Abstract
Chemotherapy remains a cornerstone in breast cancer treatment, but poor drug targeting compromises its efficacy and exacerbates side effects. To optimize drug delivery, we developed a novel bacteria-propelled biomotor system, designated as LA@CaDGP, to enhance the tumor-specific drug delivery. The biomotor was engineered to load doxorubicin (DOX) and glucose oxidase (GOD) within mesoporous calcium carbonate nanoparticles (CaCO(3) NPs), which are conjugated to Lactobacillus acidophilus (L. acidophilus, LA) via a polydopamine (PDA) coating. Following tumor accumulation facilitated by bacterial tropism, the CaCO(3) component undergoes dissolution, releasing calcium ions that induce mitochondrial dysfunction and thereby potentiate the chemotherapeutic efficacy of DOX. Concurrently, the GOD-mediated glucose depletion effect synergistically enhances antitumor activity through metabolic intervention. In a mouse orthotopic breast cancer model, the LA@CaDGP group showed a tenfold higher DOX concentration in tumor tissues compared to conventional free DOX administration, while the DOX concentration in heart tissues was 24 times lower. Mice in the LA@CaDGP group achieved a median survival time of 50 days. Collectively, these findings collectively demonstrate that the LA@CaDGP biomotor constitutes a promising therapeutic platform for breast cancer, integrating multiple synergistic mechanisms: calcium overload-mediated cytotoxicity, conventional chemotherapy, and metabolic starvation therapy.