Platinum(II) and Copper(II) complexes of asymmetric halogen-substituted [NNʹO] ligands: Synthesis, characterization, structural investigations and antiproliferative activity

“…As shown in Fig. 3, for various substituents, the energies of 3 MC states and MECP are similar, and the values are 68.49, 70.69, 68.75 and 70.97 kcal mol À1 , respectively. It is indicated that the energies of 3 MC states and MECP for monometallic Pt(II) complexes may rely on the bond strength of Pt-X (X = heteroatom) coordinate bonds.…”

“…1, T planar 1 and T bent 1 possess obviously different geometric characters, i.e., the spin densities are located on the main ligand and the acac ligand (auxiliary ligand), respectively. Hence, they can be classified as 3 ILCT-acac (intraligand charge transfer) and 3 ILCT-main ligands. Since the electron transition character is closely related to the structural change during the transition process 41 Besides, different main group substituents are also taken into account, and the computed results are exhibited in Fig.…”

“…The relative energies of T 1 states, TS, 3 MC and MECP for monometallic Pt(II) complexes With the purpose of exploring the temperature-dependent nonradiative decay processes, i.e., T 1 -TS -3 MC -MECP, the corresponding geometries are optimized or calculated. The potential energy profiles of the deactivation pathways constructed using these geometries are shown in Fig.…”

“…In the application of anticancer drugs, previous studies report that some derivatives have been conjugated to Pt(II) drugs to elicit promising anticancer effects. [1][2][3][4][5][6] The oxaliplatin scaffold was chosen based on the findings that tetracarboxylato Pt(IV) compounds are generally stable toward reduction. 7,8 This prodrug supposedly exists in its intact Pt(IV) form in the dark but is activated to release oxaliplatin and PPA under the irradiation of red light.…”

“…Fig.8Schematic potential energy profiles of the deactivation pathways for 2Pt-1, 2Pt-2 and 2Pt-3, respectively 3. ES refers to the T 1 excited state.…”

Theoretical investigation of triplet potential energy surfaces for (C^C*) cyclometalated platinum(ii) complexes and the corresponding control strategies

“…As shown in Fig. 3, for various substituents, the energies of 3 MC states and MECP are similar, and the values are 68.49, 70.69, 68.75 and 70.97 kcal mol À1 , respectively. It is indicated that the energies of 3 MC states and MECP for monometallic Pt(II) complexes may rely on the bond strength of Pt-X (X = heteroatom) coordinate bonds.…”

“…1, T planar 1 and T bent 1 possess obviously different geometric characters, i.e., the spin densities are located on the main ligand and the acac ligand (auxiliary ligand), respectively. Hence, they can be classified as 3 ILCT-acac (intraligand charge transfer) and 3 ILCT-main ligands. Since the electron transition character is closely related to the structural change during the transition process 41 Besides, different main group substituents are also taken into account, and the computed results are exhibited in Fig.…”

“…The relative energies of T 1 states, TS, 3 MC and MECP for monometallic Pt(II) complexes With the purpose of exploring the temperature-dependent nonradiative decay processes, i.e., T 1 -TS -3 MC -MECP, the corresponding geometries are optimized or calculated. The potential energy profiles of the deactivation pathways constructed using these geometries are shown in Fig.…”

“…In the application of anticancer drugs, previous studies report that some derivatives have been conjugated to Pt(II) drugs to elicit promising anticancer effects. [1][2][3][4][5][6] The oxaliplatin scaffold was chosen based on the findings that tetracarboxylato Pt(IV) compounds are generally stable toward reduction. 7,8 This prodrug supposedly exists in its intact Pt(IV) form in the dark but is activated to release oxaliplatin and PPA under the irradiation of red light.…”

“…Fig.8Schematic potential energy profiles of the deactivation pathways for 2Pt-1, 2Pt-2 and 2Pt-3, respectively 3. ES refers to the T 1 excited state.…”

Theoretical investigation of triplet potential energy surfaces for (C^C*) cyclometalated platinum(ii) complexes and the corresponding control strategies

Complexation-induced nanoarchitectonics of sulfonate cailx[4]resorcinol substituted at the upper rim by N-methyl-d-glucamine fragments: Morphological transition and in vitro anticancer activity

From Achiral Precursors to Copper Helical Coordination Polymers: Magnetic Properties and Electronic Structure