The experimental and theoretical study of a family of linear trimeric [NEt₄] {[Mn(L)]₂[M(CN)₆]} (M = Fe, Ru, Os) compounds is reported. All three complexes demonstrate slow relaxation of magnetization at low temperatures. The theoretical model for the explanation of the magnetic behavior (the magnetic susceptibility as a function of temperature and magnetization as a function of the applied magnetic field) includes the spin-orbital interaction acting within the ground²T₁ multiplet of the Fe^III, Ru^III or Os^III ion, the axial crystal field that splits this multiplet into an orbital singlet and orbital doublet, the zero-field splitting for the Mn^III ions, the isotropic exchange interaction in the M-Mn pairs as well as the intercluster interaction taken within the mean field approximation. The proposed model provides a good agreement between the observed and calculated magnetic behavior. The low-lying energy levels form the energy barriers for magnetization reversal for all examined compounds. The calculated heights of these barriers are close to the observed ones.