Synthesis and evaluation of iminosugars as DNA binding agents

Johnson, Heather Aileen

January 2001

No description available.

547

Applications of pattern recognition and pattern analysis to molecule design

Robinson, Daniel D.

January 2000

No description available.

621.3994

Protein; Ligands

New calix[4]arene metal complexes

Dubberley, Stuart R.

January 2000

No description available.

546

Anionic; Ligands

Transition metal amidinate complexes as new catalysts for olefin polymerisation

Chi-Tien, Chen

January 2001

No description available.

546

Amidinato ligands

Mechanistic organometallic chemistry

Polywka, M. E. C.

January 1988

No description available.

547

Cationic carbene ligands

Studies in niobium imido chemistry

Humphries, Martin J.

January 1999

No description available.

546

Compounds; Ligands

The molecular pathology of the macrophage scavenger receptor

Gough, Peter Joseph

January 1999

No description available.

612

Glycoproteins; Ligands; Atherosclerosis

Isothiocyanate ligand derivatives of platinum(II) terpyridines.

Waldron, Bradley Peter.

January 2008

The novel compounds [Pt(trpy)(NCS)]SbF6 (1) and [Pt{4'-(Ph)trpy}(NCS)]SbF6 (2) where trpy = 2,2':6',2''-terpyridine, have been synthesised and characterised by means of elemental analysis, infrared and 1H NMR spectroscopy, and mass spectroscopy. Compounds 1 and 2 were also prepared with the labelled S13C15N¯ ion as co-ligand; their 13C and 15N NMR spectra recorded at room temperature in CD3CN show that the ambidentate ion is coordinated to the Pt atom mainly (~ 95%) through the N atom, but that a small amount of the S-bound isomer also co-exists in an acetonitrile solution. The synthesis of 1 is preceded by the isolation of yellow 1·CH3CN?Y (Y = yellow) for which the crystal structure has been determined by single crystal X-ray diffraction; this shows that the SCN¯ ion is linearly bound to the Pt atom through the N atom in the solid state, and that the cation is planar. The solvate rapidly loses acetonitrile to form maroon 1-M (M = maroon). The maroon compound exhibits 3MMLCT (metal-metal-to-ligand charge transfer) emission in the solid state as evidenced by a red-shift in the emission maximum from 653 nm at 473 K to 770 nm at 80 K. However, there are anomalous changes in the emission intensity below 200 K; this phenomenon is explained in terms of competitive emission by defect sites in the material. Interestingly, 1-M displays thermochromic behaviour (accompanied by phase changes at Ts > 473 K) that have been documented over the temperature range 80-548 K by means of photography, emission spectral and powder X-ray diffraction measurements. Compound 1-M also exhibits selective and reversible vapochromic behaviour with acetonitrile, DMF and pyridine – the solvates are yellow. We also report solvent specific changes in the emission spectra between 1-M and its acetonitrile, DMF and pyridine solvates. The thermo- and vapochromism of 1-M are linked to the making and breaking of metallophilic Pt...Pt interactions that occur when the planar cations slide in and out of different positions with respect to each other in a π-stack. Single crystals of compound 2 are isolated by desolvation of single crystals of 2·CH3CN. The single-crystal to single-crystal transformation is easily reversed by exposing 2 to vapours of acetonitrile, as confirmed by X-ray structure determinations of 2 and 2·CH3CN performed on the same single crystal. These show that the SCN¯ ion is linearly bound to the Pt atom through the N atom and that the cation is nearly planar. Significantly, there are only very small changes in the cation and anion atom positions between 2 and 2·CH3CN; thus, single crystals of 2 have a porous metal-organic structure with solvent accessible voids/channels. As such, 2 also sorbs methanol and acetone molecules from the vapour phase, the former without loss of single crystallinity, as confirmed by an X-ray crystal structure determination of 2·CH3OH. Single crystals of 2·(CH3)2CO were obtained by direct crystallization from acetone and an X-ray structure determination performed. Interestingly, a single crystal 2·(CH3)2CO desolvates under ambient conditions to give a single crystal of 2 with the original porous metal-organic crystal structure; on the other hand 2·CH3OH does not readily desolvate because of O─H◦◦◦S hydrogen-bonding. Compound 2 and its solvates are yellow, as expected, since the planar cations hardly move on solvent uptake – in marked contrast to the easily moved cations in 1─M – suggestions as to why are given. Finally, we report the solid state photoluminescence (measured at 77 K) of 2, 2·CH3CN, 2·CH3OH, 2·(CH3)2CO and 2·CH3OH_DS where DS denotes desolvation of the methanol solvate. Emission from 2 is characterised by dual emission from 3MLCT (metal-to-ligand charge transfer) and excimeric 3(π-π*) excited states; with the latter being the predominant origin of emission at 77 K. On the other hand, the 2·CH3CN and 2·(CH3)2CO solvates give well defined monomeric 3MLCT emission exclusively. The excimeric emission is representative of the cation packing arrangement in the crystal lattice, and the fact that it is not observed for 2·CH3CN and 2·(CH3)2CO is probably a result of an increase in the potential energy barrier to the formation of excimers when free space is occupied by CH3CN or (CH3)2CO included in the crystal lattice. Emission by 2·CH3OH and 2·CH3OH_DS is further complicated by 3MMLCT emission that arises because of dz2(Pt)-dz2(Pt) orbital interactions present in the solid. As a result multiple emission from 3MLCT, excimeric and 3MMLCT excited states is observed for 2·CH3OH and 2·CH3OH_DS. / Thesis (M.Sc.)-University of KwaZulu-Natal, Pietermaritzburg, 2008.

