Gold(I) complexes with selenones and triphenylphosphine as ligands

A number of mixed ligand complexes of gold(I) with various selenones and Ph₃P, [Ph₃PAuSe=C<]Cl have been prepared and characterized by elemental analyses, i.r. and n.m.r. methods. A decrease in the i.r. frequency of the C=Se mode of selenones upon complexation is indicative of gold(I) binding viaa selenone group. An upfield shift in the ¹³ C-n.m.r. for the C=Se resonance of selenones and downfield shifts in ³¹P-n.m.r. for the Ph₃P moiety are consistent with the selenium coordination to gold(I). Available data in the literature suggest that P–Au–Se type complexes are usually linear.     

Solution and solid state NMR studies of some selenium analogues of auranofin (an anti-arthritic gold drug)

Three mixed ligand complexes of gold(I) with phosphines and selenones, [Et₃PAuSe=C<]Br as analogues of auranofin (Et₃PAuSR) have been prepared and characterized by elemental analysis, IR and NMR methods. A decrease in the IR frequency of the C=Se mode of selenones upon complexation is indicative of selenone binding to gold(I) via a selenone group. An upfield shift in ¹³C NMR for the C=Se resonance of the selenones and downfield shifts in ³¹P NMR for the R₃P moiety are consistent with the selenium coordination to gold(I). ¹³C solid state NMR shows the chemical shift difference between free and bound selenone to gold(I) for ImSe and DiazSe to be ca 10 and 17?ppm respectively. Large ⁷⁷Se NMR chemical shifts (55?ppm) upon complexation in the solid state for [Et₃PAuDiazSe]Br compared to [Et₃PAuImSe]Br (10?ppm) indicates the former to be more stable and the Au–Se bond to be stronger than in the latter complex.     

Mixed ligand gold(I) complexes with phosphines and selenourea

A series of mixed ligand Au^I complexes with selenourea (Seu) and various phosphines, [R₃PAuSeu]Cl, have been prepared and characterized by elemental analysis, i.r. and n.m.r. methods. A decrease in the i.r. frequency of the C=Se mode of Seu upon complexation is indicative of Au^I binding via a selenone group. An upfield shift in the ¹³C-n.m.r. for the C=Se resonance of Seu, and downfield shifts in ³¹P-n.m.r., for the R₃P moiety are consistent with selenium coordination to Au^I.     

Synthesis and Spectroscopic Characterization of Silver(I) Complexes of Selenones

Silver(I) complexes of selenones, [LAgNO₃] and [AgL₂]NO₃ (where L is imidazolidine-2-selenone or diazinane-2-selenone and their derivatives) have been prepared and characterized by elemental analysis, IR and NMR (¹H, ¹³C and ¹⁰⁷Ag) spectroscopy. An upfield shift in the C=Se resonance of selenones in ¹³C NMR and a downfield shift in N-H resonance in ¹H NMR are consistent with selenium coordination to silver(I). In ¹⁰⁷Ag NMR, the AgNO₃signal is deshielded by 450-650 ppm on coordination to selenones. Greater upfield shifts in ¹³C NMR were observed for [LAgNO₃] compared to [AgL₂]NO₃complexes, whereas the opposite trend was observed for ¹H and¹⁰⁷Ag NMR chemical shifts.     

Gold(I) complexes with tertiary phosphine sulfide ligands

Phosphine sulfides and their gold(I) complexes with general formula R₃P=S—Au—X (X = Cl^–, Br^– or CN^–) were prepared and characterized by elemental analyses, i.r. and ³¹P-n.m.r. spectroscopy. A decrease in the i.r. frequency of the P=S bond in the ligands upon complexation, is indicative of S coordination to gold (I). The ³¹P-n.m.r. spectra revealed that electronegativity of the substituents and angles between them were the two most important factors influencing the ³¹P-n.m.r. chemical shifts. The phosphorus resonance was observed to be more downfield in alkyl substituted phosphine sulfides as compared to the aryl substituted phosphine sulfides. Ligand scrambling in the Cy₃P=S—Au—CN complex in solution, to form [(Cy₃P=S)₂Au]⁺ and [Au(CN)₂]^–, was investigated by ¹³C and ¹⁵N-n.m.r. spectroscopy. Equilibrium constants (K _eq) for scrambling of the Cy₃P=S—Au—CN complex and for its analogue, Cy₃P=Se—Au—CN were measured by integrating the ¹³C-n.m.r. at 297 K and were found to be 0.147 and 1.81 respectively.     

