Anticoagulant therapy without bleeding: A novel molybdenum‐based nanodots alleviate lethal coagulation in bacterial sepsis by inhibiting ROS‐facilitated caspase‐11 activation

SmartMat Pub Date : 2024-01-19 DOI:10.1002/smm2.1264
Chuang Yuan, Qicai Xiao, Qiaohui Chen, Qiong Huang, K. Ai, Xinyu Yang
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Abstract

Sepsis is a leading cause of death worldwide. This syndrome is commonly accompanied by overactivation of coagulation, excessive reactive oxygen species (ROS), and inflammatory cytokine storm. Notably, disseminated intravascular coagulation (DIC) accounts for around 40% of sepsis‐associated deaths. However, anticoagulant therapy is still difficult for sepsis treatment because of the lethal bleeding side effects. Although the relationship between ROS and inflammatory cytokine storm has been described clearly, the pathogenic role of ROS in DIC, however, is still unclear, which renders novel therapeutic approaches hard to achieve bedside for inhibiting DIC. Herein, our new finding reveals that ROS greatly facilitates the entry of lipopolysaccharide (LPS) into the macrophage cytoplasm, which subsequently activates the caspase‐11/gasdermin D pathway, and finally induces DIC through phosphatidylserine exposure. Based on this finding, novel gallic acid‐modified Mo‐based polyoxometalate dots (M‐dots) with outstanding antioxidant activity are developed to provide ideal and efficient inhibition of DIC. As expected, M‐dots are capable of markedly inhibiting sepsis‐caused coagulation, organ injury, and death in sepsis. This therapeutic strategy, blocking the upstream pathway of coagulation rather than coagulation itself, can avoid the side effects of extensive bleeding caused by conventional anticoagulation therapy, and will provide a new avenue for the efficient treatment of sepsis.
抗凝治疗不出血:新型钼基纳米点通过抑制 ROS 促成的 caspase-11 激活缓解细菌性败血症中的致命凝血作用
败血症是全球死亡的主要原因。这种综合征通常伴有凝血过度激活、活性氧(ROS)过多和炎症细胞因子风暴。值得注意的是,弥散性血管内凝血(DIC)约占败血症相关死亡病例的 40%。然而,由于致命的出血副作用,抗凝疗法仍难以用于败血症治疗。尽管 ROS 与炎性细胞因子风暴之间的关系已被清楚描述,但 ROS 在 DIC 中的致病作用仍不明确,这使得抑制 DIC 的新型治疗方法难以在床边实现。在此,我们的新发现揭示了 ROS 可极大地促进脂多糖(LPS)进入巨噬细胞胞质,进而激活 Caspase-11/gasdermin D 通路,最后通过磷脂酰丝氨酸暴露诱导 DIC。基于这一发现,新型没食子酸改性钼基多氧代金属酸盐点(M-点)应运而生,它具有出色的抗氧化活性,能理想、高效地抑制 DIC。正如预期的那样,M-点能够显著抑制败血症引起的凝血、器官损伤和死亡。这种阻断凝血上游途径而非凝血本身的治疗策略,可以避免传统抗凝疗法造成的大出血副作用,为脓毒症的高效治疗提供了一条新途径。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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