Translational Medicine and Exercise Prescription (TMEP): Advancing the Era of Exercise Medicine
Sulin Cheng, M. Schumann, W. Bloch
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Bloch","doi":"10.53941/tmep.v1i1.27","DOIUrl":null,"url":null,"abstract":"Translational Medicine and Exercise Prescription (TMEP): Advancing the Era of Exercise Medicine\n\nSulin Cheng1,2,3,4, Moritz Schumann()2,4 and Wilhelm Bloch4\n\n\n1Exercise, Health and Technology Center, Department of Physical Education, Shanghai Jiao Tong University, Shanghai, China\n2Exercise Translational Medicine Center, Shanghai Center for Systems Biomedicine, Shanghai Jiao Tong University, Shanghai, China\n3Faculty of Sport and Health Sciences, University of Jyväskylä, Jyväskylä, Finland\n4Department of Molecular and Cellular Sport Medicine, German Sport University, Cologne, Germany\n\n© The Authors\n\n\"Exercise is medicine\" has gained popularity worldwide after the American Medical Association and the American College of Sports Medicine co-launched their ground-breaking health initiative in 20071 . This initiative was aimed at improving population health and well-being, mainly by raising the awareness of healthcare providers to regard performing physical activity (PA) as one of the vital signs. Ever since, this concept has spread worldwide and PA has been proposed as an essential part of treatment for chronic diseases2 . In their pioneering work, Pedersen and Saltin provided compelling evidence for the role of exercise as the first- or second-line therapy for at least 26 diseases2 . These findings are further corroborated by meta-epidemiological data, indicating exercise interventions to be as effective as drug interventions, such as during rehabilitation after stroke and for the treatment of heart failure3 . However, the overall effect appears to be strongly correlated with important determinants of the exercise program performed (i.e. dose of training [frequency, volume, intensity], type of exercise and adherence to the training program) and disease-related specifics4 , thus requiring not only clinical expertise but also an in-depth understanding of exercise physiology and biology.\n In this new journal-Translational Medicine and Exercise Prescription (TMEP), we are aiming to bring together the fields of exercise physiology and biology, sports medicine and the science of physical training and testing to bridge the gap between mechanistic research and clinical practice. The journal covers nine sections, including obesity, diabetes, cancer, cardiovascular diseases, neurological and psychiatric diseases, pulmonary diseases, musculoskeletal diseases, endocrine disorders as well as advanced exercise prescription and health maintenance. In this first issue of TMEP, we are delighted to present seven papers from different areas of translational research performed in humans on specific themes related to the treatment and prevention of chronic diseases.\n Appropriate selection of primary and secondary endpoints is critical for successfully designing translational studies. In the first paper of this issue, TMEP Section Editor, Jörn Rittweger provides his thoughts on \"What Are Good Muscle Endpoints for Translational Studies?\". In his important work, he highlights the importance of muscles for our health because of their size, their involvement in energy metabolism and their relevance for locomotion. He further suggests that at least eight different muscle functions are important to health. Well accepted methods exist for three relevant muscular endpoints, namely for power, strength and muscle mass, and these endpoints are utilized in clinical studies. However, such validated methods lack a number of additional muscle functions that are not yet fully scientifically explored. This applies foremost to not only the metabolic functions of muscles, but also to their role in storage and dissipation of mechanical energy. His work concludes by emphasizing how physiological knowledge can be an important base for the guidance of clinical diagnostics.\n Following this important message, the group of TMEP Section Editor Pieter de Lange shares their work entitled \"Exercise with Energy Restriction as a Means of Losing Body Mass While Preserving Muscle Quality and Ameliorating Comorbidities: Towards A Therapy for Obesity?\". Obesity and related comorbidities have reached pandemic proportions worldwide, particularly during the past decade. Therefore, finding effective intervention strategies not only requires scientific focus but these strategies are also of public interest. Based on both human and animal studies, this narrative review summarizes the effects of dietary and exercise-based programs on loss of different body mass components. Furthermore, both the gain and lack of loss of lean mass in view of muscle quality maintenance are discussed and data related to the mechanisms underlying the conservation of functional muscle mass provided. They also provide evidence of the interaction between energy restriction by diet and exercise-induced metabolic demands at the molecular level. This insight into the mechanisms underlines the relevance of translational considerations for personalized exercise prescription.