Synthesis,characterization and in vitro cytotoxicity of platinum(II) complexes of selenones [Pt(selenone)2Cl2]

Platinum(II) complexes with various selenones (L) having the general formula [PtL₂Cl₂] were prepared and characterized by elemental analysis and, IR and NMR (¹H, ¹³C, and ⁷⁷Se) spectroscopies. A decrease in the IR frequency of the >C=Se mode and an upfield shift in ¹³C NMR for the >C=Se resonance of selenones are consistent with their selenium coordination to platinum(II). The NMR data show that the complexes are stable in solution and do not undergo equilibration at 297 K. The geometrical structures of the complexes were predicted theoretically (with DFT method) using Gaussian09 program. DFT calculations predicted that the trans configurations were up to 1.7 kcal/mol more stable than the cis forms in gas phase, while in solution form the cis isomers were predicted to be more stable. The UV–vis spectra of the two complexes, 6 and 7 were also recorded at room temperature for 24 h and it was observed that the complexes were stable and did not undergo decomposition. The in vitro antitumor properties of the complexes as well as of cisplatin were evaluated on two human cancer cell lines, HeLa (cervical cancer cells) and MCF7 (breast cancer cells) using MTT assay. The results indicated that the prepared complexes exerted significant inhibition on the selected cancer cells.     

Gold(I) Complexation with Trialkyl/Triaryl Phosphine Selenide Ligands

Abstract

A number of phosphine selenide ligands and their gold(I) complexes of general formula R₃P?Se?Au?X (where X is Cl^?, Br^? and CN^? and R = phenyl, cyclohexyl and tolyl) were prepared. The complexes were characterized by elemental analysis, IR and ³¹P NMR spectroscopic methods. In the IR spectra of all complexes a decrease in frequency of P?Se bond upon coordination was observed, indicating a decrease in P?Se bond order. ³¹P NMR showed that the electronegativity of the substituents is the most important factor determining the ³¹P NMR chemical shift. It was observed that phosphorus resonance is more downfield in alkyl substituted phosphine selenides, as compared to the aryl substituted ones. Ligand disproportionation in the complex Cy₃P?SeAuCN in solution to form [Au(CN)₂]^? and [(Cy₃P?Se)₂Au]⁺ was investigated by ¹³C and ¹⁵N NMR spectroscopy.     

Tris(trimethylsilyl)methanselenenylhalogenide und -chalkogenide

Tris(trimethylsilyl)methaneselenenyl Halides and Chalcogenides . Ditrisyldiselenide ( 1 ) (trisyl = TSi = (Me₃Si)₃C) reacts with SOCl₂, Br₂ and I₂ to provide trisylselenenyl halides TSiSeX ( 2 : X = Cl; 3 : X = Br, 4 : X = I). Insertion of S and Se into the Se? Se bond of 1 to yield (TSiSe)₂S_n ( 5 : n = 1; 6 : n = 2) and (TSiSe)₂Se_n ( 7 : n = 1; 8 : n = 2) was catalysed by iodine. 5 was isolated in pure state and examined by X-ray diffraction. Triselenide 7 can be cleaved by I₂ in CS₂ to give 4 and Se₂I₂ ( 9 ). From 2 with Me₃SiCN and Me₃SiNCS, the new selenenyl pseudohalides TSiSeCN ( 10 ) and TSiSeSCN ( 11 ) were prepared. The compounds were characterised by ¹H, ¹³C- and ⁷⁷Se n.m.r. spectra.     

