agents. Although the data demonstrate that copper(II) complexes are not able to compete with lanthanoids species in terms of contrast, the redox-dependent switch between diamagnetic copper(I) and paramagnetic copper(II) yields a novel redox-sensitive contrast moiety with potential for reversibility.
Co-reporter:Rajeev Rajasekharan-Nair, Dean Moore, Alan R. Kennedy, John Reglinski, and Mark D. Spicer
Inorganic Chemistry 2014 Volume 53(Issue 19) pp:10276-10282
Publication Date(Web):September 10, 2014
DOI:10.1021/ic5013236
The chemistry of the hydrotris(mercaptobenzothiazolyl)borate anion (Tbz) with metal salts (HgI2, SbI3, BiI3, CoCl2) is reported in an attempt to probe the stability of the of Tbz ligand once coordinated to hard and soft metals. Complexes of Tbz with bismuth, containing the [Bi(Tbz)I3]− anion, are stable, but with the other metals this is not the case. Although simple complexes such as [Hg(Tbz)I] and [E(Tbz)I3]− (E = Sb, Bi) can be isolated from the reaction mixtures, subsequent reactions lead to ligand modification or decomposition. In the presence of mercury and antimony we observe the formation of a hitherto unseen cationic pentacyclic heterocycle. With cobalt we observe a small quantity of a product which suggests a more complete decomposition. A simple benzothiazole (bz) adduct [Co(bz)2Cl2] has been identified, in which the Tbz ligand has disintegrated and the parent heterocycle, mercaptobenzothiazole, has been desulfurized. A rationale for these observations is given.
Co-reporter:Dawn Wallace;Kirsten Chalmers;Christopher A. Dodds;Iain A. Stepek;David R. Armstrong;Leonard E. A. Berlouis;Mark D. Spicer
European Journal of Inorganic Chemistry 2014 Volume 2014( Issue 15) pp:2569-2575
Publication Date(Web):
DOI:10.1002/ejic.201301588
Abstract
A series of methimazole-based soft scorpionate anions ([RTmMe]–, R = H, Ph, Me, nBu) bearing substitution at the bridgehead boron have been used to produce a series of germanium complexes of general formulae [Ge(RTmMe)2]I2. Structural analyses of the germanium complexes by X-ray crystallography reveal that they all contain an octahedral S6 coordination sphere. The scorpionate anions (as their Li or Na salts) and their germanium complexes have been studied by thermogravimetric analysis. This analysis suggests that the degradation pathway for the free scorpionate anions differs from that of the complexes. Both pathways involve the loss of a methimazole ring thereby supporting the view that cleavage of the boron–nitrogen bonds can occur under thermally aggressive conditions. As expected, the presence of the germanium alters the degradation profile of the anion. In contrast to the free anions, the four complexes all display a similar mechanism for degradation. Although the presence of the germanium enforces a conformational change in the anions, its presence does not significantly increase the stability of the boron–nitrogen bonds.
Co-reporter:Rajeev Rajasekharan-Nair, Lisa Darby, John Reglinski, Mark D. Spicer, Alan R. Kennedy
Inorganic Chemistry Communications 2014 Volume 41() pp:11-13
Publication Date(Web):March 2014
DOI:10.1016/j.inoche.2013.12.007
•Bis-(κ3-H,S,S-dihydrobis(methimazolyl)borato)ruthenium (II) and (III) species re reported.•[Ru(BmMe)2] has been tested as a nitric oxide scavenger using NO, NOBF4 and NOBr.•The products that, NO and NO+ act as oxidising agents rather than as ligands.•Alternative routes to the synthesis of soft scorpionate ruthenium nitrosyl species are discussed.Bis-(κ3-H,S,S-dihydrobis-(methimazolyl)borato)ruthenium(II), [Ru(BmMe)2], has been prepared and tested as a nitric oxide scavenger using NO, NOBF4 and NOBr. The products isolated show that, NO and NO+ are good one electron oxidising agents towards the ruthenium complexes but NO is not coordinated to the metal. The oxidised species, [Ru(BmMe)2]BF4 has been isolated and characterised. Reaction of “Ru(NO)Cl3” with NaBmMe results in the removal of the borohydride from the ligand and formation of [Ru(mtH)3(mt)(NO)Cl]+.The reactions of bis-(κ3-H,S,S-dihydrobis(methimazolyl)borato)ruthenium(II), [Ru(BmMe)2], with nitric oxide species (NO, NOBF4 and NOBr) are investigated.
