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Sarcopenia (muscle wasting) and cachexia share some pathophysiological aspects. Sarcopenia affects approximately 20 %, cachexia <10 % of ambulatory patients with heart failure (HF). Whilst sarcopenia means loss of skeletal muscle mass and strength that predominantly affects postural rather than non-postural muscles, cachexia means loss of muscle and fat tissue that leads to weight loss. The wasting continuum in HF implies that skeletal muscle is lost earlier than fat tissue and may lead from sarcopenia to cachexia. Both tissues require conservation, and therapies that stop the wasting process have tremendous therapeutic appeal. The present paper reviews the pathophysiology of muscle and fat wasting in HF and discusses potential treatments, including exercise training, appetite stimulants, essential amino acids, growth hormone, testosterone, electrical muscle stimulation, ghrelin and its analogues, ghrelin receptor agonists and myostatin antibodies.

The Journal of Cachexia, Sarcopenia and Muscle (JCSM) aims to publish articles with relevance to wasting disorders and illnesses of the muscle in the broadest sense. In order to avoid publication of inappropriate articles and to avoid protracted disputes, the Editors have established ethical guidelines that detail a number of regulations to be fulfilled prior to submission to the journal. This article updates the principles of ethical authorship and publishing in JCSM and its two daughter journals JCSM Rapid Communication and JCSM Clinical Reports. We require the corresponding author, on behalf of all co‐authors, to certify adherence to the following principles: All authors listed on a manuscript considered for publication have approved its submission and (if accepted) approve publication in the journal; Each named author has made a material and independent contribution to the work submitted for publication; No person who has a right to be recognized as author has been omitted from the list of authors on the submitted manuscript; The submitted work is original and is neither under consideration elsewhere nor that it has been published previously in whole or in part other than in form; All authors certify that the submitted work is original and does not contain excessive overlap with prior or contemporaneous publication elsewhere, and where the publication reports on cohorts, trials, or data that have been reported on before the facts need to be acknowledged and these other publications must be referenced; All original research work has been approved by the relevant bodies such as institutional review boards or ethics committees; All relevant conflicts of interest, financial or otherwise, that may affect the authors' ability to present data objectively, and relevant sources of funding of the research in question have been duly declared in the manuscript; All authors certify that they will submit the original source data to the editorial office upon request; The manuscript in its published form will be maintained on the servers of the journal as a valid publication only as long as all statements in these guidelines remain true; If any of the aforementioned statements ceases to be true, the authors have a duty to notify as soon as possible the Editor‐in‐Chief of the journal, so that the available information regarding the published article can be updated and/or the manuscript can be withdrawn.

The new ICD‐10‐CM (M62.84) code for sarcopenia represents a major step forward in recognizing sarcopenia as a disease. This should lead to an increase in availability of diagnostic tools and the enthusiasm for pharmacological companies to develop drugs for sarcopenia.

This article details an updated version of the principles of ethical authorship and publishing in the Journal of Cachexia, Sarcopenia and Muscle (JCSM) and its two daughter journals JCSM Rapid Communication and JCSM Clinical Reports. We request of all author sending to the journal a paper for consideration that at the time of submission to JCSM, the corresponding author, on behalf of all co‐authors, needs to certify adherence to these principles. The principles are as follows: all authors listed on a manuscript considered for publication have approved its submission and (if accepted) approve publication in JCSM as provided; each named author has made a material and independent contribution to the work submitted for publication; no person who has a right to be recognized as author has been omitted from the list of authors on the submitted manuscript; the submitted work is original and is neither under consideration elsewhere nor that it has been published previously in whole or in part other than in form; all authors certify that the submitted work is original and does not contain excessive overlap with prior or contemporaneous publication elsewhere, and where the publication reports on cohorts, trials, or data that have been reported on before the facts need to be acknowledged and these other publications must be referenced; all original research work has been approved by the relevant bodies such as institutional review boards or ethics committees; all relevant conflicts of interest, financial or otherwise, that may affect the authors' ability to present data objectively, and relevant sources of funding of the research in question have been duly declared in the manuscript; the manuscript in its published form will be maintained on the servers of JCSM as a valid publication only as long as all statements in the guidelines on ethical publishing remain true. If any of the aforementioned statements ceases to be true, the authors have a duty to notify as soon as possible the Editors of JCSM, JCSM Rapid Communication, and JCSM Clinical Reports, respectively, so that the available information regarding the published article can be updated and/or the manuscript can be withdrawn.

