Implementation and Effect of Exercise and Respiratory Training on 6-minute Walking Distance in Patients With Severe Chronic Pulmonary Hypertension: a Randomized Controlled Multicenter Trial in European Countries
Overview
- Phase
- Not Applicable
- Intervention
- Not specified
- Conditions
- Pulmonary Hypertension
- Sponsor
- Heidelberg University
- Enrollment
- 129
- Locations
- 1
- Primary Endpoint
- 6 MWD
- Status
- Completed
- Last Updated
- 6 years ago
Overview
Brief Summary
Chronic pulmonary hypertension (PH) is associated with impaired exercise capacity, quality of life and right ventricular function. The disease is characterized by an increase of pulmonary vascular resistance and pulmonary arterial pressure, leading to right heart insufficiency.
Despite optimized combination-medical therapy most patients remain symptomatic, have reduced exercise capacity, quality of life and reduced survival rates, with an annual mortality rate of approximately 5 -15 % or even higher.
Previous training studies have suggested that exercise training as add-on to medical treatment is highly effective improving exercise capacity, quality of life and symptoms.
The current guidelines recommend exercise training only in specialized centres including both PH and rehabilitation specialists who are experienced in exercise training of severely compromised patients.
A specialized PH-training program has been performed in Heidelberg since 2003 including >1200 patients with various forms of chronic PH. The exercise training program is performed in a special setting with an in-hospital start of the rehabilitation program. It is characterized by a low-dose closely supervised exercise training in small groups with additional psychological support and mental training.
This training program for patients with PH will be implemented in European centers to add exercise training to the existing PH therapies. The effect of the training on physical exercise capacity will be assessed by 6-minute walking distance (6-MWD). Further clinical parameters will be assessed to evaluate the effect on exercise capacity, quality of life and symptoms.
The aim of this study is to guide European PH-centers to become specialized centers for training in PH.
126 patients will be included, who either receive exercise training or continue their daily sedentary life style (1:1 randomization) for 15 weeks.
As inpatient settings are not available in all healthcare systems the training program will be adapted from the specific training program for PH patients developed in Heidelberg to a procedure, which is feasible in the local participating centres. Another objective of this study is to assess if the particular adopted training program specified for each participating centre and country is still safe and effective.
Detailed Description
Pulmonary hypertension (PH) is defined as a mean pulmonary arterial pressure ≥25 mmHg. PH is often diagnosed at an advanced stage (WHO functional class III-IV) with a massive increase of the mean pulmonary arterial pressure. A crucial parameter determining the symptoms and prognosis of the patients is the cardiac reserve. This parameter is defined by the pulmonary vascular resistance and the right ventricular adaptation. Severe PH is characterized by a decreased cardiac output at rest, an increased afterload and consecutive cor pulmonale. Within the last years there has been a huge progress in the scientific fields of genetics, pathogenesis, pathophysiology and therapy of PH. This has also been documented in the PH world conferences. New disease-targeted medication has been developed such as endothelin receptor antagonists (bosentan, ambrisentan, sitaxentan, macitentan), prostacyclin derivates (inhaled and intravenous iloprost, epoprostenol, treprostinil), phosphodiesterase-5-inhibitors (sildenafil, tadalafil) and the soluble guanylate cyclase inhibitor riociguat. Despite these advances in treatment, the disease may not be treated causally or even be cured. In most cases however, disease progression may be slowed down. The use of PH-targeted treatment and supporting therapies such as anticoagulation and diuretics improve the symptoms and impede the progression of the disease. Nevertheless, the prognosis of the patients remains impaired. The first randomized controlled study investigating the effect of exercise training in PH showed a significant improvement of exercise capacity and quality of life. Further uncontrolled trials using a low-dose exercise and respiratory therapy in different etiologies of PH showed an improvement in exercise capacity, quality of life, muscle function and further prognostic parameters. A recent randomized controlled study could support these findings. Studies also showed an improvement in muscle capillarization of the quadriceps muscle. The training program consists of interval ergometer training, respiratory therapy, muscle training and mental gait training. The interval ergometer training allows performing aerobic exercise training with a low cardio-circulatory stress. In patients with left heart insufficiency, this training has been successfully implemented. Respiratory therapy has been established in the rehabilitation of patients with lung disease within the last years. The different techniques aim to improve ventilation, strengthen the respiratory muscles, mobilize the thorax and enhance secretolysis. The training program also contains mental (gait) training. This training was adapted from mental imagery techniques used by sport psychologists in professional athletes. Mental imagery techniques have shown to improve physical and cognitive functions. Due to the beneficial results, exercise training and rehabilitation has received a 1A recommendation at the PH world symposium in Nice in 2013. This decision was mainly based on three randomized controlled trials that investigated a limited number of patients. To unequivocally demonstrate safety and positive effects of exercise training in different settings large multicenter RCTs are essential. An exercise program has not yet been implemented in most European countries, partly due to limited access to rehabilitation programs and institutions. The aim of this large, multicenter, prospective, randomized controlled trial is to investigate the effect of exercise training and rehabilitation on physical exercise capacity across different European countries. Physical exercise capacity will be measured by exercise induced change of 6-minute walking distance (6-MWD) compared to baseline and the control group without training. As inpatient settings are not available in all healthcare systems the training program will be adapted from the specific training program for PH patients developed in Heidelberg in a system, which is feasible for the local participating centres. Another objective of this study is to assess if the adopted training program specified for each participating centre and country is still safe and effective.
