Effects of Exercise Training on Fluid Instability in Heart Failure Patients
|Study Design:||Allocation: Randomized
Endpoint Classification: Safety/Efficacy Study
Intervention Model: Parallel Assignment
Masking: Open Label
Primary Purpose: Treatment
|Official Title:||Effects of Exercise Training on Fluid Instability in Heart Failure Patients|
- Bioelectrical Impedance [ Time Frame: 24 weeks ] [ Designated as safety issue: No ]The total body water, intracellular fluid, and extracellular fluid will be calculated and reported to demonstrate Fluid Instability and Fluid Shift from intra to extra-cellular and from extra to intra-cellular. A Bioelectrical Impedance Monitor will be utilized to attain these measures.
- Body Weight [ Time Frame: 16 Weeks ] [ Designated as safety issue: No ]Body weight will be assessed via an average home weight scale. Patients will record their morning body weight in lbs up to 1 decimal point. Additionally, a hospital scale will be used to measure body weight on each clinic visit.
- Health Outcome Measures [ Time Frame: 24 Weeks ] [ Designated as safety issue: No ]Health Outcomes will be measured using the Kansas City Cardio-myopathy Questionnaire, Heart Failure Symptom Questionnaire, and subjective assessments by the study physician. All data will be reported per instrument and a total score will be tabulated for a portion of the analysis.
|Study Start Date:||November 2011|
|Study Completion Date:||December 2014|
|Primary Completion Date:||August 2014 (Final data collection date for primary outcome measure)|
Experimental: Arm 1
Walking Strength Training Bicycling
No Intervention: Arm 2
Background: Heart Failure (HF) is a significant healthcare concern in the US, with a 120% rise in mortality rates over 15 years costing the country an estimated $37.2 billion in 2009. Veterans are currently impacted at a rate of 5.2%, and cost an average of $14,959/individual/year for those utilizing the VA's Healthcare services. Research has shown that exercise training (ET) improves aerobic capacity, endothelial dysfunction, quality of life, and the ability to tolerate activity within the overall HF population. Animal models have emerged to explain some of the underlying mechanisms for the pathologic expression of symptoms and the links to ET. A translational link has not yet been explored between the animal models and human symptom expression.
Objectives: The long-term goal of this research program is to develop an exercise training (ET) program that effectively decreases fluid shift variability in HF patients, while being safely implemented in the home environment and remotely monitored by a healthcare provider within a nurse-lead HF Clinic. The purpose of the proposed research project is to determine if ET alters fluid status of patients with HF as compared to those under standard treatment of care. The central hypothesis is that a combined weight-bearing aerobic and resistance ET protocol will reduce (stabilize) 24-hour weight and bioelectrical impedance patterns of variability, as evaluated via mixed-effects regression modeling, greater than any other form of ET protocol.
Methods: Design: Using established experimental design techniques implemented in an innovative manner, a between-group design is used within the experimental arm employing a single subject, multiple-baseline design. The use of such technique allows for the subjects to be their own controls, while also allowing for statistical between group comparisons.
Subjects and Setting: 60 subjects meeting inclusion/exclusion criteria will be enrolled from the VA HF Clinic and outpatient VA cardiology clinics within 50 miles of Columbia, South Carolina. Subjects will be randomized to the exercise or usual care groups.
Procedures: The exercise protocol lasts 12 weeks, with subjects being randomized to order of ET. Weight-bearing aerobic ET will be walking on a treadmill; non-weight-bearing aerobic ET will be stationary bicycling; and resistance ET will be lower body isolation ET. Fluid stability is the concept of day-to-day variability of movement of intra-cellular fluid to extra-cellular space. Fluid stability will be assessed using 24-hour weight and bioelectrical impedance and quantified statistically using mixed effect modeling.
Data Analysis: Statistical analysis will utilize a longitudinal mixed-effects regression model, modeling variability over time for the subjects individually, as well as within groups. Additionally, main effects (time and group) and interaction effects (time by group) will be assessed.
Status: Funding began September 1, 2010. The study was transferred to Dorn VAMC in Columbia, SC in March of 2011. Currently the study is in the final phase of data analysis.
Please refer to this study by its ClinicalTrials.gov identifier: NCT01375673
|United States, South Carolina|
|Wm. Jennings Bryan Dorn VA Medical Center, Columbia, SC|
|Columbia, South Carolina, United States, 29209|
|Principal Investigator:||Andrea M Boyd, PhD||Wm. Jennings Bryan Dorn VA Medical Center, Columbia, SC|