Cachexia is a serious clinical consequence of almost all chronic diseases when reaching advanced stages. Its prevalence ranges from 5–15% in end‐stage chronic heart failure to 50–80% in advanced malignant cancer. Cachexia is also frequently occurring in patients with chronic kidney disease, chronic obstructive pulmonary disease (COPD) or neurological diseases, and rheumatoid arthritis. Mortality rates of patients with cachexia range from 15–25% per year in severe COPD through 20–40% per year in patients with chronic heart failure or chronic kidney disease to 20–80% in cancer cachexia. In the industrialized world (North America, Europe, and Japan) where epidemiological data are to some degree available, the overall prevalence of cachexia (due to any disease and not necessarily associated with hospital admission) is growing with the growth of the chronic illness prevalence, and it currently affects around 0.5–1.0% of the population, i.e. around 6–12 million people. From this, one can estimate that 1.5–2 million deaths are occurring in patients with cachexia per year. It is also a very significant health problem in other parts of the globe, but epidemiological data are scarce. The multifactorial nature of cachexia is now much better understood, and particularly, the role of inflammatory mediators and the imbalance of anabolism and catabolism are considered important therapeutic targets. Several approaches to develop cachexia and muscle wasting treatments have failed to be successful in phase III clinical trials, but new approaches are in development. Given the high prevalence and very high mortality associated with cachexia, advances are urgently needed for patients worldwide.

Statins are a family of drugs that are used for treating hyperlipidaemia with a recognized capacity to prevent cardiovascular disease events. They inhibit β‐hydroxy β‐methylglutaryl‐coenzyme A reductase, i.e. the rate‐limiting enzyme in mevalonate pathway, reduce endogenous cholesterol synthesis, and increase low‐density lipoprotein clearance by promoting low‐density lipoprotein receptor expression mainly in the hepatocytes. Statins have pleiotropic effects including stabilization of atherosclerotic plaques, immunomodulation, anti‐inflammatory properties, improvement of endothelial function, antioxidant, and anti‐thrombotic action. Despite all beneficial effects, statins may elicit adverse reactions such as myopathy. Studies have shown that mitochondria play an important role in statin‐induced myopathies. In this review, we aim to report the mechanisms of action of statins on mitochondrial function. Results have shown that statins have several effects on mitochondria including reduction of coenzyme Q10 level, inhibition of respiratory chain complexes, induction of mitochondrial apoptosis, dysregulation of Ca2+ metabolism, and carnitine palmitoyltransferase‐2 expression. The use of statins has been associated with the onset of additional pathological conditions like diabetes and dementia as a result of interference with mitochondrial pathways by various mechanisms, such as reduction in mitochondrial oxidative phosphorylation, increase in oxidative stress, decrease in uncoupling protein 3 concentration, and interference in amyloid‐β metabolism. Overall, data reported in this review suggest that statins may have major effects on mitochondrial function, and some of their adverse effects might be mediated through mitochondrial pathways.

Cachexia is a serious but underrecognised consequence of many chronic diseases. Its prevalence ranges from 5–15 % in end-stage chronic heart failure to 50–80 % in advanced cancer. Cachexia is also part of the terminal course of many patients with chronic kidney disease, chronic obstructive pulmonary disease (COPD) and rheumatoid arthritis. Mortality rates of patients with cachexia range from 10–15 % per year in COPD through 20–30 % per year in chronic heart failure and chronic kidney disease to 80 % in cancer. The condition is also associated with poor quality of life. In the industrialised world, the overall prevalence of cachexia (due to any disease and not necessarily associated with hospital admission) is growing and it currently affects around 1 % of the patient population, i.e. around 9 million people. It is also a significant health problem in other parts of the globe. Recently there have been advances in our understanding of the multifactorial nature of the condition, and particularly of the role of inflammatory mediators and the imbalance of anabolism and catabolism. Several promising approaches to treatment have failed to live up to the challenge of phase III clinical trials, but the ghrelin receptor agonist anamorelin seems to have fulfilled at least some early promise. Further advances are urgently needed.