Co-reporter:Graham Steel, Abdullahi Mustapha, John Reglinski, Alan R. Kennedy
Polyhedron 2014 67() pp: 360-367
Publication Date(Web):
DOI:10.1016/j.poly.2013.09.018
Co-reporter:Rajeev Rajesekharan-Nair;Samuel T. Lutta;Alan R. Kennedy, ;Mark D. Spicer
Acta Crystallographica Section C 2014 Volume 70( Issue 5) pp:421-427
Publication Date(Web):
DOI:10.1107/S2053229614005737
Reported here are the single-crystal X-ray structure analyses of bis-μ-methanol-κ4O:O-bis{[hydrotris(3-phenyl-2-sulfanylidene-2,3-dihydro-1H-1,3-imidazol-1-yl)borato-κ3H,S,S′](methanol-κO)sodium(I)}, [Na2(C27H22BN6S3)2(CH4O)4] (NaTmPh), bis-μ-methanol-κ4O:O-bis{[hydrotris(3-isopropyl-2-sulfanylidene-2,3-dihydro-1H-1,3-imidazol-1-yl)borato-κ3H,S,S′](methanol-κO)sodium(I)}–diethyl ether–methanol (1/0.3333/0.0833), [Na2(C18H28BN6S3)2(CH4O)4]·0.3333C4H10O·0.0833CH3OH (NaTmiPr), and a novel anhydrous form of sodium hydrotris(methylthioimidazolyl)borate, poly[[μ-hydrotris(3-methyl-2-sulfanylidene-2,3-dihydro-1H-1,3-imidazol-1-yl)borato]sodium(I)], [Na(C12H16BN6S3)] ([NaTmMe]n). NaTmiPr and NaTmPh have similar dimeric molecular structures with κ3H,S,S′-bonding, but they differ in that NaTmPh is crystallographically centrosymmetric (Z′ = 0.5) while NaTmiPr contains one crystallographically centrosymmetric dimer and one dimer positioned on a general position (Z′ = 1.5). [NaTmMe]n is a one-dimensional coordination polymer that extends along the a direction and which contains a hitherto unseen side-on η2-C=S-to-Na bond type. An overview of the structural preferences of alkali metal soft scorpionate complexes is presented. This analysis suggests that these thione-based ligands will continue to be a rich source of interesting alkali metal motifs worthy of isolation and characterization.
Co-reporter:Naseem Ullah, Muhammad Mukhitar, Muhammad Farid Khan, John Reglinski
Polyhedron 2014 Volume 78() pp:104-111
Publication Date(Web):16 August 2014
DOI:10.1016/j.poly.2014.04.008
The Ellman’s based thiol–disulfide exchange process used to quantify sulfhydryl groups in biology and medicine is interrogated using 1H NMR methods. Although not as accurate as the spectrophotometric assay NMR spectroscopy has value for the study of complex mixtures as it can identify all the key species in the mixture including the mixed disulfides of Ellman’s reagent and its sulfenic acid. We have used NMR to analysis complex mixtures involving metal (arsenic, lead, palladium) thiolates where we are able to show that Ellman’s reagent can exchange with coordinate thiolate but at the expense of the accuracy of the analysis.The Ellman’s based thiol–disulfide exchange process is interrogated using 1H NMR methods and used to study complex mixtures involving metal (arsenic, lead, palladium) thiolates.
Co-reporter:Dr. Rajeev Rajasekharan-Nair;Annemarie Marckwordt;Dr. Samuel T. Lutta;Dr. Matthias Schwalbe;Anne Biernat;Dr. David R. Armstrong;Dr. Allan J. B. Watson;Dr. Alan R. Kennedy;Dr. John Reglinski;Dr. Mark D. Spicer
Chemistry - A European Journal 2013 Volume 19( Issue 40) pp:13561-13568
Publication Date(Web):
DOI:10.1002/chem.201300091
Abstract
Soft scorpionates have thus far been seen mainly as a family of ligands. Their chemistry is extended here to the production of novel cationic macrocycles using dihaloalkanes. By replacing the dihaloalkanes with mild oxidising agents (NO+, I2) we obtain two unique polycyclic heterocycles. The mechanism which leads to the formation of these polycyclic heterocycles is investigated using ab initio DFT calculations.
Co-reporter:Rajeev Rajasekharan-Nair;Dean Moore;Dr. Kirsten Chalmers;Dr. Dawn Wallace;Louise M. Diamond;Lisa Darby;Dr. David R. Armstrong;Dr. John Reglinski;Dr. Mark D. Spicer
Chemistry - A European Journal 2013 Volume 19( Issue 7) pp:2487-2495
Publication Date(Web):
DOI:10.1002/chem.201202314
Abstract
The alkylation reactions of soft scorpionates are reported. The hydrotris(S-alkyl-methimazolyl)borate dications (alkyl=methyl, allyl, benzyl), which were prepared by the reaction of TmMe anion and primary alkyl halides, have been isolated and structurally characterised. The reaction is, however, not universally successful. DFT analysis of these alkylation reactions (CS versus BH alkylation) indicates that the observed outcome is driven by kinetic factors. Extending the study to incorporate alternative imine thiones (mercaptobenzothiazole, bz; thiazoline, tz) led to the structural characterisation of di[aquo-μ-aquohydrotris(mercaptobenzothiazolyl)boratosodium], which contains sodium atoms in the κ3-S,S,S coordination mode. Alkylation of Na[Tbz] and Na[tzTtz] leads to decomposition resulting in the formation of the simple S-alkylated heterocycles. The analysis of the species involved in these reactions shows an inherent weakness in the BN bond in soft scorpionates, which has implications for their use in more advanced chemistry.
