• Contrast resting and exercise-induced changes in vascular stiffness, endothelial function, and afterload in patients with HFpEF to age-matched controls. [ Time Frame: Throughout single visit. ] [ Designated as safety issue: No ]
  

• Determine how baseline and exercise-induced changes in the vascular parameters measured are related to LV systolic and diastolic functional reserve, cardiac output response, metabolic exercise performance, and changes in pulmonary cap [ Time Frame: Throughout single visit ] [ Designated as safety issue: No ]
  
• Determine if vascular and ventricular stiffness properties measured in specific aim 1 are associated with abnormal neurohormonal responses to exercise. [ Time Frame: Immediately pre and post exercise ] [ Designated as safety issue: No ]
  

Congestive heart failure (HF) is the leading cause of hospitalization among older Americans.1 Approximately half of affected patients have apparently normal systolic function (HF with preserved ejection fraction, HFpEF).2-4 In contrast to HF with low EF, there are no proven treatments for HFpEF, due largely to a lack of mechanistic understanding.4 HFpEF patients are typically older, hypertensive and female,2,3 and each of these characteristics is associated with vascular stiffening and dysfunction.5-7 Diastolic abnormalities may contribute to symptoms of exertional intolerance3,8, but non-cardiac limitations have recently been shown to be equally important.9-11 Patients with HFpEF display impaired decreases in mean vascular resistance in response to exercise, significantly limiting performance,9 yet this represents only one component of ventricular afterload. With aging and particularly in HFpEF, pulsatile load due to vascular stiffening and increased wave reflections becomes more magnified.6,12 The latter can be quantified by pulse wave velocity, arterial compliance and carotid augmentation index. These can be determined noninvasively, and while they have been shown to be abnormal in HFpEF patients at rest10,11, little is known about changes in each during exercise stress, or how this might modulate ventricular performance. Recent evidence indicates that endothelial and autonomic dysfunction are present in HFpEF9, but it is not known how these abnormalities might limit ventricular-vascular function with exercise. The primary objective of this proposal is to compare resting and exercise-induced changes in vascular function in patients with HFpEF and age-matched controls, to determine how these factors may affect exercise performance and cardiovascular reserve function. Specific Aim 1. Contrast resting and exercise-induced changes in vascular stiffness, endothelial function, and afterload in patients with HFpEF to age-matched controls. Net, mean, and late components of afterload will be assessed by arterial elastance (Ea), systemic vascular resistance (SVR), and central augmentation index (AI). Vascular stiffness will be quantified by pulse wave velocity and total arterial compliance. Stiffness and afterload are dynamically modulated by endothelial and autonomic function, and these responses will be assessed by finger volume plethysmography. Parameters will be measured at rest, during upright cycle ergometry, and immediately post exercise by noninvasive blood pressure, tonometry and comprehensive echo-Doppler examination with tissue Doppler echo (TDE). Specific Aim 2. Determine how baseline and exercise-induced changes in the vascular parameters measured in specific aim 1 are related to LV systolic and diastolic functional reserve, cardiac output response, metabolic exercise performance, and changes in pulmonary capillary blood volume. LV systolic and diastolic function will be assessed by echo-Doppler and TDE parameters at rest and immediately after peak exercise. Cardiac output response will be determined by the product of echo-Doppler stroke volume and heart rate. Exercise performance will quantified by expired gas analysis. Pulmonary blood volume will be estimated based upon the ratio of diffusion capacity of nitric oxide and carbon monoxide, obtained both at rest and immediately post exercise. Regression analyses will then be performed using the measured components of afterload and vascular stiffness as the independent variable and each of the above parameters as dependent output variables to delineate the role of vascular stiffening on exercise performance, reserve and ventricular-vascular coupling. Specific Aim 3. Determine if vascular and ventricular stiffness properties measured in specific aim 1 are associated with abnormal neurohormonal responses to exercise. Blood samples will be obtained from HFpEF subjects and controls prior to and immediately after peak exercise to contrast exercise-induced changes in B-type natriuretic peptide levels and cyclic guanosine monophosphate levels.