Sarcopenia is now defined as a decline in walking speed or grip strength associated with low muscle mass. Sarcopenia leads to loss of mobility and function, falls, and mortality. Sarcopenia is a major cause of frailty, but either condition can occur without the other being present. Sarcopenia is present in about 5 to 10 % of persons over 65 years of age. It has multiple causes including disease, decreased caloric intake, poor blood flow to muscle, mitochondrial dysfunction, a decline in anabolic hormones, and an increase in proinflammatory cytokines. Basic therapy includes resistance exercise and protein and vitamin D supplementation. There is now a simple screening test available for sarcopenia—SARC-F. All persons 60 years and older should be screened for sarcopenia and treated when appropriate.

The term sarcopenia was introduced in 1988. The original definition was a “muscle loss” of the appendicular muscle mass in the older people as measured by dual energy x‐ray absorptiometry (DXA). In 2010, the definition was altered to be low muscle mass together with low muscle function and this was agreed upon as reported in a number of consensus papers. The Society of Sarcopenia, Cachexia and Wasting Disorders supports the recommendations of more recent consensus conferences, i.e. that rapid screening, such as with the SARC‐F questionnaire, should be utilized with a formal diagnosis being made by measuring grip strength or chair stand together with DXA estimation of appendicular muscle mass (indexed for height2). Assessments of the utility of ultrasound and creatine dilution techniques are ongoing. Use of ultrasound may not be easily reproducible. Primary sarcopenia is aging associated (mediated) loss of muscle mass. Secondary sarcopenia (or disease‐related sarcopenia) has predominantly focused on loss of muscle mass without the emphasis on muscle function. Diseases that can cause muscle wasting (i.e. secondary sarcopenia) include malignant cancer, COPD, heart failure, and renal failure and others. Management of sarcopenia should consist of resistance exercise in combination with a protein intake of 1 to 1.5 g/kg/day. There is insufficient evidence that vitamin D and anabolic steroids are beneficial. These recommendations apply to both primary (age‐related) sarcopenia and secondary (disease related) sarcopenia. Secondary sarcopenia also needs appropriate treatment of the underlying disease. It is important that primary care health professionals become aware of and make the diagnosis of age‐related and disease‐related sarcopenia. It is important to address the risk factors for sarcopenia, particularly low physical activity and sedentary behavior in the general population, using a life‐long approach. There is a need for more clinical research into the appropriate measurement for muscle mass and the management of sarcopenia. Accordingly, this position statement provides recommendations on the management of sarcopenia and how to progress the knowledge and recognition of sarcopenia.

Cachexia is a serious, however underestimated and underrecognised medical consequence of malignant cancer, chronic heart failure (CHF), chronic kidney disease (CKD), chronic obstructive pulmonary disease (COPD), cystic fibrosis, rheumatoid arthritis, Alzheimer's disease, infectious diseases, and many other chronic illnesses. The prevalence of cachexia is high, ranging from 5% to 15% in CHF or COPD to 60% to 80% in advanced cancer. By population prevalence, the most frequent cachexia subtypes are in order: COPD cachexia, cardiac cachexia (in CHF), cancer cachexia, and CKD cachexia. In industrialized countries (North America, Europe, Japan), the overall prevalence of cachexia (due to any disease) is growing and currently about 1%, i.e., about nine million patients. The relative prevalence of cachexia is somewhat less in Asia, but is a growing problem there as well. In absolute terms, cachexia is, in Asia (due to the larger population), as least as big a problem as in the Western world. Cachexia is also a big medical problem in South America and Africa, but data are scarce. A consensus statement recently proposed to diagnose cachexia in chronic diseases when there is weight loss exceeding 5% within the previous 3–12 months combined with symptoms characteristic for cachexia (e.g., fatigue), loss of skeletal muscle and biochemical abnormalities (e.g., anemia or inflammation). Treatment approaches using anabolics, anti-catabolic therapies, appetite stimulants, and nutritional interventions are under development. A more thorough understanding of the pathophysiology of cachexia development and progression is needed that likely will lead to combination therapies being developed. These efforts are greatly needed as presence of cachexia is always associated with high-mortality and poor-symptom status and dismal quality of life. It is thought that in cancer, more than 30% of patients die due to cachexia and more than 50% of patients with cancer die with cachexia being present. In other chronic illnesses, one can estimate that up to 30% of patients die with some degree of cachexia being present. Mortality rates of patients with cachexia range from 10% to 15% per year (COPD), to 20% to 30% per year (CHF, CKD) to 80% in cancer.