Co-reporter:Abdullahi Mustapha, Christoph Busche, John Reglinski, Alan R. Kennedy
Polyhedron 2011 30(9) pp: 1530-1537
Publication Date(Web):
DOI:10.1016/j.poly.2011.03.004
Co-reporter:Andrew Mills, Paul A. Duckmanton and John Reglinski
Chemical Communications 2010 vol. 46(Issue 14) pp:2397-2398
Publication Date(Web):01 Feb 2010
DOI:10.1039/B925784E
A novel oxygen catalyst is prepared via the photodeposition of ruthenium(IV) oxide on a titania photocatalyst derived from a perruthenate precursor.
Co-reporter:Dawn Wallace ; Edward J. Quinn ; David R. Armstrong ; John Reglinski ; Mark D. Spicer ;W. Ewen Smith
Inorganic Chemistry 2010 Volume 49(Issue 4) pp:1420-1427
Publication Date(Web):January 7, 2010
DOI:10.1021/ic9014898
The chemisorption of the soft scorpionate Li[PhTmMe] onto silver and gold surfaces is reported. Surface enhanced Raman spectroscopy in combination with the Raman analysis of suitable structural models, namely, [Cu(κ3-S,S,S-PhTmMe)(PCy3)], [Ag(κ3-S,S,S-PhTmMe)(PCy3)], [Ag(κ2-S,S-PhTmMe)(PEt3)], and [Au(κ1-S-PhTmMe)(PCy3)], are employed to identify the manner in which this potentially tridentate ligand binds to these surfaces. On colloidal silver surface-enhanced Raman spectroscopy (SERS) spectra are consistent with PhTmMe binding in a didentate fashion to the surface, holding the aryl group in close proximity to the surface. In contrast, on gold colloid, we observe that the species prefers a monodentate coordination in which the aryl group is not in close proximity to the surface.
Co-reporter:Abdullahi Mustapha ; John Reglinski ; Alan R. Kennedy ; David R. Armstrong ; Jörg Sassmannshausen ;Mark Murrie
Inorganic Chemistry 2010 Volume 49(Issue 12) pp:5350-5352
Publication Date(Web):May 18, 2010
DOI:10.1021/ic100594n
The reaction of the multidentate Schiff base species TrenSal, TrenBrSal, and TEtSal with copper acetate is reported. The heptadentate ligands generate a tetrametallic L2Cu4OH motif that contains an internalized hydroxide anion. In contrast, the hexadentate TEtSal ligand is found to form an open trimetallic motif. The importance of L2Cu4OH to the family of copper complexes with an endohedral hydroxide anion is discussed. [(TrenBrSal)2Cu4OH][OAc] is analyzed by temperature-dependent magnetic measurements.
Co-reporter:Katherine D. Trotter, Michelle K. Taylor, John C. Forgie, John Reglinski, Leonard E.A. Berlouis, Alan R. Kennedy, Corinne M. Spickett, Rebecca J. Sowden
Inorganica Chimica Acta 2010 Volume 363(Issue 7) pp:1529-1538
Publication Date(Web):20 April 2010
DOI:10.1016/j.ica.2010.01.012
A series of cis and trans tetradentate copper macrocyclic complexes, of ring size 14–16, that employ amine and thioether donor groups are reported. Apart from 5,6,15,16-bisbenzo-8,13-diaza-1,4-dithia-cyclohexadecane copper(I) (cis-[Cu(H4NbuSen)]+) all of the complexes are obtained in the copper(II) form. Crystallographic analysis shows that the copper(II) complexes all adopt a distorted planar geometry around the copper. In contrast, cis-[Cu(H4NbuSen)]+ is found to adopt a distorted tetrahedral geometry. The complexes were subjected to electrochemical analysis in water and acetonitrile. The effect of the solvent, positions of the donor atoms (cis/trans) on E1/2 is discussed as is the comparison of the electrochemical behaviour of these complexes with their parent Schiff base macrocycles.A series of tetradentate copper macrocyclic complexes, which employ amine and thioether donor groups are reported. Apart from cis-[Cu(H4NbuSen)]+ all of the complexes are obtained in the copper(II) form. Crystallographic analysis shows that the copper(II) complexes all adopt a distorted planar geometry. In contrast, cis-[Cu(H4NbuSen)]+ adopts a distorted tetrahedral geometry. The complexes were subjected to electrochemical analysis and the effect of the solvent and the donor atoms positions on E1/2 discussed.
