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The efficacy of transarterial chemoembolization (TACE) has been limited by insufficient embolization and a high incidence of tumor recurrence. Herein, we identified that aberrant metabolic reprogramming and immunosuppression contribute to TACE refractoriness and Rhein, as a potential glycolytic metabolism inhibitor and immunoactivation inducer, was optimized to sensitize tumors to TACE therapy. To achieve efficient embolization, we developed an oil‐in‐water lipiodol embolic emulsion by stabilizing the self‐assembled Rhein nanogel. The assembled Rhein exhibited a nanofiber network, and its integration enhanced the mechanical stability and viscoelasticity of the lipiodol embolic agent. With the synergistic advantages of solid and liquid embolic agents, this carrier‐free Pickering emulsion exhibits efficient embolization and sustained drug release in models of unilateral renal artery embolization, rabbit ear tumor embolization, rabbit orthotopic liver cancer, and rat orthotopic liver cancer. Compared to conventional three‐way catheter mixing methods, multimodal imaging corroborates a marked enhancement in local drug retention and tumor suppression. Importantly, the incorporation of Rhein‐mediated synergistic immunoembolization in this strategy achieved efficient embolization while robustly activating anti‐tumor immune responses, including inducing immunogenic cell death, dendritic cell activation, and major histocompatibility complex class I presentation to CD8+ T cells for tumor killing. Together, these findings reveal a novel strategy for the application of self‐assembled Rhein nanofiber‐stabilized lipiodol emulsion to control metabolic signaling and immunoactivation in TACE.
The efficacy of transarterial chemoembolization (TACE) has been limited by insufficient embolization and a high incidence of tumor recurrence. Herein, we identified that aberrant metabolic reprogramming and immunosuppression contribute to TACE refractoriness and Rhein, as a potential glycolytic metabolism inhibitor and immunoactivation inducer, was optimized to sensitize tumors to TACE therapy. To achieve efficient embolization, we developed an oil‐in‐water lipiodol embolic emulsion by stabilizing the self‐assembled Rhein nanogel. The assembled Rhein exhibited a nanofiber network, and its integration enhanced the mechanical stability and viscoelasticity of the lipiodol embolic agent. With the synergistic advantages of solid and liquid embolic agents, this carrier‐free Pickering emulsion exhibits efficient embolization and sustained drug release in models of unilateral renal artery embolization, rabbit ear tumor embolization, rabbit orthotopic liver cancer, and rat orthotopic liver cancer. Compared to conventional three‐way catheter mixing methods, multimodal imaging corroborates a marked enhancement in local drug retention and tumor suppression. Importantly, the incorporation of Rhein‐mediated synergistic immunoembolization in this strategy achieved efficient embolization while robustly activating anti‐tumor immune responses, including inducing immunogenic cell death, dendritic cell activation, and major histocompatibility complex class I presentation to CD8+ T cells for tumor killing. Together, these findings reveal a novel strategy for the application of self‐assembled Rhein nanofiber‐stabilized lipiodol emulsion to control metabolic signaling and immunoactivation in TACE.
Background Hepatocellular carcinoma (HCC) remains a leading cause of cancer-related mortality, underscoring the need for novel therapeutic targets. This study aimed to elucidate the role of endoplasmic reticulum membrane protein complex subunit 1 (EMC1) in HCC progression and its therapeutic potential. Methods Publicly available sequencing data and biopsy specimens were analyzed to assess EMC’s clinical value and functions in HCC. In vitro experiments validated EMC functions, and multiplex immunofluorescence analysis examined EMC-associated sorafenib resistance mechanisms. EMC1 expression was knocked down in HCC cell lines, followed by cell viability, wound healing, and transwell migration assays. Tumor growth and response to sorafenib treatment were evaluated in mouse models. Metabolomic analysis assessed changes in the TCA cycle. Results EMC genes were aberrantly expressed in HCC, and high EMC1 expression correlated with poorer survival rates. EMC1 disruption enhanced HCC cells’ sensitivity to sorafenib, reducing cell viability, increasing apoptosis, and decreasing tumor size and weight. EMC1 maintained cancer cell stemness and promoted M2 macrophage infiltration. Metabolomic analysis revealed significant changes in the TCA cycle, indicating EMC1’s role in HCC metabolic reprogramming. Importantly, EMC1 is highly associated with sorafenib resistance, potentially linked to CTNNB1 mutation or activation. Conclusion EMC1 plays a critical role in regulating the sorafenib resistance in HCC. Targeting EMC1 may improve HCC treatment efficacy.
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