Four guanine bases are held together by Hoogsteen hydrogen bonds to form a square planar G-quartet. Two or more quartets may stack on top of each other to form a G-quadruplex. The presence of G-quadruplex plays a significant role in potentially leading to the shortening of chromosome ends in the cancer cells and regulating gene expression. The number of G-tracts and the number of guanine bases in the G-tract gives a variety of structural morphology of G-quadruplex. For example, Bcl2mid (d[5’-G3CGCG3AGAAG5CG3-3’]). Missing a G-tract hinders the formation of G-quadruplex and preserving a G-tract with 5 consecutive guanine bases favors the formation of high order. Nevertheless, the most common apparatus for G-quadruplex examination, CD spectrum has been challenged for its reliability. Our experiment results show the inadequacy in G-quadruplex inspection for CD spectrum only while missing a G-tract; however, CD spectrum may apply on monitoring structural conversion of G-quadruplex once it has been confirmed on NMR spectrum. Previously our lab observed the structural conversion of Bcl2mid from a monomer to a thermodynamic product, dimer, upon heating above melting temperature; however, we would like to mimic the human body temperature and molecular crowding environment to study the possible structural conversion for Bcl2mid. We applied copper ion to induce the unfolding on G-quadruplex and EDTA2- chelates the copper ion to make random coil refolding back to G-quadruplex at a constant temperature. We have utilized CD, gel electrophoresis, emulsion induced filtration to study possible structural conversion. As a result, the kinetic product of G-quadruplex, monomer, in physiological temperature dominates in a short period of G-quadruplex refolding time. This finding may lead to a further studies on screening small molecules for the dominated G-quadruplex structure in the cells for the potential candidate of anti-cancer drugs.