Co-reporter:Abdullahi Mustapha, John Reglinski, Alan R. Kennedy
Inorganic Chemistry Communications 2010 Volume 13(Issue 4) pp:464-467
Publication Date(Web):April 2010
DOI:10.1016/j.inoche.2010.01.009
The cationic nickel, copper and zinc complexes of tris-(2-hydroxybenzyl)-aminoethylamine (H6TrenSal) have been deprotonated using potassium hydroxide. The nickel complex can be sequentially deprotonated to form a series of compounds namely, [(H6TrenSal)Ni]+, [(H6TrenSal)Ni] and “[(H6TrenSal)Ni]K”. The latter is isolated as a mixture of species namely [{(H6TrenSal)Ni}K(EtOH)]2, [{(H6TrenSal)Ni}K(EtOH)2-μ-OH2]2 and [{(H6TrenSal)Ni}K(EtOH)2-μ-EtOH]2, which co-crystallise in a roughly 50:27.5:22.5 ratio. In contrast the deprotonation of [(H6TrenSal)M]+ (M = Cu, Zn) results in the formation of tetrameric complexes [({(H6TrenSal)Ni}K(OH2)2)4(μ4-OH2)].The cationic nickel, copper and zinc complexes of tris-(2-hydroxybenzyl)-aminoethylamine (H6TrenSal) have been deprotonated using potassium hydroxide. The nickel complex can be sequentially deprotonated to form a series of compounds namely, [(H6TrenSal)Ni]+ , [(H6TrenSal)Ni] and “[(H6TrenSal)Ni]K”. The latter is isolated as a mixture of species namely [{(H6TrenSal)Ni}K(EtOH)]2, [{(H6TrenSal)Ni}K(EtOH)2–μ2-OH2]2 and [{(H6TrenSal)Ni}K(EtOH)2–μ2-EtOH]2. which co-crystallise in a roughly 50:27.5:22.5 ratio. In contrast the deprotonation of [(H6TrenSal)M]+ (M = Cu, Zn) results in the formation of tetrameric complexes [({(H6TrenSal)Ni}K(OH2)2)4(μ4-OH2)].
Co-reporter:Abdullahi Mustapha, Paul Duckmanton, John Reglinski, Alan R. Kennedy
Polyhedron 2010 29(13) pp: 2590-2594
Publication Date(Web):
DOI:10.1016/j.poly.2010.06.001
Co-reporter:Mark D. Spicer
European Journal of Inorganic Chemistry 2009 Volume 2009( Issue 12) pp:1553-1574
Publication Date(Web):
DOI:10.1002/ejic.200801240
Abstract
This review describes the development of the anionic soft scorpionate ligand hydrotris(methimazolyl)borate (TmMe), its N-alkyl and N-aryl congeners and draws comparisons where appropriate with its close relatives, the dihydrobis(methimazolyl)borates (BmR). Key features of the interaction of these species with metal centres, including bonding modes, electron-donor properties, M···H–B interactions, ligand degradation and metallaboratrane formation are addressed and a summary of the coordination chemistry of these species with both main group and transition metals is given. (© Wiley-VCH Verlag GmbH & Co. KGaA, 69451 Weinheim, Germany, 2009)
Co-reporter:Abdullahi Mustapha, John Reglinski, Alan R. Kennedy
Inorganica Chimica Acta 2009 Volume 362(Issue 4) pp:1267-1274
Publication Date(Web):2 March 2009
DOI:10.1016/j.ica.2008.06.026
The synthetic utility of tris-((2-hydroxybenzyl)-aminoethyl)amine (H6TrenSal) and tris-((2-hydroxy-5-bromobenzyl)-aminoethyl)amine (H6Tren5BrSal) are investigated. A range of monomeric complexes with general formula [(H6TrenSal)M][NO3] with nickel, copper and zinc are reported and crystallographically analysed. Nickel adopts three motifs which are different to that observed for copper and zinc. The use of these species as platforms for the synthesis of more complex systems in conjunction with the lanthanoids are explored. Copper and zinc do not follow a similar reaction pathway to nickel. While nickel forms the expected trimetallic motif [{(TrenSal)Ni}2Ln(HOMe)]+, copper forms a copper trimetallic motif. In contrast to both nickel and copper, reactions with [(H6TrenSal)Zn]+ produce lanthanoid based products namely [(H6Tren5BrSal)Gd(NO3)3] and [{(H6TrenSal)Ce}2-μ2-O2].The synthetic utility of Tris-((2-hydroxybenzyl)-aminoethyl)amine (H6TrenSal) and Tris-((2-hydroxy-5-bromobenzyl)-aminoethyl)amine (H6Tren5BrSal) are investigated. A range of monomeric complexes with general formula [(H6TrenSal)M] [NO3] with nickel, copper and zinc are reported and crystallographically analysed. The use of these species as platforms for the synthesis of more complex systems in conjunction with the lanthanoids are explored. While nickel forms the expected trimetallic motif [{(TrenSal)Ni}2Ln(HOMe)]+, copper forms a copper trimetallic motif. In contrast [(H6TrenSal)Zn] produce lanthanoid based products namely [(H6Tren5BrSal)Gd(NO3)3] and [{(H6TrenSal)Ce}2−μ2-O2].
