Effects of Catecholamine Stress on Diastolic Function and Myocardial Energetics in Obesity

Rider, Oliver J; Francis, Jane M; Ali, Mohammed K.; Holloway, Cameron; Pegg, Tammy; Robson, Matthew D.; Tyler, Damian J.; Byrne, James P.; Clarke, Kieran; Neubauer, Stefan

doi:10.1161/circulationaha.111.069518

Cited by 122 publications

(114 citation statements)

References 40 publications

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“…Furthermore, obesity, DMII and IR can have direct adverse effects on myocardial structure and function independently of common confounders as hypertension or coronary artery disease, which has been referred to as "obesity" [116], "diabetic" [117] or "insulin-resistant" [118] cardiomyopathy. Adverse myocardial structural and functional changes induced by obesity, DMII and IR include myocardial hypertrophy and fibrosis [119][120][121], reduced myocardial energetic reserve [122][123][124], impaired myocardial relaxation [115,125] and increased diastolic LV [72] and cardiomyocyte stiffness [126]. Metabolic risk factors are strongly associated with myocardial and systemic inflammation, oxidative stress and endothelial dysfunction [116][117][118], which importantly contribute to myocardial dysfunction and remodeling and result in downregulation of NO-cGMP-PKG signaling [127,128].…”

Section: Metabolic Risk Factorsmentioning

confidence: 99%

“…Impaired myocardial relaxation results from obesity-induced myocardial mitochondrial dysfunction, lipotoxicity, uncoupled oxidative phosphorylation and disturbed cardiomyocyte calcium handling [135]. Compared to normal weight subjects, obese individuals had impaired myocardial energetics (phosphocreatine/ATP ratio) and diastolic filling rate at rest, which further deteriorated after inotropic stress [123]. Myocardial blood flow, as measured by PET, was significantly reduced in obese postmenopausal women, which was negatively correlated with waist/hip ratio [136].…”

Section: Overweight/obesitymentioning

confidence: 99%

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Impact of Comorbidities on Myocardial Remodeling and Dysfunction In Heart Failure with Preserved Ejection Fraction

Heerebeek

Paulus²

2014

SOJPPS

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Section: Metabolic Risk Factorsmentioning

confidence: 99%

Section: Overweight/obesitymentioning

confidence: 99%

Impact of Comorbidities on Myocardial Remodeling and Dysfunction In Heart Failure with Preserved Ejection Fraction

Heerebeek

Paulus²

2014

SOJPPS

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“…23,29 It has been shown that in animal models of obesity 35 and in humans with no other co-morbidity, abnormally low PCr/ATP ratios occur at rest, potentially due to, in addition to changes in substrate utilization, a loss of the total creatine pool in proportion to the loss of PCr, as occurs in many other forms of hypertrophy. 1,[78][79][80][81] Furthermore, this has been linked to altered cardiac diastolic function and is exacerbated during catecholamine stress. 80 …”

Section: Cardiac Energetics and Obesitymentioning

confidence: 99%

“…1,[78][79][80][81] Furthermore, this has been linked to altered cardiac diastolic function and is exacerbated during catecholamine stress. 80 …”

Section: Cardiac Energetics and Obesitymentioning

confidence: 99%

“…7 Cardiac metabolism and ATP production is altered in obesity and has emerged as a candidate mechanism to explain the increase in heart failure in this population. 8 Indeed, it has recently been shown that obesity, in the absence of co-morbidities, is linked to impaired myocardial high-energy phosphate metabolism 9 and diastolic dysfunction, [10][11][12] both markers of increased cardiovascular risk, 13 providing a mechanistic link between altered myocardial energy production and mortality.…”

Section: Introductionmentioning

confidence: 99%

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Myocardial substrate metabolism in obesity

et al. 2012

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Obesity is linked to a wide variety of cardiac changes, from subclinical diastolic dysfunction to end-stage systolic heart failure. Obesity causes changes in cardiac metabolism, which make ATP production and utilization less efficient, producing functional consequences that are linked to the increased rate of heart failure in this population. As a result of the increases in circulating fatty acids and insulin resistance that accompanies excess fat storage, several of the proteins and genes that are responsible for fatty acid uptake and metabolism are upregulated, and the metabolic machinery responsible for glucose utilization and oxidation are inhibited. The resultant increase in fatty acid metabolism, and the inherent alterations in the proteins of the electron transport chain used to create the gradient needed to drive mitochondrial ATP production, results in a decrease in efficiency of cardiac work and a relative increase in oxygen usage. These changes in cardiac mitochondrial metabolism are potential therapeutic targets for the treatment and prevention of obesity-related heart failure. (2013) Keywords: myocardial metabolism; review; obese INTRODUCTION Cardiac energy metabolism is essentially a four-step process involving the following: (1) myocellular substrate uptake/selection, (2) mitochondrial ATP production and (3) ATP transfer from the site of production (mitochondrion) to (4) the site of ATP utilization (cardiac myofibril; Figure 1). 1 Although glycolysis is an ATP generator, the overall ATP production is controlled largely by the rate at which the Krebs (tricarboxylic acid) cycle operates. 2 Acetyl co-enzyme A (CoA), which is produced from the oxidation of fatty acids, ketone bodies, or glucose via glycolysis, and the pyruvate dehydrogenase (PDH) enzyme complex 3 enters the Krebs cycle for complete oxidation. During oxidative phosphorylation, electrons, primarily obtained from oxidative metabolism of carbohydrates and fats, are transferred through the electron transport chain, a fourcomplex protein system embedded within the inner membrane of the mitochondria. The major function of the electron transport chain is to produce a proton electrochemical potential difference between two compartments that powers ATP synthase to generate ATP, which is used for all cardiac cellular processes. 4 ATP is the heart's only immediate source of energy for contraction, and as both systole and diastole are ATP-consuming processes, 5,6 cardiac ATP demand is very high. To keep up with this demand for continuous and efficient contraction and relaxation, the heart needs to produce around 20 times its own weight in ATP per day. 1 As a result of this large energy requirement, any impairment in ATP production, transfer or utilization can have detrimental effects on cardiac function. 7 Cardiac metabolism and ATP production is altered in obesity and has emerged as a candidate mechanism to explain the increase in heart failure in this population. 8 Indeed, it has recently been shown that obesity, in the absence of co-morbiditie...

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MRS Studies of Muscle and Heart in Obesity and Diabetes

Prompers

Nicolay

2016

eMagRes

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Effects of Catecholamine Stress on Diastolic Function and Myocardial Energetics in Obesity

Cited by 122 publications

References 40 publications

Impact of Comorbidities on Myocardial Remodeling and Dysfunction In Heart Failure with Preserved Ejection Fraction

Impact of Comorbidities on Myocardial Remodeling and Dysfunction In Heart Failure with Preserved Ejection Fraction

Myocardial substrate metabolism in obesity

MRS Studies of Muscle and Heart in Obesity and Diabetes

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