Hole site-based interactions in the trigonal bipyramidal geometrical structure of hypervalent pnicogen, halogen, and aerogenbearing molecules with pyridine and NCH Lewis bases (LBs) were comparatively examined. In this respect, the ZF 5 •••, XF 3 O 2 •••, and AeF 2 O 3 •••LB complexes (where Z = As, Sb; X = Br, I; Ae = Kr, Xe; and LB = pyridine and NCH) were investigated. The electrostatic potential (EP) analysis affirmations outlined the occurrence of σ-holes on the systems under consideration with disparate magnitudes that increased according to the following order: AeF 2 O 3 < XF 3 O 2 < ZF 5 . In line with EP outcomes, the proficiency of σ-hole site-based interactions increased as the atomic size of the central atom increased with a higher favorability for the pyridine-based complexes over NCH-based ones. The interaction energy showed the most favorable negative values of −35.97, −44.53, and −56.06 kcal/mol for the XeF 2 O 3 •••, IF 3 O 2 •••, and SbF 5 •••pyridine complexes, respectively.The preferentiality pattern of the studied interactions could be explained as a consequence of (i) the dramatic rearrangement of ZF 5 molecules from the trigonal bipyramid geometry to the square pyramidal one, (ii) the significant and tiny deformation energy in the case of the interaction of XF 3 O 2 molecules with pyridine and NCH, respectively, and (iii) the absence of geometrical deformation within the AeF 2 O 3 •••pyridine and •••NCH complexes other than the XeF 2 O 3 •••pyridine one. Quantum theory of atoms in molecules and noncovalent interaction index findings reveal the partially covalent nature of most of the investigated interactions. Symmetry−adapted perturbation theory affirmations declared that the electrostatic component was the driving force beyond the occurrence of the considered interactions. The obtained findings will help in improving our understanding of the effect of geometrical deformation on intermolecular interactions.