Amsterdam University Medical Centers, The Netherlands (W.J.P.).
RHJ Department of Veterans Affairs Medical Center, Medical University of South Carolina, Charleston (M.R.Z.).
Circ Res. 2021 May 14;128(10):1451-1467. doi: 10.1161/CIRCRESAHA.121.318159. Epub 2021 May 13.
In accordance with the comorbidity-inflammation paradigm, comorbidities and especially metabolic comorbidities are presumed to drive development and severity of heart failure with preserved ejection fraction through a cascade of events ranging from systemic inflammation to myocardial fibrosis. Recently, novel experimental and clinical evidence emerged, which strengthens the validity of the inflammatory/profibrotic paradigm. This evidence consists among others of (1) myocardial infiltration by immunocompetent cells not only because of an obesity-induced metabolic load but also because of an arterial hypertension-induced hemodynamic load. The latter is sensed by components of the extracellular matrix like basal laminin, which also interact with cardiomyocyte titin; (2) expression in cardiomyocytes of inducible nitric oxide synthase because of circulating proinflammatory cytokines. This results in myocardial accumulation of degraded proteins because of a failing unfolded protein response; (3) definition by machine learning algorithms of phenogroups of patients with heart failure with preserved ejection fraction with a distinct inflammatory/profibrotic signature; (4) direct coupling in mediation analysis between comorbidities, inflammatory biomarkers, and deranged myocardial structure/function with endothelial expression of adhesion molecules already apparent in early preclinical heart failure with preserved ejection fraction (HF stage A, B). This new evidence paves the road for future heart failure with preserved ejection fraction treatments such as biologicals directed against inflammatory cytokines, stimulation of protein ubiquitylation with phosphodiesterase 1 inhibitors, correction of titin stiffness through natriuretic peptide-particulate guanylyl cyclase-PDE9 (phosphodiesterase 9) signaling and molecular/cellular regulatory mechanisms that control myocardial fibrosis.
根据共病-炎症范式,共病,尤其是代谢共病,被认为通过一系列事件导致射血分数保留的心力衰竭的发生和严重程度增加,这些事件从全身炎症到心肌纤维化不等。最近出现了新的实验和临床证据,进一步证实了炎症/纤维化的假说。这些证据包括:(1)免疫活性细胞浸润心肌,不仅是因为肥胖引起的代谢负荷,还因为高血压引起的血流动力学负荷。后者被细胞外基质的成分(如基底膜层粘连蛋白)所感知,而后者又与心肌肌联蛋白相互作用;(2)循环促炎细胞因子诱导心肌细胞中诱导型一氧化氮合酶的表达。这导致心肌中降解蛋白的堆积,因为未折叠蛋白反应失败;(3)机器学习算法定义射血分数保留心力衰竭患者的表型组,这些患者具有独特的炎症/纤维化特征;(4)中介分析中明确的共病、炎症生物标志物和紊乱的心肌结构/功能与内皮细胞黏附分子表达之间的直接耦合,这在射血分数保留心力衰竭的早期临床前阶段(HF 阶段 A、B)已经很明显。这些新证据为射血分数保留心力衰竭的未来治疗方法铺平了道路,例如针对炎症细胞因子的生物制剂、使用磷酸二酯酶 1 抑制剂刺激蛋白泛素化、通过利钠肽-颗粒型鸟苷酸环化酶-PDE9(磷酸二酯酶 9)信号通路纠正肌联蛋白的僵硬以及控制心肌纤维化的分子/细胞调节机制。