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Clinical Trial Summary

The overall objective of this study is to uncover and utilize the mechanisms behind the activation of endogenous organ protection by remote ischemic conditioning (RIC), high intensity traditional resistance training (TRT) and low intensity blood flow restricted resistance exercise (BFRE) with the perspective of defining their applicability for immediate organ protection in ischemia-reperfusion injury (acute conditioning) and subsequent tissue repair (chronic conditioning) during a prolonged recovery period. This objective will be achieved by studying which and how molecular pathways underlying these protective mechanisms are shared and can be transferred to treat medical conditions. A specific focus is the roles of EVs and miRNAs. Another objective is to explore how exercise training with and without ischemia can counteract muscle wasting.


Clinical Trial Description

Background

Clinical background - ischemia related and inflammatory conditions The pandemic of cardiovascular disease has immense negative effects on global population health and life expectancy. The most detrimental acute ischemic events are myocardial infarction and stroke. Organ failure caused by ischemia-reperfusion syndromes such as stroke and myocardial infarction constitutes the leading cause of death globally and carry a vast socio-economical burden. Overall, 17 million people worldwide are estimated to die from cardiovascular diseases (7.4 million from ischemic heart disease and 6.7 million from stroke). Attempts to modify risk factor and life style related growth in cardiovascular disease are important and have been successful in some parts of the world, but improved treatment of acute and chronic cardiovascular disease is crucial to alleviate the disease burden.

In acute ischemic conditions such as myocardial infarction and stroke, early and successful restoration of tissue perfusion following an ischemic event is the most effective strategy to reduce tissue injury and improve clinical outcome, but reperfusion may induce further tissue damage itself, so-called reperfusion injury. Although reperfusion strategies continue to progress with improved logistics and medical treatment, even optimal acute reperfusion treatment may leave patients with chronic ischemic disease. Actually, as initial survival has improved due to improvements in acute reperfusion therapy, the number of patients with chronic ischemic heart disease is growing globally (more than 35 million people worldwide suffering from heart failure). Collectively, patients with heart failure have a poorer 5-year survival rate than patients with most types of cancer. However, the development of effective drugs to target the detrimental effects of reperfusion injury itself has proven to be a challenge. Several pharmacologic strategies showing convincing effects in animal models of ischemia-reperfusion injury have failed to translate into clinical benefit.

A key feature of heart failure caused by chronic ischemic heart disease is inflammation, which shares mechanisms with other inflammatory conditions such as inflammatory bowel disease and ankylosing spondylitis. Further debilitating, heart failure also exerts a negative effect on habitual physical activity and skeletal muscle tissue health, producing multiple detrimental effects on whole-body metabolism and mobility. A common underlying mechanistic trait of these processes could be regulation by circulating small non-coding RNAs (micro RNAs or miRNAs/miRs).

Scientific background Remote ischemic conditioning The main prognostic determinant of outcome in acute myocardial infarction is the extent of tissue damage (infarct size), which is determined not only by the duration of ischemia but also by injury caused by reperfusion injury. Remote Ischemic Conditioning (RIC) is a new treatment modality to attenuate reperfusion injury. Organ protection by RIC can be achieved simply by inducing 3 or 4 five-minute cycles of limb ischemia and reperfusion using a tourniquet or simple blood pressure cuff. With few exceptions, RIC has consistently been shown to exert powerful protection against ischemia-reperfusion injury in the heart, brain, kidneys, lungs, and liver in animal models, and RIC has successfully been translated into clinical use. A specific advantage of RIC is its easy applicability during ongoing ischemia of the target organ, which has been exploited in animal models and humans to show that RIC reduces injury during evolving myocardial infarction and stroke.

While the mediators and mechanisms of RIC remain to be identified, RIC has been shown to 1) induce cytoprotection, 2) improve endothelial function and microcirculation, and 3) modify inflammation - all three key players in the pathology behind heart failure - suggesting a potentially powerful tool to simultaneously counteract detrimental biological processes involved in the development of heart failure. RIC may have further potential because continued RIC after myocardial infarction seems to induce sustained benefits during the following adverse remodeling of the heart. The anti-inflammatory effects may be of importance in other conditions involving acute or chronic inflammation.

