Controlling oxygen deficiencies is essential for the development of novel chemical and physical properties in strongly correlated oxides. In the recent dedaces, low-temperature topochemical reactions using metal hydrides (e.g., CaH₂) are known as a powerful method to lead to highly reduced oxides such as SrFeO₂ and LaNiO₂ although their applicability is limited due to uncontrollable product. In this work we use a combination of electrochemical protonation and thermal dehydration to synthesize highly reduced oxide. SrCoO_2.5 thin film is converted to SrCoO₂ by dehydration of HSrCoO_2.5 at 350 °C (Figure 1). SrCoO₂ represents the first perovskite-derived compound consisting only of tetrahedra, forming a four-legged spin tube. Upon heating, HSrCoO_2.5 with distorted octahedra gradually dehydrates (H_1-xCoO_2.5–x/2) and then switches to the one-dimensional spin tube structure. This suggests that ‘destabilization’ of the SrCoO_2.5 precursor by protonation drastically alters the reaction energy landscape. Given that electrochemical protonation has been applied to a variety of transition metal oxides, this simple process opens new avenues for exploring novel oxides.