Reviewing the Aging of Heart Muscle
Here, researchers review what is known of the aging of heart muscle, and what might be done about it. The heart is more vital to life than any other specific muscle tissue, and thus the panoply of late life dysfunctions and other manifestations of aging are well studied in this organ. Connecting the underlying mechanisms of aging to observed changes in function remains a work in progress, and will likely only advance significantly as therapies to address specific mechanisms of aging are developed and deployed. Consider the accelerated pace at which the understanding of cellular senescence in aging has advanced since the the first senolytic drugs were demonstrated in animal studies fifteen years ago, for example.
The heart, a vital organ, works without interruption and constantly adjusts to the ever-changing demands on our body. It adapts to physiological and pathological changes, including exercise and emotional state, as well as metabolic, respiratory, and vascular abnormalities. The pumping action of the heart is determined by the health of the myocardium, which undergoes changes with ageing that are both under-investigated and incompletely understood, potentially impacting our approach to pathological conditions. Here, the alterations in cellular, tissue, and gross physiological function of the heart with age are discussed.
At the molecular level, non-coding RNAs influence cellular senescence, and extracellular vesicles induce fibrosis through matrix remodelling. Mitochondrial dysfunction and altered fatty acid oxidation reduce cellular energetics, whilst accumulation of reactive oxygen species and steatosis, as well as telomere shortening coupled with reduced autophagy, limit the myocardium's regenerative capability. Loss of cardiomyocytes, combined with senescence, requires compensatory hypertrophy, inducing myocardial stiffness and altered muscle function. In addition to these direct alterations in myocardial characteristics with ageing, other factors that can affect the myocardium indirectly are addressed, including valve calcification, resulting in regurgitation and/or stenosis; vascular abnormalities, reducing compliance and exacerbating hypertension; fibrosis leading to cardiac arrhythmias; and autonomic dysregulation, reducing cardiac adaptability.
Finally, potential modulation of cardiac ageing is discussed whilst also addressing which senescent modifications should be considered as ageing-related physiological changes of the myocardium. A better understanding of myocardial ageing will differentiate physiological changes from early, preventable, and reversible pathological changes, consequently helping to optimize management of individuals with or at risk of myocardial disease by taking into account diverse trajectories of myocardial ageing.