Ischemia and conditioning with blood flow restricted resistance exercise Exercise is traditionally categorized and practiced as either oxygen-demanding aerobic endurance exercise with effect on metabolic properties or mechanically stressing resistance exercise with effect on contractile properties. In addition to local myocellular effects, exercise appears to promote molecular inter-organ communication. Indeed, recent studies have demonstrated the ability of traditional exercise regimens to protect against e.g. myocardial ischemia-reperfusion injury and also to improve cognitive function, hence the conception that "exercise is medicine". Studies suggest that these remote effects are induced by myocellular production of circulatory mediators to influence tissues of remote organs. Exercise-induced muscle-organ cross-talk may, similar to RIC, rely on extracellular vesicle derived miRNA (see next paragraph). Supporting such a notion, is the finding that high intensity traditional resistance exercise evokes increased transcription of miR133b, since miR133b has recently been demonstrated to promote recovery after stroke via transfer of exosome-enriched extracellular particles. However, high intensity traditional exercise can produce muscle injury and may therefore not comply with exercise in patients with cardiovascular or other chronic muscle wasting diseases.

A novel approach may be offered by Ischemic resistance exercise training conducted as low-intensity blood flow restricted resistance exercise (BFRE), with a low occlusion pressure stimulus, which only compromises venous but not arterial blood flow. Much like RIC, BFRE is conducted as 3-5 cycles (sets of exercise) interspaced by short duration of recovery. By this mechanically very gentle approach, muscle accretion similar to that of high intensity traditional resistance training (TRT) can be achieved, possibly due to acceleration of metabolic build-up or activation of muscle stem cells. Interestingly, new results by us, demonstrate that BFRE can mediate long-lasting preconditioning effects in muscle. Since low-intensity BFRE mimics events of both traditional high intensity resistance exercise (occlusion-reperfusion) and traditional aerobe exercise (hypoxia), BFRE can be speculated to drive health beneficial metabolic as well as anabolic adaptations in the muscle. Based on its resemblance to RIC, BFRE likely also affect remote tissues and infer remote organ protection. The extent to which RIC and exercise regimens may share or overlap or differ mechanistically - and potentially exert additive effects - is unknown, but application of BFRE entails highly promising clinical perspectives.

Micro RNA signaling Circulating extracellular vesicles (EVs) are small particles released from plasma membranes from almost all cell types. These EVs seem to act as transport systems in the body carrying a cargo of signaling substances including miRNAs. miRNAs are also effector molecules in ischemic events, e.g. myocardial miRNA144 (miR144) levels are reduced by ischemic reperfusion injury (IR injury), which is attenuated by RIC. RIC also induces increased circulatory EV levels, while EVs enriched with miR22 and miR451 from anoxic cultured MSCs and cardiomycyte progenitor cells mitigate cardiac injury. Potentially, treatment with specific miRNA loaded into EVs may provide protection against acute and chronic effects of myocardial ischemia-reperfusion injury in patients [19]. EVs are also believed to contain other substances including anti-inflammatory components acting in synergy with miRNA to exert the full effect of the signaling cascade.

Objectives The overall objective of this study is to uncover and utilize the mechanisms behind the activation of endogenous organ protection by remote ischemic conditioning (RIC), high intensity traditional resistance training (TRT) and low intensity blood flow restricted resistance exercise (BFRE) with the perspective of defining their applicability for immediate organ protection in ischemia-reperfusion injury (acute conditioning) and subsequent tissue repair (chronic conditioning) during a prolonged recovery period. This objective will be achieved by studying which and how molecular pathways underlying these protective mechanisms are shared and can be transferred to treat medical conditions. A specific focus is the roles of EVs and miRNAs. Another objective is to explore how exercise training with and without ischemia can counteract muscle wasting.

Hypotesis

The overall hypothesis of the proposal is that RIC and exercise potentiated by BFRE and TRT release circulating protective mediators that exert immediate protective effects against IR injury as well as promote beneficial repair during subsequent tissue rebuilding and in chronic inflammatory conditions. Specifically, we will test the following hypotheses:

1. RIC, BFRE and TRT share organ protecting and anti-inflammatory properties induced through common miRNA signaling pathways

2. Long lasting effect of RIC, BFRE and TRT can be achieved by repeated treatment, and the chronic effects include anti-inflammatory and anti-ischemic properties of clinical relevance by:

1. Improving ventricular function and reduce symptoms in patients with heart failure and chronic ischemic heart disease (individual sub-study, a separate application has been submitted to and approved by De Videnskabsetiske Komitéer).

2. Counteracting muscle wasting in patients with heart failure.

3. BFRE is a more effective mean to increase muscle mass, muscle power and muscle function compared to TRT.

4. Non-conditioned EVs can be loaded with RIC, BFRE and specific miRNA, in vitro and exert immediate protective effects against IR injury upon intravenous injection (future sub-study) ;


Study Design


Related Conditions & MeSH terms


NCT number NCT03380663
Study type Interventional
Source University of Aarhus
Contact Frank de Paoli, MD, PhD
Phone +45 61460880
Email fdp@biomed.au.dk
Status Recruiting
Phase N/A
Start date September 1, 2016
Completion date July 1, 2019

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