Oxidative addition of different electrophiles with rhodium(I) carbonyl complexes of unsymmetrical phosphine–phosphine monoselenide ligands

Dimeric chlorobridge complex [Rh(CO)₂Cl]₂ reacts with two equivalents of a series of unsymmetrical phosphine–phosphine monoselenide ligands, Ph₂P(CH₂)_nP(Se)Ph₂ {n = 1( a ), 2( b ), 3( c ), 4( d )}to form chelate complex [Rh(CO)Cl(P∩Se)] ( 1a ) {P∩Se = η²‐(P,Se) coordinated} and non‐chelate complexes [Rh(CO)₂Cl(P～Se)] ( 1b–d ) {P～Se = η¹‐(P) coordinated}. The complexes 1 undergo oxidative addition reactions with different electrophiles such as CH₃I, C₂H₅I, C₆H₅CH₂Cl and I₂ to produce Rh(III) complexes of the type [Rh(COR)ClX(P∩Se)] {where R = ? C₂H₅ ( 2a ), X = I; R = ? CH₂C₆H₅ ( 3a ), X = Cl}, [Rh(CO)ClI₂(P∩Se)] ( 4a ), [Rh(CO)(COCH₃)ClI(P～Se)] ( 5b–d ), [Rh(CO)(COH₅)ClI‐(P～Se)] ( 6b–d ), [Rh(CO)(COCH₂C₆H₅)Cl₂(P～Se)] ( 7b–d ) and [Rh(CO)ClI₂(P～Se)] ( 8b–d ). The kinetic study of the oxidative addition (OA) reactions of the complexes 1 with CH₃I and C₂H₅I reveals a single stage kinetics. The rate of OA of the complexes varies with the length of the ligand backbone and follows the order 1a > 1b > 1c > 1d . The CH₃I reacts with the different complexes at a rate 10–100 times faster than the C₂H₅I. The catalytic activity of complexes 1b–d for carbonylation of methanol is evaluated and a higher turnover number (TON) is obtained compared with that of the well‐known commercial species [Rh(CO)₂I₂]^?. Copyright © 2006 John Wiley & Sons, Ltd.     

Rhodium(III) halide complexes with sulphur donors. The crystal structure ofmer-tris(o-ethylthiocarbamate)-trichlororhodium(III)acetone(1/1)

Summary The complexes [Rh(TC)₃Cl₃] · Me₂CO and [Rh(TC)₃X₃] · 0.5 Me₂CO (TC=O-ethylthiocarbamate; X=Br or I) have been prepared and characterized by i.r. and¹H n.m.r. spectroscopy.The crystal structure of [Rh(TC)₃Cl₃] · Me₂CO has been determined by x-ray diffractometer data and refined to R=0.040. Crystals are monoclinic, space group P2₁, with a=9.101(5), b=15.785(8), c=8.776(5) Å, and =103.00(3)°; Dx=1.57 gcn^–3 for Z=2. The complex is monomeric with octahedral Rh. Relevant distances are Rh-Cl (trans to one another) 2.354(2) and 2.353(2) Å, Rh-Cl (trans to S) 2.388(2) Å; Rh-S (trans to one another) 2.376(3) and 2.369(3) Å, Rh-S (trans to Cl) 2.332(3) Å. There is intramolecular, and possibly intermolecular, hydrogen bonding in the structure.     

Preparation and properties of palladium(II) and rhodium(I) complexes containing bidentate phosphine sulphide and selenide ligands

Summary The synthesis and properties of cationic complexes of general formula [ML₂{CH₂(Ph₂PE)₂}]BF₄, where M = Pd^II and Rh^II, L₂ = ³-MeC₃H₄, {P(O)(OR)₂}₂H (R = Me, Et), COD, (CO)₂, (CO)PPh₃ and E = S, Se are described. The methylene proton of the coordinated phosphine sulphide or selenide ligands react with strong bases as BuLi in n-hexane or NaH in THF, to give neutral complexes of the type [ML₂{CH(Ph₂PE)₂}], where M = Pd^II, Rh^I; L₂ = ³-MeC₃H₄, COD and E = S, Se. The complexes have been characterized by elemental analyses, molar conductivities, i.r., ¹H n.m.r. and ³¹P{¹H} n.m.r. spectroscopy.     

