Magnesium microspheres to enhance lipiodol-mediated transarterial chemo-embolization (TACE) of hepatocellular carcinoma: From bench to a pilot clinical study.

Abstract

e16204 Background: Transarterial chemoembolization (TACE) has been extensively used in clinic to treat unresectable hepatocellular carcinoma (HCC). However, arterial embolization would worsen the hostile physicochemical features in the tumor microenvironment (TME) by further reducing its pH and increasing hypoxia, leading to immunosuppressive TME and drug resistance. Methods: Magnesium microspheres (Mg MSs), acting as H2 donors and pH modulators, were prepared via gas atomization pulverization. Characterization included inverted optical microscopy, SEM, and XRD analysis. Their H2 generation and acid neutralization capabilities were confirmed. The Lip-Mg dispersion (Mg MSs dispersed in lipiodol) was tested for therapeutic efficacy in H22 murine liver tumor-bearing mice, 4T1, and CT26 subcutaneous tumor models, as well as in vivo interventional TAE therapy for rabbit orthotopic liver tumors. The modulated capacities of Lip-Mg in H2 gas generation, acid neutralization, and promotion of antitumor immune response were investigated in vivo. Finally, a single-center, single-arm, open-label trial (ChiCTR2200064999) evaluated the safety and efficacy of TACE treatment with Lip-Mg (M-TACE) in Chinese HCC patients. Results: Inverted optical microscopy and SEM images confirmed uniform, smooth Mg microspheres (~60 μm) with a grayish-white color. In acidic buffer (pH 6.4), Mg microspheres rapidly increased pH, as measured by pH meter or fluorescent probe. Lip-Mg treatment significantly inhibited tumor growth compared to controls, prolonging mouse survival by ~2-fold, validated in 4T1 and CT26 models. Ultrasonic and multispectral fluorescence imaging demonstrated Lip-Mg's ability to release H2 and neutralize pH in vivo, reversing the immunosuppressive tumor microenvironment. Clinical study showed manageable treatment-related adverse events, with no unexpected toxicities and negligible impact on serum magnesium levels, confirming the safety of Mg microspheres for M-TACE. According to mRECIST, M-TACE exhibited high CR (61.5%), PR (38.5%), and ORR (100%) rates, with an overall response rate and CR rate of 90% and 60%, respectively. Conclusions: Metallic Mg microspheres (~60 μm) were developed to enhance lipiodol-mediated TAE/TACE for HCC. When combined with lipiodol and injected, they neutralized the acidic TME, triggered hydrogen therapy, and reversed immunosuppression, effectively inhibiting tumor growth. Lip-Mg showed superior outcomes to lipiodol alone for TAE therapy, with M-TACE treatment exhibiting higher ORR and CR rates than cTACE. Post-M-TACE, adverse events were managed well without treatment discontinuations. Our study introduces Mg microspheres as a promising embolic device for M-TACE therapy, potentially improving TACE benefits. Clinical trial information: ChiCTR2100050327.