Co-reporter:Katherine D. Trotter, John Reglinski, Keith Robertson, John C. Forgie, John A. Parkinson, Alan R. Kennedy, David R. Armstrong, Rebecca J. Sowden, Corinne M. Spickett
Inorganica Chimica Acta 2009 Volume 362(Issue 11) pp:4065-4072
Publication Date(Web):15 August 2009
DOI:10.1016/j.ica.2009.05.060
The X-ray crystal structures of two related trans-N2S2 copper macrocycles are reported. One was isolated with the copper in the divalent form and the other with copper in its univalent form affording a valuable insight into the changes of geometry and metrical parameters that occur during redox processes in macrocyclic copper complexes. A variable temperature NMR study of the copper(I) complex is reported, indicative of a chair-boat conformational change within the alkyl chain backbone of the macrocycle. It was possible to extract the relevant kinetic and thermodynamic parameters (ΔG‡, 57.8 kJ mol−1; ΔH‡, 52.1 kJ mol−1; ΔS‡, −19.2 J K−1 mol−1) for this process at 298 K. DFT molecular orbital calculations were used to confirm these observations and to calculate the energy difference (26.2 kJmol−1) between the copper(I) macrocycle in a planar and a distorted tetrahedral disposition.The dynamic behaviour of two related trans-N2S2 copper macrocycles are reported in relation to their use as redox sensors and models of blue copper proteins. Two processes are studied namely the boat chair conformational change of the alkyl moieties within the macrocyclic backbone (52.1 kJ mol−1) and the energy required to move the ring from a distorted planar into to a tetrahedral geometry (26.2 kJ/mol−1). The view obtained is of a ligand which is able to re-organise to suit the prevailing conditions.
Co-reporter:Michelle K. Taylor, Katherine D. Trotter, John Reglinski, Leonard E.A. Berlouis, Alan R. Kennedy, Corinne M. Spickett, Rebecca J. Sowden
Inorganica Chimica Acta 2008 Volume 361(9–10) pp:2851-2862
Publication Date(Web):27 June 2008
DOI:10.1016/j.ica.2008.02.021
A series of bis-salicylidene based N2S2 copper macrocycles were prepared, structurally characterised and subjected to electrochemical analysis. The aim was to investigate the effects of length of polymethylene chains between either the imine donors or the sulfur donors on redox state and potential of the metal. The complexes structurally characterised had either distorted square planar or tetrahedral geometries depending on their oxidation state (Cu2+ or Cu+, respectively), and the N–(CH2)n–N bridge was found to be most critical moiety in determining the redox potential and oxidation state of the copper macrocycles, with relatively little change in these properties caused by lengthening the S–(CH2)n–S bridge from two to three carbons. In fact, a weakness was observed in the complexes at the sulfur donor, as further lengthening of the S–(CH2)n–S methylene bridge to four carbons caused fission of the carbon–sulfur bond to give dimeric rings and supramolecular assemblies. Cu+ complexes could be oxidised to Cu2+ by tert-butylhydroperoxide, with a corresponding change in the spectrophotometric properties, and likewise Cu2+ complexes could be reduced to Cu+ by treatment with β-mercaptoethylamine. However, repeated redox cycles appeared to compromise the stability of the macrocycles, most probably by a competing oxidation of the ligand. Thus the copper N2S2 macrocycles show potential as redox sensors, but further development is required to improve their performance in a biochemical environment.A series of bis-salicylidene based N2S2 copper macrocycles were prepared, structurally characterised and subjected to electrochemical analysis. The aim was to investigate the effects of length of polymethylene chains between either the imine donors or the sulfur donors on redox state and potential of the metal. The potential of the copper N2S2 macrocycles as redox sensors is discussed.