Investigators
Prof. Dr. med. Ekkehard Gruenig
Prof. Dr. med.
Heidelberg University
Eligibility Criteria
Inclusion Criteria
- •Female and male patients of any ethnic origin ≥ 18 years
- •WHO functional class II-IV
- •PH diagnosed by right heart catheter showing:
- •Baseline mean pulmonary arterial pressure (mPAP) ≥ 25 mmHg
- •Baseline pulmonary vascular resistance (PVR) ≥ 240 dyn x s x cm-5
- •Baseline pulmonary capillary wedge pressure (PCWP) ≤ 15 mm Hg
- •Patients receiving optimized conventional PH therapy including intensified treatment with diuretics and who have been stable for 2 months before entering the study
- •Except for diuretics, medical treatment should not be expected to change during the entire 15-week study period
- •Negative pregnancy test (β-HCG) at the start of the trial and appropriate contraception throughout the study for women with child-bearing potential
- •Able to understand and willing to sign the Informed Consent Form
Exclusion Criteria
- •PH of any cause other than permitted in the entry criteria, e.g. concomitantly to portal hypertension, complex congenital heart disease, reversed shunt, HIV infection, suspected pulmonary veno-occlusive disease based on pulmonary edema during a previous vasoreactivity test or on abnormal findings compatible with that diagnosis (septal lines or pulmonary edema at high resolution computer tomography), congenital or acquired valvular defects with clinically relevant myocardial function disorders not related to pulmonary hypertension or unclear diagnosis
- •Pregnancy
- •Patients with signs of right heart decompensation
- •Walking disability
- •Acute infection
- •Any change in disease-targeted therapy within the last 2 months
- •Any subject who is scheduled to receive an investigational drug during the course of this study
- •Severe lung disease: FEV1/FVC \<0.5 and total lung capacity \< 70% of the normal value
- •Active liver disease, porphyria or elevations of serum transaminases \>3 x ULN (upper limit of normal) or bilirubin \> 1.5 x ULN
- •Hemoglobin concentration of less than 75 % of the lower limit of normal
Outcomes
Primary Outcomes
6 MWD
Time Frame: 15 weeks
Change in 6-MWD between baseline and 15 weeks in the training vs. the control Group; meters
Secondary Outcomes
- Change of the right ventricular size(15 weeks)
- Change in WHO functional class in training vs. control group(15 weeks)
- Change in Quality of life in training vs. control group(15 weeks)
- Change in Borg scale 6-MWD training vs. control group(15 weeks)
- Change in tricuspid annular plane systolic excursion(15 weeks)
- Change in tissue Doppler imaging(15 weeks)
- Change in left ventricular pump function(15 weeks)
- Change in right ventricular pump function(15 weeks)
- Change in thickness of interventricular septum(15 weeks)
- Change insize of inferior vena cava(15 weeks)
- Change in systolic pulmonary arterial pressure(15 weeks)
- Change in left ventricular eccentricity index(15 weeks)
- Change in Tei index(15 weeks)
- Change in right ventricular area(15 weeks)
- Change in right atrial area(15 weeks)
- Change in workload(15 weeks)
- Change in heart rate(15 weeks)
- Change in ventilation(15 weeks)
- Change in carbon dioxide output(15 weeks)
- Change in spiroergometry parameters in training vs. control group(15 weeks)
- Change in VCO2 at anaerobic threshold(15 weeks)
- Change in oxygen uptake(15 weeks)
- Change in diffusion-limited carbon monoxide (DLCO)(15 weeks)
- Change in alveolar volume (VA)(15 weeks)
- Change in residual volume (RV)(15 weeks)
- Change in total lung volume (TLC)(15 weeks)
- Change in forced expiratory flow(15 weeks)
- Change in peak expiratory flow rate(15 weeks)
- Change in forced expiratory volume in one second (FEV1)(15 weeks)
- Assessment of clinical laboratory Investigation alerts (values out of range)(15 weeks)
- Change in forced vital capacity (FVC)(15 weeks)
- Change in NTproBNP(15 weeks)
- Change in interleukins(15 weeks)
- Change in inflammatory markers(15 weeks)
- Change in carbon dioxide partial pressure(15 weeks)
- Change in oxygen saturation of the blood (SaO2)(15 weeks)
- Change in additional oxygen supplementation (yes/no and quantity)(15 weeks)
- Change in oxygen partial pressure(15 weeks)
- Change in oxygen saturation(15 weeks)
- Assessment of adverse Events(15 weeks)
- Assessment of serious adverse events(15 weeks)
- frequency of hospitalizations(15 weeks)
- length of hospitalizations(15 weeks)
- Qualitative Review of electrocardiogram (ECG)(15 weeks)
- Assessment of survival(1 year)
- Change in resting heart rate(15 weeks)
- Change in blood pressure(15 weeks)
- frequency of pathological findings in long-term ECG(15 weeks)
- Change of the right ventricular pump function(15 weeks)
- Change of the left ventricular pump function(15 weeks)
- Change in microRNA expression(15 weeks)
- Change in DNA-methylation(15 weeks)
- Assessment of relationship of DNA mutations and disease progression(15 weeks)
- Change of the left ventricular size(15 weeks)
- Assessment of relationship of DNA mutations and training effects(15 weeks)