在抑制哺乳动物雷帕霉素靶标(mTOR)的背景下,多模式核因子-红细胞生成素-2相关因子(NRF2)疗法可重编烧伤和吸入联合损伤后的急性全身和肺部免疫反应。

IF 2.7 3区 医学 Q2 CRITICAL CARE MEDICINE SHOCK Pub Date : 2024-08-21 DOI:10.1097/SHK.0000000000002466
Matthew D Alves, Ryan A Clark, Denise A Hernandez, Madelyn P Bucci, Duo Chen, Philip A Efron, Shannon M Wallet, Ben G Keselowsky, Robert Maile
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引用次数: 0

摘要

摘要:严重烧伤导致急性和慢性感染易感性,这主要归因于过度炎症反应和慢性抗炎反应。并发吸入性损伤(B+I)会引起气道炎症。肺巨噬细胞和中性粒细胞 "亢奋",活性氧(ROS)和氮种(RONS)活性增加,但无法清除感染,激活后造成气道损伤。核因子-红细胞-2 相关因子(NRF2)是一种重要的免疫调节成分,激活后可诱导代偿性抗炎途径。另一方面,抑制哺乳动物雷帕霉素靶标(mTOR)可减少促炎反应。这些靶点的治疗用途有限,因为已知的这些通路调节剂不溶于生理盐水,需要长期给药。我们制作了一种生物相容的 NRF2 激动剂(CDDO)和雷帕霉素(RAPA)聚乳酸-共聚乙醇酸(PLGA)微颗粒(MP),并假设这种微颗粒能减轻小鼠 B + I 损伤模型中的急性高炎症反应。BI 损伤小鼠在损伤一小时后接受 CDDO-MP,或同时接受 CDDO-MP 和 RAPA-MP(Combo-MP)治疗,在损伤 48 小时后,肺部和全身免疫基因及其相关免疫通路的激活模式发生了显著变化。例如,与未经处理或 CDDO-MP 处理的小鼠相比,Combo-MP 处理的小鼠的炎症基因表达明显减少。我们还假设,Combo-MP疗法会在损伤后迅速降低细菌的易感性。BI 受伤小鼠在受伤一小时后接受 Combo-MP,48 小时后接种铜绿假单胞菌(PAO1),感染 48 小时后处死,与未接受治疗的 B + I 小鼠相比,肺部和肝脏中的细菌数量明显减少。在感染减少的同时,肺和血浆细胞因子谱也发生了显著变化,肺和脾细胞的免疫功能也发生了重编程。我们的研究结果有力地表明,基于 MP 的多模式疗法在烧伤后重塑免疫反应方面大有可为,尤其是通过减轻高炎症阶段和防止随后的感染易感性。
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Multimodal Nuclear Factor-Erythroid-2-Related Factor (NRF2) Therapy in the Context of Mammalian Target of Rapamycin (mTOR) Inhibition Reprograms the Acute Systemic and Pulmonary Immune Response after Combined Burn and Inhalation Injury.

Abstract: Severe burn injuries induce acute and chronic susceptibility to infections, which is largely attributed to a hyper-pro-inflammatory response followed by a chronic anti-inflammatory response. Concurrent inhalation injury (B + I) causes airway inflammation. Pulmonary macrophages and neutrophils are "hyperactive" with increased reactive oxygen (ROS) and nitrogen species (RONS) activity, but are unable to clear infection, causing airway damage upon activation. Nuclear Factor-Erythroid-2-Related Factor (NRF2) is a critical immunomodulatory component that induces compensatory anti-inflammatory pathways when activated. On the other hand, inhibition of Mammalian Target of Rapamycin (mTOR) reduces pro-inflammatory responses. The therapeutic use of these targets is limited, as known modulators of these pathways are insoluble in saline and require long-term administration. A biocompatible NRF2 agonist (CDDO) and rapamycin (RAPA) poly (lactic-co-glycolic acid) (PLGA) microparticles (MP) were created, which we hypothesized would reduce the acute hyper-inflammatory response in our murine model of B + I injury. BI-injured mice that received CDDO-MP or both CDDO-MP and RAPA-MP (Combo-MP) an hour after injury displayed significant changes in the activation patterns of pulmonary and systemic immune genes and their associated immune pathways 48 h after injury. For example, mice treated with Combo-MP showed a significant reduction in inflammatory gene expression compared to untreated or CDDO-MP-treated mice. We also hypothesized that Combo-MP therapy would acutely decrease bacterial susceptibility after injury. BI-injured mice that received Combo-MP an hour after injury, inoculated 48 h later with Pseudomonas aeruginosa (PAO1), and sacrificed 48 h after infection, displayed significantly decreased bacterial counts in the lungs and liver versus untreated B + I mice. This reduction in infection was accompanied by significantly altered lung and plasma cytokine profiles and immune reprogramming of pulmonary and splenic cells. Our findings strongly suggest that multimodal MP-based therapy holds considerable promise for reprogramming the immune response after burn injuries, particularly by mitigating the hyper-inflammatory phase, and preventing subsequent susceptibility to infection.

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来源期刊
SHOCK
SHOCK 医学-外科
CiteScore
6.20
自引率
3.20%
发文量
199
审稿时长
1 months
期刊介绍: SHOCK®: Injury, Inflammation, and Sepsis: Laboratory and Clinical Approaches includes studies of novel therapeutic approaches, such as immunomodulation, gene therapy, nutrition, and others. The mission of the Journal is to foster and promote multidisciplinary studies, both experimental and clinical in nature, that critically examine the etiology, mechanisms and novel therapeutics of shock-related pathophysiological conditions. Its purpose is to excel as a vehicle for timely publication in the areas of basic and clinical studies of shock, trauma, sepsis, inflammation, ischemia, and related pathobiological states, with particular emphasis on the biologic mechanisms that determine the response to such injury. Making such information available will ultimately facilitate improved care of the traumatized or septic individual.
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