Institute of Computer-Assisted Cardiovascular Medicine (N.B., J.E., I.W., S.N., M. Kelm, L.G., M.S., A.H., T.K.), Charité-Universitätsmedizin Berlin, corporate member of Freie Universität Berlin, and Humboldt-Universität zu Berlin, Germany.
Institute of Biochemistry (J.E., I.W., H.-G.H.), Charité-Universitätsmedizin Berlin, corporate member of Freie Universität Berlin, and Humboldt-Universität zu Berlin, Germany.
Circulation. 2021 Dec 14;144(24):1926-1939. doi: 10.1161/CIRCULATIONAHA.121.055646. Epub 2021 Nov 11.
Many heart diseases can result in reduced pumping capacity of the heart muscle. A mismatch between ATP demand and ATP production of cardiomyocytes is one of the possible causes. Assessment of the relation between myocardial ATP production (MV) and cardiac workload is important for better understanding disease development and choice of nutritional or pharmacologic treatment strategies. Because there is no method for measuring MV in vivo, the use of physiology-based metabolic models in conjunction with protein abundance data is an attractive approach.
We developed a comprehensive kinetic model of cardiac energy metabolism (CARDIOKIN1) that recapitulates numerous experimental findings on cardiac metabolism obtained with isolated cardiomyocytes, perfused animal hearts, and in vivo studies with humans. We used the model to assess the energy status of the left ventricle of healthy participants and patients with aortic stenosis and mitral valve insufficiency. Maximal enzyme activities were individually scaled by means of protein abundances in left ventricle tissue samples. The energy status of the left ventricle was quantified by the ATP consumption at rest (MV[rest]), at maximal workload (MV[max]), and by the myocardial ATP production reserve, representing the span between MV(rest) and MV(max).
Compared with controls, in both groups of patients, MV(rest) was increased and MV(max) was decreased, resulting in a decreased myocardial ATP production reserve, although all patients had preserved ejection fraction. The variance of the energetic status was high, ranging from decreased to normal values. In both patient groups, the energetic status was tightly associated with mechanic energy demand. A decrease of MV(max) was associated with a decrease of the cardiac output, indicating that cardiac functionality and energetic performance of the ventricle are closely coupled.
Our analysis suggests that the ATP-producing capacity of the left ventricle of patients with valvular dysfunction is generally diminished and correlates positively with mechanical energy demand and cardiac output. However, large differences exist in the energetic state of the myocardium even in patients with similar clinical or image-based markers of hypertrophy and pump function. Registration: URL: https://www.clinicaltrials.gov; Unique identifiers: NCT03172338 and NCT04068740.
许多心脏病可导致心肌泵血能力下降。心肌细胞的 ATP 需求与产生不匹配是可能的原因之一。评估心肌 ATP 产生 (MV) 与心脏工作量之间的关系对于更好地了解疾病的发展和选择营养或药物治疗策略非常重要。由于目前尚无测量 MV 的体内方法,因此结合蛋白质丰度数据使用基于生理学的代谢模型是一种很有吸引力的方法。
我们开发了一种全面的心脏能量代谢动力学模型 (CARDIOKIN1),该模型重现了使用分离的心肌细胞、灌注动物心脏以及对人类进行体内研究获得的大量有关心脏代谢的实验发现。我们使用该模型评估了健康参与者和主动脉瓣狭窄及二尖瓣关闭不全患者的左心室能量状态。通过左心室组织样本中的蛋白质丰度对最大酶活性进行个体缩放。通过休息时的 ATP 消耗 (MV[rest])、最大工作量时的 MV[max]和代表 MV[rest]和 MV[max]之间跨度的心肌 ATP 产生储备来量化左心室的能量状态。
与对照组相比,两组患者的 MV[rest]均增加,MV[max]均降低,导致心肌 ATP 产生储备减少,尽管所有患者的射血分数均正常。能量状态的变异性很高,范围从降低到正常值。在两组患者中,能量状态均与机械能量需求密切相关。MV[max]的降低与心输出量的降低相关,表明心脏功能和心室的能量性能紧密耦合。
我们的分析表明,瓣膜功能障碍患者的左心室 ATP 产生能力通常降低,并且与机械能量需求和心输出量呈正相关。但是,即使在具有相似的临床或基于图像的肥大和泵功能标志物的患者中,心肌的能量状态也存在很大差异。
网址:https://www.clinicaltrials.gov;独特标识符:NCT03172338 和 NCT04068740。
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