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We investigated the cis- and trans-isomers of Pt(NH_3)_2Cl_2 and [Pt(NH_3)_2]~(2+) using a quantum chemical non-empirical calculation method, the pseudopotcntial valence electron only ah initio method. The electronic structure and electrostatic potential counter maps were in turn determined through the wave functions so obtained. There was a sharp difference between the dipole moments of the cis- and trans-isomers. The electrostatic counter maps of the isomers also had remarkably different features. Based on the interaction between the platinum (Ⅱ) coordination compound and the base pairs of nucleic acid, the difference in antitumour activity of the isomeric compounds was discussed, It is pointed out that the key factor for antitumour activity is that the platinum (Ⅱ) coordination compound must be mutually complementary with the target acceptor in both configuration and bonding activity. This mutualcomplementary requirement includes a bonding ability of the platinum complex with two negative centers i
We investigated the cis- and trans-isomers of Pt (NH_3) _2Cl_2 and [Pt (NH_3) _2] ~ (2+) using a quantum chemical non-empirical calculation method, the pseudopotcntial valence electron only ah initio method. The electronic structure and electrostatic potential counter maps were in turn determined through the wave functions so obtained. There was a sharp difference between the dipole moments of the cis- and trans-isomers. The electrostatic counter maps of the isomers also had remarkably different features. Based on the interaction between the platinum (Ⅱ) coordination compound and the base pairs of nucleic acid, the difference in antitumor activity of the isomeric compounds was discussed, It is pointed out that the key factor for antitumor activity is that the platinum (Ⅱ) coordination compound must be mutually complementary with the target acceptor in both configuration and bonding activity. This mutual complication requirement includes a bonding ability of the platinum complex with tw o negative centers i