Tris(dimethylamino)phosphine Selenide Complexes of Cadmium(II): Synthesis and Multinuclear (31P, 77Se,and 113Cd) NMR Characterization in Solution

The complexes CdL₄(ClO₄)₂ (1), CdL₂(NO₃)₂ (2), and CdL₂Cl₂ (3) (L = (Me₂N)₃P(Se)) have been prepared and characterized by elemental analysis, conductivity measurements, IR, and multinuclear (³¹P, ⁷⁷Se, and ¹¹³Cd) NMR spectroscopy. ³¹P and ⁷⁷Se NMR data were informative of changes associated with complex formation. The structure of the prepared complexes was further confirmed in solution by their ¹¹³Cd NMR spectra, which show a quintuplet for the perchlorate complex and a triplet for each of the nitrate and chloride complexes due, respectively, to coupling with four and two equivalent phosphorus atoms, consistent with a four coordinate tetrahedral geometry for the cadmium center. The NMR data are discussed and compared with those reported for related complexes.     

The first coordination complexes of selenones: a structural comparison with complexes of sulfones

Reactivity of the two classes of very weak donors R(2)XO(2) (X = S, R = Me (1) and Ph (2); X = Se, R = Me (3) and Ph (4)) have been studied. Coordination properties of sulfones and selenones in solution and in the gas phase have been compared for the first time using a model bidentate metal complex, [Rh(2)(O(2)CCF(3))(4)]. Two coordination modes, bridging mu(2)-O,O' and terminal eta(1)-O, have been detected. These types of binding were realized in two series of sulfone and selenone metal complexes, polymeric mono-adducts [Rh(2)(O(2)CCF(3))(4).(R(2)XO(2))]( infinity ) (X = S, R = Me (1a); R = Ph (2a); X = Se, R = Ph (4a)) and discrete bis-adducts [Rh(2)(O(2)CCF(3))(4).(R(2)XO(2))(2)] (X = S, R = Ph (2b); X = Se, R = Me (3b)). The compositions and structures of new compounds have been confirmed by NMR and IR spectroscopy, chemical analyses, and X-ray diffraction studies. Compounds 3b and 4a are the first crystallographically characterized metal complexes having selenone ligands coordinated to the metal centers. Preparation and X-ray study of analogous metal complexes of sulfone and selenone ligands allow, for the first time, tracking the structural changes induced by metal coordination. In addition, the X-ray structure of dimethyl selenone, Me(2)SeO(2) (3), an analogue of Me(2)SO(2), has been determined. Geometries of coordinated sulfone and selenones ligands have been compared with those of the corresponding "free" molecules.     

Reactions of platinum(II) complexes with sulfur- and histidine-containing peptides: a model for selective platination of peptides and proteins

The reactions between two monofunctional platinum complexes [Pt(Me₄dien)Cl]⁺ (Me₄dien = 1,1,7,7-tetramethyl-diethylenetriamine) and [Pt(Et₄dien)Cl]⁺ (Et₄dien = 1,1,7,7-tetraethyldiethylenetriamine) and the peptides, N-acetylated L-methionyl-L-histidine (MeCO–Met–His) and glutathione (GSH), have been investigated by ¹H-n.m.r. spectroscopy and u.v.–vis. spectrophotometry. The reactions of the platinum(II) complexes with MeCO–Met–His were carried out at room temperature and at pH 3.0 and 7.0, whereas with GSH the reactions were studied only at pH 3.0. No binding of these two platinum complexes to the sulfur atom of methionine or to nitrogen atoms of histidine residue of MeCO–Met–His was observed during the first 24 h. When the reaction was followed further, after 24 h very slow binding of [Pt(Me₄dien)Cl]⁺ to the N3 nitrogen atom of imidazole was observed. Both platinum complexes react with the sulfur atom of the cysteine residue in GSH. Kinetic data show that GSH reacts twice as fast with [Pt(Me₄dien)Cl]⁺ than with [Pt(Et₄dien)Cl]⁺. Our findings indicate that sterically crowded platinum(II) complexes are only capable of reacting with the sulfhydryl group of the cysteine residue. This influences the design of new platinum(II) complexes for selective covalent modification of peptides and proteins.     

