Clinical Research Directory

Sports Shoes and the Six-Minute Walk Test in COPD

COPD: A Leading Cause of Respiratory Disability COPD, primarily linked to smoking, affects 3.5 million people in France and causes 15,000 deaths each year. It is a major source of disability, particularly due to dyspnoea, which affects one in three patients. Around 400,000 patients are registered under long-term conditions (ALD), and 200,000 receive home-based respiratory support. The most severe cases fall under the category of chronic respiratory failure-a term also applicable to other respiratory or neuromuscular diseases. Walking Exposes Physical Limitations In patients with respiratory failure, walking rapidly induces disabling dyspnoea, as it may represent their maximal effort. This severely limits autonomy and quality of life. To improve exercise tolerance, clinicians rely on pulmonary rehabilitation (exercise reconditioning, bronchodilators, oxygen therapy). When these measures are insufficient, mobility aids such as scooters or electric scooters may help, although they have limitations (cost, bulkiness, muscular deconditioning). The Six-Minute Walk Test (6MWT): A Key Tool The 6MWT is a standardised test that assesses walking distance, dyspnoea, heart rate, and oxygenation. It is used to evaluate the severity and prognosis of respiratory failure and to measure response to treatment. It is integrated into prognostic indices and criteria for assessing the effectiveness of rehabilitation. The only non-standardised parameter remains the type of footwear worn. Research Hypothesis Some so-called "active" sports shoes enhance walking by design-through cushioning, rocker soles, and rigid inserts-which store and return impact energy to assist propulsion. We hypothesise that wearing such shoes could improve walking performance in COPD patients, as reflected by a greater distance on the 6MWT. If confirmed, this simple and low-cost solution could meaningfully improve the daily lives of many patients.

Predictive Factors of Response to Phase II Cardiac Rehabilitation in Heart Failure With Reduced Ejection Fraction

Exercise intolerance, measured as peak oxygen consumption (VO₂peak) during exercise in patients with heart failure with reduced ejection fraction (HFrEF). Change in VO₂peak (ΔVO₂peak), which serves as a prognostic marker for HFrEF engaged in exercise based cardiac rehabilitation program (ExCR). Responders to ExCR generally show improved cardiac function but some patients with HFrEF do not respond to ExCR. VO₂peak depends on three major components of oxygen transport: Pulmonary (lungs), circulatory (heart and vessels) and skeletal muscle (oxygen utilization) functions. These physiological responses to ExCR may be influenced by epigenetic regulation, specifically the expression of circulating microRNAs (c-miRNAs). Linking non-invasive measurements and epigenetic markers could 1) identify which component of the oxygen transport chain is most impaired and 2) allow personalized interventions to maximize VO₂peak improvements. The primary objective of this stidy is to assess the association between changes in VO₂peak during exercise training and circulating microRNA expression (miR-146a, miR-191, miR-23a, miR-140, miR-1, miR-21, miR-133a, miR-17-5p, miR-3200-3p). The secondary objective is to examine the relationship between pulmonary, cardiovascular, and neuromuscular adaptations to exercise and circulating microRNA expression.

Myocardial Protection in Patients With Post-acute Inflammatory Cardiac Involvement Due to COVID-19

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.

Effects of Breathing Training and Nitrate on Exercise at Simulated Altitude

This study investigates whether respiratory muscle training (RMT) and dietary nitrate supplementation can improve exercise tolerance under simulated moderate altitude conditions. Exposure to reduced oxygen availability at altitude places additional strain on the cardiovascular and respiratory systems, which may limit endurance performance. By combining RMT-designed to strengthen the muscles involved in breathing-with nitrate therapy, which enhances nitric oxide availability and vascular function, this study aims to determine whether these interventions independently or synergistically improve oxygen delivery, reduce physiological strain, and enhance exercise performance. The findings will help identify non-pharmacological strategies to improve physical performance and tolerance to hypoxia in both clinical and operational environments.