Apart from N-heterocyclic carbenes (NHCs), compounds consisting of isoelectronic low-oxidation state heavier Group 14 elements, the so-called metallylene, have been attractive targets for fundamental research because of their ambiphilic character that is critical for bond activations. On top of that, such capability of accepting and donating electrons simultaneously makes them potential candidates toward catalytic reactions that are normally mediated by precious transition metals. The efficiency for metallylene (R2E:) in chemical bond activation process is heavily dependent on the energy difference between the filled in-plan metal-centered lone pair and the remaining vacant p orbital of the central divalent Group 14 element. While most of the synthetic efforts towards reactive metallylenes were devoted to the replacement of amino substituents with silyl or boryl group, enhancing the electrophilicity of metallylene through manipulating the π-donating ability of amino substituents is less explored. Herein, we have investigated two strategies to lower the energy of the vacant p orbital of stannylene and germylene by mitigating the E→N π-interaction. On one hand, we plan to block the mesomeric effect of amino groups by tethering the two nitrogen atoms with a strained ring system. On the other hand, we envisage that the concept of antiaromatic metallylene would be a good way to boost the electrophilicity of the E(II) centers.