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Query: UMLS:C0018801 (heart failure)
 72,216 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The normal aging process is often accompanied by arterial wall stiffening and by a decrease in myocardial compliance. These processes contribute to isolated systolic hypertension and diastolic heart failure, which lead to substantial morbidity and mortality among older individuals. Patients with diabetes manifest arterial stiffening and diastolic dysfunction at a younger age. This leads to the concept that the mechanism that underlies changes in vascular mechanical properties during aging is accelerated in diabetes. The Maillard reaction or advanced glycation of proteins occurs slowly in vivo with normal aging and at an accelerated rate in diabetes. Advanced glycation end-products (AGEs) that form during the Maillard reaction are implicated in the complications of aging and diabetes. The formation of AGEs on vascular wall and myocardial collagen causes cross-linking of collagen molecules to each other. This leads to the loss of collagen elasticity, and subsequently a reduction in arterial and myocardial compliance. Aminoguanidine, an inhibitor of AGE formation, is effective in slowing or preventing arterial stiffening and myocardial diastolic dysfunction in aging and diabetic animals. In aged and diabetic animals, agents that can chemically break pre-existing cross-linking of collagen molecules are capable of reverting indices of vascular and myocardial compliance to levels seen in younger or non-diabetic animals. These studies suggest that collagen cross-linking is a major mechanism that governs aging and diabetes-associated loss of vascular and cardiac compliance. The development of AGEs cross-link breakers may have important role for future therapy of isolated systolic hypertension and diastolic heart failure in these conditions.
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PMID:Cross-linking of glycated collagen in the pathogenesis of arterial and myocardial stiffening of aging and diabetes. 1254 24

Heart failure (HF) is associated with increased large conduit artery stiffness and afterload resulting in stiffening of the coronary arteries. Perivascular adipose tissue (PVAT) and advanced glycation end products (AGE) both promote arterial stiffness, yet the mechanisms by which coronary PVAT promotes arterial stiffness and the efficacy of exercise to prevent coronary stiffness are unknown. We hypothesized that both chronic continuous and interval exercise training would prevent coronary PVAT-mediated AGE secretion and arterial stiffness. Yucatan miniature swine were divided into four groups: control-sedentary (CON), aortic banded sedentary-heart failure (HF), aortic banded HF-continuous exercise trained (HF+CONT), and aortic banded HF-interval exercise trained (HF+IT). The left circumflex and right coronary arteries underwent ex vivo mechanical testing, and arterial AGE, elastin, and collagen were assessed. Coronary elastin elastic modulus (EEM) and elastin protein were lower and AGE was increased with HF compared with CON, which was prevented by both HF+CONT and HF+IT. Mouse aortic segments treated with swine coronary PVAT conditioned medium had lower EEM and elastin content and greater AGE secretion and arterial AGE accumulation in HF compared with CON, which was prevented by both HF+CONT and HF+IT. Aminoguanidine (AMG), an AGE inhibitor, prevented the reduction in EEM, arterial elastin content, and AGE accumulation in mouse aortic segments treated with PVAT conditioned medium in the HF group. Our data demonstrate efficacy for chronic continuous and interval exercise to prevent coronary artery stiffness via inhibition of PVAT-derived AGE secretion in a preclinical miniswine model of pressure overload-induced HF.NEW & NOTEWORTHY Our findings show that chronic continuous and interval exercise training regimens prevent coronary artery stiffness associated with inhibition of perivascular adipose tissue-derived advanced glycation end products in a translational pressure overload-induced heart failure model potentially providing an effective therapeutic option for heart failure patients.
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PMID:Chronic exercise training prevents coronary artery stiffening in aortic-banded miniswine: role of perivascular adipose-derived advanced glycation end products. 3129 62