Co-reporter:Anne Biernat, Matthias Schwalbe, Dawn Wallace, John Reglinski and Mark D. Spicer
Dalton Transactions 2007 (Issue 22) pp:2242-2244
Publication Date(Web):03 May 2007
DOI:10.1039/B705161C
The synthesis and structure of two related sodium complexes are reported which demonstrate that sulfur can preferentially complex to sodium irrespective of the presence of more apposite donor species such as DMF.
Co-reporter:Matthias Schwalbe;Prokopis C. Andrikopoulos;David R. Armstrong;Mark D. Spicer
European Journal of Inorganic Chemistry 2007 Volume 2007(Issue 10) pp:
Publication Date(Web):22 FEB 2007
DOI:10.1002/ejic.200601175
The syntheses of the complexes [M(TmMe)(CO)2(NO)] (M = Mo, W) by reaction of NOBF4 with [M(TmMe)(CO)3]– are reported and their spectroscopic characterisation and crystal structures are described. The analogous Cr complex could not be prepared by this methodology. The complexes adopt the expected pseudo-octahedral geometry. Complexes [M(L)(CO)2(NO)] (M = Cr, Mo, W; L = Cp, Tp and TmMe) together with the hypothetical [Mo(CO)2(NO)]+ cation were subjected to DFT calculations. Geometry-optimised structures closely parallel the crystallographic determinations and indicate that the complex [Cr(TmMe)(CO)2(NO)] is not inherently unstable. The DFT calculations allow the assignment of the C–O and N–O stretches in the IR spectrum and give insight into both the M–NO bonding and the metal to tripodal ligand bonding. The electron-donor strengths are confirmed to lie in the order TmMe > Tp > Cp. A side reaction of the B–H moiety of the TmMe anion with NO+ results in the isolation of the dimethylformamide adduct of (trismethimazolyl)borane, providing further evidence that the reaction pathways of the TmR ligands are more varied and less passive than in the chemistry of the nitrogen-based scorpionates.(© Wiley-VCH Verlag GmbH & Co. KGaA, 69451 Weinheim, Germany, 2007)
Co-reporter:Michelle K. Taylor, John Reglinski, Leonard E.A. Berlouis, Alan R. Kennedy
Inorganica Chimica Acta 2006 Volume 359(Issue 8) pp:2455-2464
Publication Date(Web):15 May 2006
DOI:10.1016/j.ica.2006.01.039
We report a study which correlates the metrical parameters of the unsubstituted tetradentate copper Schiff base complexes containing N2O2, N2N2 and N2S2 donors with their respective redox potentials. To achieve this aim we were required to structurally characterise many of the seminal species including, [CuAmbpr-H2], [CuH4Amben][ClO4]2, [CuH4Ambpr][ClO4]2, [CuH4Ambbu][ClO4]2, CuH4Salpr and [Cu(SSalen)2][ClO4]2 which were absent from the crystallographic catalogue. The oxidative dehydrogenation of CuH4Salen is revisited through the isolation and structural characterisation of (N-salicyl-N′-salicylidene-1,2-ethylenediamine)copper(II) (CuH3Salen). The redox potentials of the three series of compounds are measured, clearly identifying the operating ranges of each donor set. The modulating effect of coordination geometry on redox potential is evident in the series of N2O2 complexes. This study forms the basis of the rational synthesis of tuneable copper redox sensors by demonstrating the regions in which the various donor sets operate.We report a study which correlates the metrical parameters of the unsubstituted tetradentate copper Schiff base complexes containing N2O2, N2N2 and N2S2 donors with their respective redox potentials. The modulating effect of coordination geometry on redox potential is evident in the series of N2O2 complexes.
Co-reporter:Christopher A. Dodds Dr.;Mark D. Spicer Dr.
Chemistry - A European Journal 2006 Volume 12(Issue 3) pp:
Publication Date(Web):30 SEP 2005
DOI:10.1002/chem.200500677
The syntheses and structures of complexes of the fifth period elements indium and antimony, and the sixth period element bismuth with the soft scorpionate ligand, hydrotris(methimazolyl)borate (TmMe) are reported. A considerable variety of structural motifs were obtained by reaction of the main-group element halide and NaTmMe. The indium(III) complexes took the form [In(κ3-TmMe)2]+. This motif could not, however, be isolated for antimony(III), the dominant product being [Sb(κ3-TmMe)(κ1-TmMe)X] (X=Br, I). An iodo-bridged species [Sb(κ3-TmMe)I(μ2-I)]2, analogous to a previously reported bismuth complex, was also isolated. Reaction of antimony(III) acetate with NaTmMe results in a remarkable species in which three different ligand binding modes are observed. In each antimony complex the influence of the nonbonded electron pair is observed in the structure. Bismuth halides form complexes analogous to those of antimony, with directional lone pairs, but in addition, reaction of Bi(NO3)3 with NaTmMe results in a complex with a regular S6 coordination sphere and a nonstereochemically active lone pair. Comparisons are drawn with known TmMe complexes of As, Sn, and Bi in which the stereochemical influence of the lone pairs is negligible and with TmMe complexes of Te and Bi in which the lone pairs are stereochemically active. This study highlights the ability of TmMe to coordinate in a variety of modes as dictated by the metal centre with no adverse effects on the stability of the complexes formed.