Pseudohalogeno-Metallverbindungen. LXXV. Pentacarbonylrhenium-und Triphenylphosphangold-Komplexe mit Pseudohalogeniden: (OC)5ReX,Ph3PAuX (X = ONC(CN)2, o-MeC6H4SO2C(CN)2,o-MeC6H4SO2NCN,Ph2(S)PNCN)

Pseudohalogeno Metal Compounds. LXXV. Pentacarbonylrhenium and Triphenylphosphinegold Complexes of Pseudohalide Anions: (OC)₅ReX, Ph₃PAuX (x = ONC(CN)₂, o-MeC₆H₄SO₂C(CN)₂, o-MeC₆H₄SO₂NCN, Ph₂(S)PNCN) The pseudohalides (X^?) nitrosodicyanmethanide, o-tosyldicyanmethanide, o-tosylcyanamide and diphenylthiophosphinylcyanamide react with the Organometallic Lewis Acids (OC)₅Re⁺ (as (OC)₅ReFBF₃) and Ph₃PAu⁺ (as Ph₃PAuNO₃) to give the neutral title complexes (OC)₅Re—X and Ph₃PAu? X, respectively. X-ray diffraction shows that nitroso-dicyanmethanide is coordinated through the nitroso N-atom to the Re(CO)₅ fragment. Cyanide-N-coordination is observed for the complexes with o-tosyldicyanmethanide and o-tosylcyanamide whereas diphenylthiophosphinylcyanamide is S-coordinated to the gold atom. Spectroscopic data (IR, NMR) of 1–6 are described.     

Preparation of novel palladium(II) complexes with dithiocarbimates from sulfonamides

Potassium N-R-sulfonyldithiocarbimates, K₂(RSO₂N=CS₂) (R = Me, Ph, 2-MeC₆H₄), react with Pd(OAc)₂ to yield complex anions bis(N-R-sulfonyldithiocarbimato)palladate(II), [Pd(RSO₂N=CS₂)₂]^2–, which were isolated as their n-Bu₄N⁺ salts. When the reaction was performed in the presence of Ph₃P in a 2:1 ratio with respect to Pd(OAc)₂, the N-R-sulfonyldithiocarbimatobis(triphenylphosphine)palladium(II) complexes were obtained. Elemental analyses, i.r. spectra and electronic spectra data were consistent with the formation of palladium–sulfur diamagnetic square planar complexes in the first case and mixed square planar complexes of palladium with Ph₃P and dithiocarbimates in the second case. The ¹H-n.m.r., ¹³C-n.m.r. and ³¹P-n.m.r. spectra showed the expected signals for the Bu₄N⁺ cation, Ph₃P and the dithiocarbimate moieties.     

Doping Sumanene with Both Chalcogens and Phosphorus(V): One‐Step Synthesis,Coordination, and Selective Response Toward AgI

Heterasumanenes 4 – 6 containing chalcogen (S, Se, and Te) and phosphorus atoms have been synthesized in a one‐pot reaction from trichalcogenasumanenes 1 – 3 by replacing one chalcogen atom with a P=S unit. The P=S unit makes 4 – 6 almost planar and shrinks the HOMO–LUMO gap as compared to 1 – 3 . The bonding between Ag⁺ and S atom on P=S brings about a distinct change to the optical properties of 4 – 6 ; 4 in particular shows a selective fluorescence response toward Ag⁺ with LOD of 0.21 μm . Compounds 4 – 6 form complexes with AgNO₃ to be ( 4 )₂?AgNO₃, ( 5 )₂?AgNO₃, and ( 6 )₂?(AgNO₃)₃. In complexes, the coordination between Ag⁺ and P=S is observed, which leads to shrinkage of C?P and C?X (X=S, Se, Te) bond lengths. As a result, 4 , 5 , and 6 are all bowl‐shaped in complexes with bowl‐depths reaching to 0.66 Å, 0.42 Å, and 0.40 Å, respectively. There are Ag?Te dative bonds between Ag⁺ and Te atom on telluorophene in ( 6 )₂?(AgNO₃)₃.     

