View clinical trials related to Exercise Intolerance.
Filter by:Long COVID or Postacute sequelae of COVID-19 infection (PASC) are increasingly recognised complications, defined by lingering symptoms, not present prior to the infection, typically persisting for more than 4 weeks. Cardiac symptoms due to post-acute inflammatory cardiac involvement affect a broad segment of people, who were previously well and may have had only mild acute illness (PASC-cardiovascular syndrome, PASC-CVS). Symptoms may be contiguous with the acute illness, however, more commonly they occur after a delay. Symptoms related to the cardiovascular system include exertional dyspnoea, exercise intolerance chest tightness, pulling or burning chest pain, and palpitations (POTS, exertional tachycardia). Pathophysiologically, Long COVID relates to small vessel disease (endothelial dysfunction) vascular dysfunction and consequent tissue organ hypoperfusion due to ongoing immune dysregulation. Active organs with high oxygen dependency are most affected (heart, brain, kidneys, muscles, etc.). Thus, cardiac symptoms are often accompanied by manifestations of other organ systems, including fatigue, brain fog, kidney problems, myalgias, skin and joint manifestations, etc, now commonly referred to as the Long COVID or PASC syndrome. Phenotypically, PostCOVID Heart involvement is characterised by chronic perivascular and myopericardial inflammation. We and others have shown changes using sensitive cardiac MRI imaging that relate to cardiac symptoms (Puntmann et al, Nature Medicine 2022; Puntmann et al, JAMA Cardiol 2020; Summary of studies included in 2022 ACC PostCOVID Expert Consensus Taskforce Development Statement, JACC 2022, references below). Early intervention with immunosuppression and antiremodelling therapy may reduce symptoms and development of myocardial impairment, by minimising the disease activity and inducing disease remission. Low-dose maintenance therapy may help to maintain the disease activity at the lowest possible level. The benefits of early initiations of antiremodelling therapy to reduce symptoms of exercise intolerance are well recognised, but not commonly employed outside the classical cardiology contexts, such as heart failure or hypertension. As most patients with inflammatory heart disease only have mild or no structural abnormalities, they are left untreated (standard of care). The aim of this study is to examine the efficacy of a combined immunosuppressive / antiremodelling therapy in patients with PASC symptoms and inflammatory cardiac involvement determined by CMR, to reduce the symptoms and inflammatory myocardial injury and thereby stop the progression to reduced LVEF, HF and death. References: https://www.nature.com/articles/s41591-022-02000-0 https://jamanetwork.com/journals/jamacardiology/fullarticle/2768916 https://www.jacc.org/doi/abs/10.1016/j.jacc.2022.02.003
Aim of investigators was to study whether abnormalities of lung diffusing capacity for nitric oxide (DLNO) and carbon monoxide (DLCO) in long COVID may have a clinical impact in relation to exercise intolerance.
Although the Covid-19 infection mainly manifests itself with respiratory symptoms, as early as two months after the onset of the pandemic, the presence of other symptoms, including muscle ones, became clear. With the disappearance of the emergency and the advancement of knowledge, medium- and long-term effects have been reported at the level of different organs and systems. Many patients, after several months from infection, report intolerance to exercise and many suffer from pain and muscle weakness. No studies has been carried out on the muscular consequences of the infection and on their possible contribution to intolerance to exercise. Since skeletal muscle possesses the ACE2 receptor (Angiotensin converting enzyme 2) to which SARS-Cov-2 binds, it follows that the involvement of the skeletal muscle could be due not only to the secondary effects of the infection (e.g. reduced oxygen supply from persistent lung disease, perfusion defects from cardiovascular defects and vascular damage), but also to the direct action of virus (SARS-Cov-2 myositis). The general purpose of the research is to quantify the spread of symptoms and signs of muscle weakness and pain among the patient population welcomed at the Cardiorespiratory Rehabilitation Department of the Alexandria Hospital which have been suffering from SARS-CoV-2, being discharged and healed for more than two months, and define the possible contribution of muscular modifications to exercise intolerance.
Exercise tolerance decreases with age and a sedentary lifestyle. Muscle critical power (CP), is a sensitive measure of exercise tolerance that is more even more relevant to and predictive of endurance performance than VO2max. While recent evidence indicates that CP and muscle function decrease with aging, the cause of this decrease in CP and the best way to mitigate the decrease in CP are unknown. This study will: 1. Measure knee extensor CP in young and old individuals and determine the extent to which changes in muscle oxygen delivery (e.g. resistance artery function, maximum exercise blood flow), muscle mass and composition (e.g. whole-muscle size, muscle fiber cross-sectional area) and mitochondrial oxygen consumption (e.g. maximal coupled respiration of permeabilized fibers biopsied from the knee extensors) contribute to the decrease in CP with age. 2. Examine the effectiveness of two different therapies (1. High Intensity Interval Training, HIIT and 2. Muscle Heat Therapy) at improving muscle function and critical power in young and older adults. 3. Examine the impact of muscle disuse (2 weeks of leg immobilization), a potential contributor to the decrease in muscle function with aging, on muscle function and critical power and determine if heat therapy is an effective means of minimizing the impact of disuse on muscle function and critical power.