Co-reporter:Jonathan F. Ojo, Paul A. Slavin, John Reglinski, Mark Garner, Mark D. Spicer, Alan R. Kennedy, Simon J. Teat
Inorganica Chimica Acta 2001 Volume 313(1–2) pp:15-20
Publication Date(Web):26 February 2001
DOI:10.1016/S0020-1693(00)00313-3
The syntheses of two new, soft, tripodal anions, hydrotris(mercaptothiazolyl)borate (Tz) and hydrotris(mercaptobenzothiazolyl)borate (Tbz), are reported. These species not only extend the series of thiazolylborate anions which can be generated using the protocol of Trofimenko, but analysis of the respective thione melting points and pKa values, enables the prediction of which thiazolylborate anions can be produced using borohydride melts. Both of the products are converted into their thallium complexes, which can be used as convenient ligand transfer reagents. The X-ray crystal structure of thallium(I) hydrotris(2-mercapto-benzothiazolyl)borate, [Tl(Tbz)]∞, is reported. The ligand complexes to Tl as a C3 tridentate species, while a bridging thione links Tl(Tbz) units into zigzag one-dimensional polymeric chains.
Co-reporter:Paul A. Slavin, John Reglinski, Mark D. Spicer and Alan R. Kennedy
Dalton Transactions 2000 (Issue 3) pp:239-240
Publication Date(Web):26 Jan 2000
DOI:10.1039/A908236K
The synthesis and crystal structure of the [bis{hydrotris(methimazolyl)borato}thallium(III)] cation is reported, in which the thallium ion is co-ordinated by six sulfur thione donors in a regular octahedral environment.
Co-reporter:Andrew Mills, Paul A. Duckmanton and John Reglinski
Chemical Communications 2010 - vol. 46(Issue 14) pp:NaN2398-2398
Publication Date(Web):2010/02/01
DOI:10.1039/B925784E
A novel oxygen catalyst is prepared via the photodeposition of ruthenium(IV) oxide on a titania photocatalyst derived from a perruthenate precursor.
Co-reporter:Anne Biernat, Matthias Schwalbe, Dawn Wallace, John Reglinski and Mark D. Spicer
Dalton Transactions 2007(Issue 22) pp:NaN2244-2244
Publication Date(Web):2007/05/03
DOI:10.1039/B705161C
The synthesis and structure of two related sodium complexes are reported which demonstrate that sulfur can preferentially complex to sodium irrespective of the presence of more apposite donor species such as DMF.
![Benzenemethanol, 2-[(2-aminoethyl)thio]-](http://img.cochemist.com/ccimg/96800/96751-78-9.png)
![Benzenemethanol, 2-[(2-aminoethyl)thio]-](http://img.cochemist.com/ccimg/96800/96751-78-9_b.png)
![Benzoic acid, 2,2'-[1,2-ethanediylbis(thio)]bis-](http://img.cochemist.com/ccimg/53000/52961-83-8.png)
![Benzoic acid, 2,2'-[1,2-ethanediylbis(thio)]bis-](http://img.cochemist.com/ccimg/53000/52961-83-8_b.png)
![Benzenemethanol, 2,2'-[1,2-ethanediylbis(thio)]bis-](http://img.cochemist.com/ccimg/76200/76124-46-4.png)
![Benzenemethanol, 2,2'-[1,2-ethanediylbis(thio)]bis-](http://img.cochemist.com/ccimg/76200/76124-46-4_b.png)
![Phenol, 2,2'-[1,4-butanediylbis(iminomethylene)]bis-](http://img.cochemist.com/ccimg/92700/92633-18-6.png)
![Phenol, 2,2'-[1,4-butanediylbis(iminomethylene)]bis-](http://img.cochemist.com/ccimg/92700/92633-18-6_b.png)
![BENZOIC ACID, 2,2'-[1,4-BUTANEDIYLBIS(THIO)]BIS-](http://img.cochemist.com/ccimg/76400/76305-69-6.png)
