文獻引用產品：

bsm-30276A-PE |  mouse CD206 Rat mAb, PE conjugate | IF, FC

bs-20633R |  HMGB1 Rabbit pAb | IF

bsm-30151H-PerCp-Cy5.5 |  Mouse CD3e Hamster mAb, PerCp-Cy5.5 conjugated | FC

bs-0647R-FITC | CD4 Rabbit pAb, FITC conjugated | IF, FC

bsm-30396A-PE |  mouse CD8a Rat mAb, PE conjugate | IF, FC

bsm-2508R-FITC | CD11c Rabbit pAb, FITC conjugated | FC

bs-1035R-APC | CD86 Rabbit pAb, APC conjugated | FC

bs-2211R-PerCP-Cy5.5 | CD80 Rabbit pAb, PerCP-Cy5.5 conjugated | FC

bsm-54156R-APC | CD11b Recombinant Rabbit mAb, APC conjugated | Other

bsm-41204R-PerCP-Cy5.5 | ADGRE1 Recombinant Rabbit mAb, PerCP-Cy5.5 conjugated | Other

作者單位：哈爾濱工程大學

摘要：Low efficacy of immunotherapy due to the poor immunogenicity of most tumors and their insufficient infiltration by immune cells highlights the importance of inducing immunogenic cell death and activating immune system for achieving better treatment outcomes. Herein, ferroelectric Bi₂CuO₄ nanoparticles with rich copper vacancies (named BCO-V_Cu) are rationally designed and engineered for ferroelectricity-enhanced apoptosis, cuproptosis, and the subsequently evoked immunotherapy. In this structure, the suppressed recombination of the electron–hole pairs by the vacancies and the band bending by the ferroelectric polarization lead to high catalytic activity, triggering reactive oxygen species bursts and inducing apoptosis. The cell fragments produced by apoptosis serve as antigens to activate T cells. Moreover, due to the generated charge by the ferroelectric catalysis, this nanomedicine can act as “a smart switch" to open the cell membrane, promote nanomaterial endocytosis, and shut down the Cu⁺ outflow pathway to evoke cuproptosis, and thus a strong immune response is triggered by the reduced content of adenosine triphosphate. Ribonucleic acid transcription tests reveal the pathways related to immune response activation. Thus, this study firstly demonstrates a feasible strategy for enhancing the efficacy of immunotherapy using single ferroelectric semiconductor-induced apoptosis and cuproptosis.

文獻引用產品：

bs-20322R | CD31 Rabbit pAb | IF

bs-33009P | Recombinant GFP protein, His | Other

作者單位：四川大學

摘要：Large-scale and deep trauma restricts the effective hemostasis and tissue regeneration management, even causing death. The formation of the fibrin network is the initial stage of wound control. Inspired by Fn's characteristics during coagulation, an artificial polycationic fibroin (pCSF/β) is designed to achieve hemostasis-regeneration transition. pCSF/β replicates the aggregation state and maturation process of Fn through intermolecular interaction and subsequent strain hardening originating from ethanol-inducing β-sheet to recapitulate natural coagulation networks, achieving mechanical reinforcement and shape recovery. Proteomics and transcriptomics analyses reveal that pCSF/β connects hemostasis and regeneration through platelet contents’ release and the PI3K/Akt signaling pathway. The results of incompressible hemostasis, large-area skin repair, and penetrating liver regeneration in animal models such as minipigs confirm pCSF/β is superior to clinical products in rapid hemostasis and synchronous tissue regeneration. The molecular design of pCSF/β provides new insights for developing biomaterials in rapid hemostasis and simultaneous regeneration.