Platinum compounds.

Ligands.

Synthesis and characterization of gold (I) complexes of bis(diphenylphosphino)-acetonitrile.

Sithole, Sicelo Vincent.

January 2010

This study comprised the synthesis and characterization of select phosphine ligands and their complexation to gold(I). An initial approach was the reaction between Ph2PCl in "wet" organic solvent and [ClAu(tht)] (tht = tetrahydrothiophene) which led to the complex [ClAu{Ph2P(OH)}], 1, which was the second polymorph of this complex based on solid state Xray crystallographic studies. Related to the Ph2PCl precursor, the study refocused on the preparation of the ligand bis(diphenylphosphino)acetonitrile, (PPh2)2CHCN, ("dppm-CN"), 2, obtained from a modified literature method. Ligand 2 underwent a facile reaction with either [ClAu(tht)] or [(C6F5)Au(tht)] (molar ratio 1:2) to yield new open-ended dinuclear gold(I) complexes [(ClAu)2(dppm-CN)], 3, and [(C6F5Au)2(dppm-CN)], 4, respectively, both in satisfactory yield. Ligand 2 can also be deprotonated to form the anion [(PPh2)2CCN]¯ which reacted with [AuCl(tht)] (molar ratio 1:1) to form the neutral cyclic dinuclear gold(I) complex [Au2{(PPh2)2CCN}2], 5. The anion [(PPh2)2CCN··· showed unexpected reactivity behaviour toward mono- or bis(phosphine) gold(I) chloride complexes that led to the cleavage and formation of new Au-P bonds. Complexes 1, 3, 4, 5 were all subjected to a single crystal X-ray studies. Complex 1 has a central intermolecular Au···Au interaction of 3.0375(2) Å, and peripheral hydrogen bonding (O-H···Cl) within the structure. Complex 3 displays an intramolecular Au···Au interaction of 3.1669(4) Å, but no other intermolecular interactions. The structure of complex 4 reveals a side-by-side "dimer of dimers" structural motif in the solid state and represents a new type of system. Complex 4 contains intramolecular Au· · ·Au interactions alternating between 3.0902(7) Å and 3.0809(6) Å, and an intermolecular Au· · ·Au interaction of 3.592 Å. The next dimeric unit along the virtual 1D chain is more than 6 Å away. Complex 5 has an intramolecular Au···Au separation of 2.8650(4) Å and no intermolecular interactions. The C≡N bond in 5 is 1.160(7)° and is longer relative to the C≡N bond in complexes 3 and 4. The new complexes were further investigated by elemental analyses, mass spectrometry, 1H and 31P solution NMR, and FT-IR. The luminescence properties of the complexes was investigated in the solid state. Results showed 3 to be non- or very weakly emissive at room-temperature, the emission of 4 seems to be quenched by the C6F5 group at room temperature and qualitative results for 5 showed luminescence both at room temperature and at 77K. / Thesis (M.Sc.)-University of KwaZulu-Natal, Westville, 2010.

Gold.

Ligands.

Theses--Chemistry.

The application of novel multinuclear catalysts derived from dendrimeric ligands in the polymerization and oligomerization of unsaturated hydrocarbons.

Malgas, Rehana

January 2007

<p>G1 and G2 dendrimeric salicylaldimine ligands containing both substituted and unsubstituted aryl rings were synthesized via a Schiff base condensation of the appropriate salicylaldehyde and the peripheral amino groups of the corresponding G1 and G2 polypropyleneimine dendrimers. The new ligands were characterized using FTIR, 1H NMR and 13C NMR spectroscopy, elemental analysis and ESI mass spectrometry. The dendrimeric ligands were converted to multinuclear nickel complexes by reaction with nickelacetate. The metal complexes were characterized by FTIR spectroscopy, elemental analysis and ESI mass spectrometry.</p> <p>Some of the dendritic complexes were evaluated as catalyst precursors in the oligomerization of &alpha / -olefins such as ethylene and 1-pentene, using aluminium alkyls such as EtAlCl2 and modified methylaluminoxane (MMAO) as activators. All the dendrimeric catalysts evaluated are active in the oligomerization reactions. From the oligomerization results it was observed that there is a clear dendritic effect, in that both catalyst activity as well as selectivity are impacted by the dendrimer generation. In most cases it was observed that the second generation complexes show higher activity than the corresponding first generation complexes.</p> <p>The dendrimeric complexes were also evaluated as catalyst precursors in the vinyl polymerization of norbornene. In this case methylaluminoxane (MAO) were employed as an activator. Once again it was noted that a dendritic effect is operative, with second generation metallodendrimers having a higher activity than the first generation complexes.</p>

Ligands

Complex compounds.