In the past several decades, molecular electronics have been widely discussed in many fields and extended metal atom chains (EMACs) are of considerable significance for their potential applications as molecular wires. In order to develop new generation of metal string complexes, two series of them, which contain fine tuning of ligands or a heterometallic framework, have been studied. Ligands such as oligo-α-pyridylamines and oligo-naphthyridylamine are usually used in the linear metal string complex, and another series of ligands made up of pyridyl and naphthyridyl moieties, are designed and used for the development of metal-string complexes. For the series, the shortest symmetrical ligand, 2,7-bis(α-pyridylamino)-1,8-naphthyridine (H2bpyany), has been used for the syntheses of a series of hexa-nuclear metal string complexes, [M6(μ6-bpyany)4X2](PF6)n (M = Ni, Co; X = Cl, NCS; n = 1, 2), and their structural characterizations, electrochemistry, and magnetic properties have been published. In the present work, we modified the published ligand, H2bpyany, replacing the 5-position hydrogen atom of pyridyl groups with phenyl groups and the pyridyl groups with pyrimidyl and pyrazine groups. Three fine-tune ligands, H2bphpyany, H2bphpmany, and H2bphpzany, were synthesized and used to synthesize nickel and cobalt metal-string complexes. In hexanickel metal-string complexes, four linear extended Ni chains complexes, [Ni6(bphpyany)4Cl2](PF6)2 (1), [Ni6(bphpyany)4Cl2](PF6) (2), [Ni6(bphpyany)4(NCS)2](PF6)2 (3), [Ni6(bphpmany)4Cl2](PF6)2 (4), and [Ni6(bphpmany)4Cl2](PF6) (5), have been synthesized using the modified H2bphpyany and H2bphpmany ligands, and their structures have been determined by single-crystal X-ray diffraction. The crystal structure of these complexes show that the Ni‒N and Ni‒Ni distances are similar with [Ni6(bpyany)4X2](PF6)n (X = Cl, NCS; n = 2, 1) in the literature. The temperature dependent magnetic measurements performed on two independent high-spin nickel(II) ions of 1, 3, and 4, demonstrating that metal strings are antiferromagnetic. Complexes 2 and 5 contain two independent high-spin nickel(II) ions like 1 and one mixed-valence Ni23+, displaying that it is paramagnetic. In the second part, five hexacobalt metal-string complexes, [Co6(bphpyany)4(NCS)2](PF6) (6), [Co6(bphpyany)4(NCS)2](PF6)2 (7), [Co5(bphpzany)4(NCS)2] (8), [Co5(bphpzany)4(OTf)2] (9), [Co6(bphpzany)4(NCS)2](PF6) (10), supported by four bphpyany2- or bphpzany2- ligands have been synthesized, and characterized. The structure of complexes 8 and 9 consist of two lantern-type dinuclear Co2 fragments at the terminal positions and one rare octacoordinated cobalt at the centre forming a linear [Co2…Co…Co2] chain. The magnetic susceptibility measurements show a quartet ground state with a significant spin-orbital contribution of the centre Co(II) ion. Complexes 6 and 10 consist of a linear Co611+ configuration wrapped by four ligands and their magnetic susceptibility measurement reveal a spin-crossover process (S = 1/2 ⇆ S = 3/2). The structure of 7 is similar with 6, and its magnetic behavior measurement reveals paramagnetism. In the study of single molecular conductance, defective pentacobalt and fully delocalized hexacobalt atom chains also do not show any difference. We use the theoretical calculation, Extended Hückel method, to analyze the consisting of molecular orbitals and the distributing of bond order about 8 and 10, and successfully explain the interesting phenomenon.