Bioactive glass is a biomaterial commonly used in dental care products and bone tissue engineering applications due to its biocompatibility, bone-forming ability, and remineralization capability. Bioactive glasses form a hydroxyapatite-like layer on dentinal tubules by releasing calcium and phosphorus ions after interaction with saliva. Bioactive 45S5 glass traditionally synthesized by wet chemical methods which require high-temperature heating and the use of a strong acid catalyst, bringing into question of the possibility of introducing toxic acid residues into the final product. Therefore, there is a need to develop environmental-friendly bioactive glass synthesis methods or to modify existing ones in a way to uplift their environmental friendliness. To satisfy this need, we greenized the traditional sol-gel method by replacing the acid catalyst with an environment-friendly alternative and successfully used it for the synthesis of nanostructured 45S5 bioactive glass. First, physicochemical characterization of the synthesized bioactive glasses was performed. Then, the apatite formation capability of bioglasses were investigated in saliva. Next, the mineralization kinetics of bioglasses were tested in Ca/P buffer. In vitro toxicity tests were performed to assess the cytotoxic potential of the synthesized bioactive glass. All analyses were repeated for the traditional synthesis method for comparison purposes. The results confirmed that green synthesis is more advantageous in terms of bioactivity and functionality required for dental applications. Increasing the safety and functionality of bioglass at the same time during the production phase has critical importance for ensuring the sustainability of current applications as well as creating new uses in the biomedical field