Metal transplants, autografts, and allografts are currently used for the treatment of bone-related problems, but each comes with inherent limitations. However, advances in science and technology have underscored the need for the development of cost-effective, eco-friendly, and customized architectural scaffolds with desirable porosity and mechanical strength. Additionally, the synthesis of sustainable scaffolds using biowaste is being studied to decrease environmental pollution. Green fabrication of scaffolds has an inestimable influence on decreasing production costs and toxicity while increasing biological compatibility. With this motivation, in the present study, a 70S30C calcium silicate bioactive material (BM) was synthesized through a simple precipitation method, using recycled rice husk (as a silica source) and eggshells (as a calcium source). Further, the BM and turmeric powder (Tm) were impregnated onto cellulose-based cotton fabric (CF), considering its easy availability, flexibility, mechanical strength, and cost-effective nature. The prepared scaffolds were characterized using UV-visible spectroscopy, XRD, FTIR spectroscopy, SEM, and EDS mapping. Further,