The binary systems of Cu(II) and Al(III) complexes with adenosine triphosphate (ATP), phosphocreatine (PCr), glycine (gly), serine (Ser), tyrosine (Tyr) and threonine (Thr) and the ternary systems where La was ATP or PCr and Lb was one of the four amino acids, were investigated. The study was performed in aqueous solution using potentiometry, ultraviolet visible, Raman, NMR and EPR spectroscopies. The stability constants of the complexes were determined by potentiometry. When L is one of the amino acids, it can be observed that all the CuL complexes are more stable than the correspondent AlL complexes. This can be explained by the greater affinity between the Cu(II) and the amino group. On the other hand, the binary complexes formed by one of the phosphates (ATP or PCr) and Al(III) have greater values of log b than the correspondent complexes of Cu(II). This can be explained by the greater affinity of Al(III) ion to the oxygen atoms of the phosphates. For this same reason, all the ternary complexes of Al(III) are more stable than the Cu(II) ones. The values of the stability constants of the complexes could be divided in two groups: one of the binary complexes and the second of the ternary complexes, with higher values. For the Cu(II) complexes this behavior was confirmed by the decreasing of the maximum wavelength in the absorption spectra and the increasing of the A0 parameter as the stability constants increase. The maximum wavelength of the CuATPLb complexes were greater than those of the CuPCrLb complexes and this means that ATP must be bound to Cu(II) ion through two oxygen atoms of the phosphates, whereas in CuPCrLb complexes, PCr is bound through one oxygen atom and one nitrogen atom and the amino acid is the same. Values of DlogK (logbCuLaLb - (logbCuLa+ logbCuLb) showed that when La was ATP, the ternary complexes of Cu(II) and Al(III) were less stable than the binary ones suggesting that it does not occur any interaction between the ligands in the ternary complexes. When La was PCr, the stability constants of the Cu(II) complexes where Lb was Ser or Tyr were greater. This showed that these ligands favored more stable ternary complexes and this must be due to the interaction of the OH group of these amino acids and the phosphate or carboxylate of PCr. For the AlPCrLb complexes, when Lb was one of the four amino acids, the stability constants of the complexes were greater. This shows that in this case, the interaction cannot be between the OH groups of the amino acid since glycine does not have any OH group. Probably the interaction occur through the non coordinated oxygen of the phosphate of PCr and the hydrogen of the amino group of the aminoacid. The study of the sistem Al(III):Ser by Raman spectroscopy, showed that [Al(Ser)(H2O)4]2+is the predominant species and that Ser acts as bidentate ligand (N atom of the amino group and O atom of the carboxylate). This must be the behavior of all the complexes of Al(III) and the amino acids.