![BENZOIC ACID, 2,2'-[1,4-BUTANEDIYLBIS(THIO)]BIS-](http://img.cochemist.com/ccimg/76400/76305-69-6_b.png)
![BENZENEMETHANOL, 2,2'-[1,3-PROPANEDIYLBIS(THIO)]BIS-](http://img.cochemist.com/ccimg/76200/76124-47-5.png)
![BENZENEMETHANOL, 2,2'-[1,3-PROPANEDIYLBIS(THIO)]BIS-](http://img.cochemist.com/ccimg/76200/76124-47-5_b.png)
![Benzaldehyde, 2,2'-[1,3-propanediylbis(thio)]bis-](http://img.cochemist.com/ccimg/76200/76124-48-6.png)
![Benzaldehyde, 2,2'-[1,3-propanediylbis(thio)]bis-](http://img.cochemist.com/ccimg/76200/76124-48-6_b.png)
![1,4-Butanediamine, N,N'-bis[(2-aminophenyl)methylene]-](http://img.cochemist.com/ccimg/15900/15808-27-2.png)
![1,4-Butanediamine, N,N'-bis[(2-aminophenyl)methylene]-](http://img.cochemist.com/ccimg/15900/15808-27-2_b.png)
![1,3-Propanediamine, N,N'-bis[(2-aminophenyl)methylene]-](http://img.cochemist.com/ccimg/15900/15808-26-1.png)
![1,3-Propanediamine, N,N'-bis[(2-aminophenyl)methylene]-](http://img.cochemist.com/ccimg/15900/15808-26-1_b.png)
![Phenol, 2,2'-[1,3-propanediylbis(iminomethylene)]bis-](http://img.cochemist.com/ccimg/2300/2287-28-7.png)
![Phenol, 2,2'-[1,3-propanediylbis(iminomethylene)]bis-](http://img.cochemist.com/ccimg/2300/2287-28-7_b.png)
![1,3-Propanediamine, N,N'-bis[(2-aminophenyl)methyl]-](http://img.cochemist.com/ccimg/827400/827323-05-7.png)
![1,3-Propanediamine, N,N'-bis[(2-aminophenyl)methyl]-](http://img.cochemist.com/ccimg/827400/827323-05-7_b.png)
![Benzaldehyde, 2,2'-[1,2-ethanediylbis(thio)]bis-](http://img.cochemist.com/ccimg/25700/25676-67-9.png)
![Benzaldehyde, 2,2'-[1,2-ethanediylbis(thio)]bis-](http://img.cochemist.com/ccimg/25700/25676-67-9_b.png)
![Ferrate(2-), [7,12-diethenyl-3,8,13,17-tetramethyl-21H,23H-porphine-2,18-dipropanoato(4-)-κN21,κN22,κN23,κN24]-, hydrogen (1:2), (SP-4-2)-](/data/chemimg/522800/14875-96-8.png)
![Ferrate(2-), [7,12-diethenyl-3,8,13,17-tetramethyl-21H,23H-porphine-2,18-dipropanoato(4-)-κN21,κN22,κN23,κN24]-, hydrogen (1:2), (SP-4-2)-](/data/chemimg/522800/14875-96-8_b.png)
![Zinc,[[2,2'-[1,2-ethanediylbis[(nitrilo-kN)methylidyne]]bis[phenolato-kO]](2-)]-, (T-4)-](http://img.cochemist.com/ccimg/14200/14167-22-7.png)
![Zinc,[[2,2'-[1,2-ethanediylbis[(nitrilo-kN)methylidyne]]bis[phenolato-kO]](2-)]-, (T-4)-](http://img.cochemist.com/ccimg/14200/14167-22-7_b.png)
![3H-Indolium,2-[2-[3-[2-[1,3-dihydro-3,3-dimethyl-1-(4-sulfobutyl)-2H-indol-2-ylidene]ethylidene]-2-[(4-isothiocyanatophenyl)thio]-1-cyclohexen-1-yl]ethenyl]-3,3-dimethyl-1-(4-sulfobutyl)-,inner salt, sodium salt (1:1)](http://img.cochemist.com/ccimg/152200/152111-91-6.png)
![3H-Indolium,2-[2-[3-[2-[1,3-dihydro-3,3-dimethyl-1-(4-sulfobutyl)-2H-indol-2-ylidene]ethylidene]-2-[(4-isothiocyanatophenyl)thio]-1-cyclohexen-1-yl]ethenyl]-3,3-dimethyl-1-(4-sulfobutyl)-,inner salt, sodium salt (1:1)](http://img.cochemist.com/ccimg/152200/152111-91-6_b.png)
![1,2-Ethanediamine,N1,N2-bis[(2-aminophenyl)methylene]-](http://img.cochemist.com/ccimg/4500/4408-47-3.png)
![1,2-Ethanediamine,N1,N2-bis[(2-aminophenyl)methylene]-](http://img.cochemist.com/ccimg/4500/4408-47-3_b.png)
