Dirhodium(II,II) Complexes as Electrocatalysts for CO₂ Reduction

Manamperi, Hemanthi D.

January 2020

No description available.

Chemistry

Dirhodium complexes

Reduction of carbon dioxide

Formic acid

Eelctrocatalysis

Investigation of Rh₂(II,II) complexes for applications in photochemotherapy and mismatch detection

Akhimie, Regina Nicole

January 2017

No description available.

Chemistry

Photodynamic therapy ,PDT

photochemotherapy ,PCT

dirhodium complexes

Molecular Modeling of Dirhodium Complexes

Debrah, Duke A

01 December 2014

Dirhodium complexes such as carboxylates and carboxylamidates are very efficient metal catalysts used in the synthesis of pharmaceuticals and agrochemicals. Recent experimental work has indicated that there are significant differences in the isomeric ratios obtained among the possible products when synthesizing these complexes. The relative stabilities of the Rh2(NPhCOCH3)4 tolunitrile complexes, Rh2(NPhCOCH3)4(NCC6H4CH3)2, were determined at the HF/LANL2DZ ECP, 6-31G and DFT/B3LYP/LANL2DZ ECP, 6-31G levels of theory using NWChem 6.3. The LANL2DZ ECP (effective core potential) basis set was used for the rhodium atoms and 6-31G basis set was used for all other atoms. Specifically, the o-tolunitrile, m-tolunitrile, and p-tolunitrile complexes of the 2,2-trans and the 4,0- isomers of Rh2(NPhCOCH3)4 were compared.

Density Functional Theory

Dirhodium Complexes

Molecular Modeling

Basis Set

Hartree-Fock Procedure

Schrodinger Equation

Chemistry

Structure Property Relationships for Dirhodium Antitumor Active Compounds: Reactions with Biomolecules and In Cellulo Studies

Aguirre-Flores, Jessica Dafhne

2009 December 1900

The molecular characteristics that affect the activity of various dirhodium complexes are reported. The importance of the axial position in the action of dirhodium compounds was studied. Three dirhodium complexes with increasing number of accessible axial coordination sites were synthesized and characterized. In cis-[Rh2(u-OAc)2(np)2]2+ (np = 1,8- naphthyridine) both axial sites are available for coordination, whereas for cis-[Rh2(u-OAc)2(np)(pynp)]+2 (pynp = 2-(2-pyridyl)1,8-naphthyridine) and cis-[Rh2(u-OAc)2(pynp)2]+2 the pyridyl arm on the ligand pynp blocks one and two axial sites, respectively. The availability of the axial positions affects the in vitro and in cellulo activity of these complexes demonstrating that open axial coordination sites are necessary for biological activity. The inhibitory activity of derivatives of dirhodium-dppz complexes (dppz = dipyrido[3,2-a:2',3'-c]phenazine) has also been investigated. The dppz derivatives included compounds with electron-withdrawing (Cl, CN, and NO2) as well as electro-donating (MeO and Me) substituents. These compounds inhibit transcription of T7-RNA polymerase by reducing accessible cysteine residues. The activity correlates with the electron withdrawing character of the substituent on the dppz ligand. Density functional theory (DFT) calculations reveal that the lowest unoccupied molecular orbitals (LUMOs) in the series are ligand-based pi* orbitals localized on the phenazine ring. These complexes represent the first family of dirhodium complexes whose inhibitory ability can be tuned by controlling their redox properties. The effect of the presence of diimine ligands in the dirhodium core in both in vitro and in cellulo activity is discussed. The presence of one diimine ligand allows for dual binding, intercalation and covalent, as observed by melting temperature and relative viscosity measurements, as well as electrophoretic mobility shift assay (EMSA). The mono-substituted dirhodium complexes are effective against HeLa and COLO-316 cell lines, with [Rh2(u-O2CCH3)2(n1-O2CCH3)(dppz)]+ being the most effective compound of the series. Results of the comet assay indicate that all of the monosubstituted complexes studied damage nuclear DNA, although in different degrees. The cytotoxic effect of these complexes is not affected by the presence of glutathione. The addition of the second diimine ligand hinders the ability of the complexes to damage DNA. The bis-substituted complexes are also slightly less cytotoxic than their mono-substituted congeners. Thus, the number of equatorial positions occupied by diimine ligands play a critical role in the mechanism of cytotoxicity of dirhodium(II,II) complexes. Finally, the results also demonstrate that improving the internalization of the dirhodium complexes can be achieved by co-incubation with cell penetrating peptides. This work provides a foundation for the preparation of new and more effective dirhodium complexes.

Dirhodium complexes

anticancer compounds

metal-metal bonded complexes

HeLa cells

COLO-316 cells

comet assay

Permeability of POPC bilayer by dirhodium complexes

Sears, Randy Bryan

10 December 2007

No description available.

Chemistry, Inorganic

Dirhodium complexes

Membrane Permeability

Photodynamic Therapy

SYBR Green I

Ab Initio and Semi-Empirical Calculations of Cyanoligated Rhodium Dimer Complexs

Asiri, Yazeed

01 May 2017

Molecular modeling, using both ab initio and semi-empirical methods has been undertaken for a series of dirhodium complexes in order to improve the understanding of the nature of the chemical bonding in this class of homogeneous catalysts. These complexes, with carboxylamidate and carboxylate ligands, are extremely functional metal catalysts used in the synthesis of pharmaceuticals and agrochemicals. The X-ray crystallography shows anomalies in the bond angles that have potential impact on understanding the catalysis. To resolve these issues, minimum energy structures of several examples (e.g. Rh2(NHCOCH3)4, Rh2(NHCOCH3)4NC, Rh2(CO2CH3)4, Rh2(CO2CH3)4NC, Rh2(CHO2)4, and Rh2(CHO2)4NC) were calculated using Hatree-Fock and Density Functional Theory/B3LYP with the LANL2DZ ECP (Rh), and cc-pVDZ (all other atoms) basis sets.

Molecular Modeling

Hartree-Fock Self Consistent Field

Density Functional Theory

Dirhodium Complexes

Computational

Atomic Units.

Other Chemistry

Physical Chemistry