Doping Sumanene with Both Chalcogens and Phosphorus(V): One‐Step Synthesis,Coordination, and Selective Response Toward AgI

Heterasumanenes 4 – 6 containing chalcogen (S, Se, and Te) and phosphorus atoms have been synthesized in a one‐pot reaction from trichalcogenasumanenes 1 – 3 by replacing one chalcogen atom with a P=S unit. The P=S unit makes 4 – 6 almost planar and shrinks the HOMO–LUMO gap as compared to 1 – 3 . The bonding between Ag⁺ and S atom on P=S brings about a distinct change to the optical properties of 4 – 6 ; 4 in particular shows a selective fluorescence response toward Ag⁺ with LOD of 0.21 μm . Compounds 4 – 6 form complexes with AgNO₃ to be ( 4 )₂?AgNO₃, ( 5 )₂?AgNO₃, and ( 6 )₂?(AgNO₃)₃. In complexes, the coordination between Ag⁺ and P=S is observed, which leads to shrinkage of C?P and C?X (X=S, Se, Te) bond lengths. As a result, 4 , 5 , and 6 are all bowl‐shaped in complexes with bowl‐depths reaching to 0.66 Å, 0.42 Å, and 0.40 Å, respectively. There are Ag?Te dative bonds between Ag⁺ and Te atom on telluorophene in ( 6 )₂?(AgNO₃)₃.     

The Effect of Hard and Soft Donors on Structural Motifs in (Isocyanide)gold(I) Complexes

Treatment of the (isocyanide)gold(I) species LAuCl (L=^tBuNC, 2,6‐Me₂C₆H₃NC) with 4‐mercaptobenzoic acid in the presence of NaOMe yields the complexes [Au(4‐SC₆H₄CO₂H)L] in good yield. Reaction of LAuCl with 2‐HSQn (Qn=quinoline) and 2‐HSPy (Py=pyridine) under the same conditions provides the thiolato compounds [Au(2‐SQn)L] and [Au(2‐SPy)L], respectively. A structural investigation of the pyridylthiolato compound revealed chains of molecules with alternating medium and long Au−Au interactions. Treatment of this compound with HBF₄ results in the cationic species [Au(2‐HSPy)(2,6‐Me₂C₆H₃NC)]⁺ as the BF₄⁻ salt. The same product is obtained on reaction of [AuCl(2,6‐Me₂C₆H₃NC)] with AgOTf followed by HSPy. Treatment of the gold(I) halide compounds LAuCl (L=^tBuNC, 2,6‐Me₂C₆H₃NC) with potassium 1,3,4‐thiadiazole‐2,5‐dithiolate (KSSSK) leads to the isolation of dinuclear thiolatogold complexes [(AuL)₂(SSS)]. These products go on to form insoluble polymers through loss of isocyanide on standing in solution. A single crystal of [{Au(^tBuNC)}₂(SSS)] was obtained and the subsequent structural analysis revealed one of the most complicated networks known based solely on aurophilic interactions. A good comparison to the ‘soft' S‐donation of the thiolato ligands was provided by the synthesis of a number of nitratogold(I)complexes with the anion bound through the ‘hard' O‐donor. Reaction of ⁱPrNC and CyNC with Au(tht)Cl provided the complexes [AuCl(ⁱPrNC)] and [AuCl(CyNC)], respectively. These compounds were found to yield the respective nitrato species [Au(NO₃)ⁱPrNC)] and [(Au(NO₃)(CyNC)] on treatment with AgNO₃. The nitrato complexes yielded single crystals enabling a structural investigation to be carried out. While [Au(NO₃)(CyNC)] has a more conventional structure with dimers aligned into strings with alternating short and long aurophilic bonding, [Au(NO₃)(ⁱPrNC)] has a unique structure based on strings of alternating, corner‐sharing Au₆ and Au₈ units with short Au−Au contacts in edge‐sharing Au₃ triangles.