Among patients awaiting cardiac surgery, a significant proportion are patients with severe angina, heart failure (HF) and peripheral atherosclerosis. These factors are predictors of an unfavorable near and long-term prognosis after open cardiac surgery. It is known that the restriction of motor activity in patients with peripheral atherosclerosis and HF leads to loss of muscle mass, as well as to a decrease in its strength and endurance: secondary (disuse) sarcopenia is formed. In patients with peripheral atherosclerosis and HF, the low functional status of skeletal muscles is associated with a poor prognosis, regardless of gender, age, and concomitant coronary artery disease. A number of studies have shown that the deterioration of muscle status before abdominal, orthopedic and vascular surgery interferes with the close results of surgery, increases the number of complications, the length of ICU and in-hospital stay. Thus, sarcopenia serves as an additional factor worsening the prognosis. Therefore, efforts aimed at improving the functional status in patients planning an open cardiosurgical surgery seem to be very justified. Standard preoperative management of patients includes the identification and correction of comorbidities and the optimal medical treatment. The idea of "rehabilitation" means an additional improvement in the functional capabilities of patients awaiting surgery. Prevention includes outpatient outreach and educational work by nurses, as well as preoperative physical exercises. For this, multi-level training is used: respiratory exercises for the patients with the most severe illness, free movements of the limbs without load, or bike or treadmill training with increasing load for tolerable patients. However, adequate physical rehabilitation is difficult particularly on an outpatient basis. Low adherence is due in part to inadequate strength and inability to tolerate or sustain even low levels of activity due to angina, chronic lower limb ischemia and heart failure symptoms. In this study, the investigators propose to use neuromuscular electrical stimulation (NMES) to assist patient initiation of quadriceps strengthening in order to progressively increase low exercise tolerance.
Myalgic encephalomyelitis/Chronic fatigue syndrome (ME/CFS), otherwise known as Chronic fatigue syndrome (CFS) or myalgic encephalomyelitis (ME), is an under-recognized disorder whose cause is not yet understood. Suggested theories behind the pathophysiology of this condition include autoimmune causes, an inciting viral illness, and a dysfunctional autonomic nervous system caused by a small fiber polyneuropathy. Symptoms include fatigue, cognitive impairments, gastrointestinal changes, exertional dyspnea, and post-exertional malaise. The latter two symptoms are caused in part by abnormal cardiopulmonary hemodynamics during exercise thought to be due to a small fiber polyneuropathy. This manifests as low biventricular filling pressures throughout exercise seen in patients undergoing an invasive cardiopulmonary exercise test (iCPET) along with small nerve fiber atrophy seen on skin biopsy. After diagnosis, patients are often treated with pyridostigmine (off-label use of this medication) to enhance cholinergic stimulation of norepinephrine release at the post-ganglionic synapse. This is thought to improve venoconstriction at the site of exercising muscles, leading to improved return of blood to the heart and increasing filling of the heart to more appropriate levels during peak exercise. Retrospective studies have shown that noninvasive measurements of exercise capacity, such as oxygen uptake, end-tidal carbon dioxide, and ventilatory efficiency, improve after treatment with pyridostigmine. To date, there are no studies that assess invasive hemodynamics after pyridostigmine administration. It is estimated that four million people suffer from ME/CFS worldwide, a number that is thought to be a gross underestimate of disease prevalence. However, despite its potential for debilitating symptoms, loss of productivity, and worldwide burden, the pathophysiology behind ME/CFS remains unknown and its treatment unclear. By evaluating the exercise response to cholinergic stimulation, this study will shed further light on the link between the autonomic nervous system and cardiopulmonary hemodynamics, potentially leading to new therapeutic targets.
Heart failure (HF) is a major public health problem. This is the first cause of hospitalization and mortality of about 65 years old. This syndrome is characterized by a poor prognosis and a high cost of care. Thus, new strategies for treatment and prevention of the HF are among the major challenges facing health sciences today. The management of HF requires multimodal approach it involves a combination of non-pharmacological and pharmacological treatment, Besides improvements in pharmacological treatment, supervised exercise programs are recommended for all patients with HF as part of a non-pharmacological management but many questions regarding exercise training in HF patients remain unanswered. Even simple questions such as the best mode of training for these patients are unclear. The aim of this study 1. First, to characterize the physiological functions involved in the genesis of exercise intolerance and dyspnea especially muscle function (respiratory and skeletal), and cardiopulmonary patients suffering from chronic HF. 2. Second, to study and compare the effects of different rehabilitation programs and prove the superiority of the combination of three training modalities program: aerobic training (AT), resistance training (RT) and inspiratory muscle training (IMT). These modalities are: Aerobic Training: It has been proven effective in improving muscle abnormalities on changing the ventricular remodeling, dyspnea, functional capacity, increasing the maximum performance and reducing hospitalization in subjects suffering HF. Resistance Training: It has been proven effective in improving skeletal muscle metabolism and angiogenesis; increasing capillary density and blood flow to the active skeletal muscles, promoting the synthesis and release of nitric oxide, and decreasing oxidative stress. Selective Inspiratory Muscle Training: It has been proven effective in improving the strength and endurance of the respiratory muscles and reduction of dyspnea during daily activities.
A growing body of physiological evidence now exists to support a potential role for inhaled cannabis in the medical management of adults with chronic obstructive pulmonary disease (COPD), particularly as it may related to improving pulmonary function, alleviating the symptom of breathlessness and improving exercise endurance. The purpose of this randomized double-blind crossover trials is to evaluate the efficacy and physiological mechanism(s) of action of inhaled vaporized cannabis targeted to relief of physical activity-related breathlessness and exercise endurance in symptomatic patients with severe-to-very severe COPD.
Heart failure with preserved ejection fraction (HFpEF) is a major public health problem that has no proven effective treatment. This study assessed the effects of acute nitrite administration on resting and exercise hemodynamics in patients with HFpEF.