\n Obesity and an unhealthy lifestyle are also known to be among the risk factors for type 2 diabetes (T2DM). The research group of TMEP Section Editor Thomas Yates highlights research opportunities and challenges for combining exercise and medical therapies by means of a narrative review entitled \"Exercise, Pharmaceutical Therapies and Type 2 Diabetes: Looking beyond Glycemic Control to Whole Body Health and Function\". The authors provide evidence on newer generations of glucose-lowering therapies that also induce concomitant weight loss, particularly on glucagon-like peptide-1 receptor agonists (GLP-1RAs) and sodium-glucose cotransporter 2 inhibitors (SGLT2is). Based on current knowledge, they stress the importance of investigating the interaction or synergy between exercise and other glucose-lowering or weight loss therapies, to make exercise a tailored therapy rather than a generic treatment in the management of T2DM. This review, therefore, clearly highlights the need of precise exercise prescription, originating from an in-depth mechanistic understanding of the effects of exercise.\n Cancer is another important metabolic and chronic inflammatory disease that may also be associated with obesity. TMEP Section Editor Jesper F Christensen and Associate Editor Ciaran M Fairman provide a very interesting viewpoint in their article,\"Targeted Exercise Training for Cancer Patients: Moving beyond Generic Exercise Guidelines in Clinical Oncology\". This paper aims to update the current knowledge and the clinical rationale for targeted exercise interventions in exercise oncology. Moreover, a framework for systematic guidance of the design and execution of targeted exercise interventions in oncology is presented. The authors hope that their framework can encourage further research into targeted exercise interventions in oncology and may also be used as a guideline for the design of future trials to increase quality and impact.\n The group of TMEP Section Editor Helen Dawes, shares their original data in the context of neurological and psychiatric diseases in the article entitled \"Physical Activity and Fatigue in Multiple Sclerosis: Secondary Outcomes from a Double-blinded Randomized Controlled Trial of Cocoa Flavonoid Drinks\". In this study, they performed intensive phenotyping of the inter-relationships of the time of day, physical activity levels and fatigue to determine exercise prescription in a group of people with multiple sclerosis (MS) participating in a six-week randomized controlled trial of morning flavonoid intake. It was found that fatigue levels increased during the day and higher levels of fatigue reduced physical activity; yet physical activity itself did not lead to increased fatigue. Additionally, morning cocoa intake reduced daytime fatigue and fatigue related to subsequent physical activity. Therefore, combined prescription of morning exercise and dietary flavonoids may optimize the exercise and physical activity potential in people with MS. This study nicely demonstrates the importance of understanding and considering possible covariants such as nutrition and chronobiology to determine an optimal exercise prescription model.\n TMEP Section Editor Jonathan Myers and colleague Baruch Vainshelboim present a narrative review on \"Resistance Training for Rehabilitation of Patients with Idiopathic Pulmonary Fibrosis\". In this paper, the pathophysiology and clinical manifestations of Idiopathic Pulmonary Fibrosis (IPF) are summarized with an emphasis on the numerous health and clinical benefits of resistance training among older adults and patients with this respiratory disease. This article effectively explores the potential mechanisms by which systematic resistance training may help overcome exercise limitations in IPF, providing a therapeutic opportunity for rehabilitation. Furthermore, the authors provide important recommendations for pulmonary rehabilitation programs that are based on resistance training for patients with IPF. With this paper, the authors highlight that disease-adapted exercise prescription requires a pathophysiological understanding to justify the inclusion of specific exercise regimens.\n In the final paper of this special issue, the research group of Section Editor Anthony C Hackney shares their original data on the \"Energy Availability and RED-S Risk Factors in Competitive, Non-elite Male Endurance Athletes\". This paper particularly emphasizes the entire spectrum of TMEP, that is more than just the most common types of non-communicable diseases, but also includes chronic conditions that may be for example induced by athletic training. In this study, the authors assessed the associations of energy availability and risk factors of relative energy deficiency in sport (RED-S) in 60 competitive, recreationally trained male endurance athletes. They found that hormonal and bone biomarkers were within normal clinical ranges, even when the energy availability was low. 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Abstract
Translational Medicine and Exercise Prescription (TMEP): Advancing the Era of Exercise Medicine
Sulin Cheng1,2,3,4, Moritz Schumann()2,4 and Wilhelm Bloch4
1Exercise, Health and Technology Center, Department of Physical Education, Shanghai Jiao Tong University, Shanghai, China
2Exercise Translational Medicine Center, Shanghai Center for Systems Biomedicine, Shanghai Jiao Tong University, Shanghai, China
3Faculty of Sport and Health Sciences, University of Jyväskylä, Jyväskylä, Finland
4Department of Molecular and Cellular Sport Medicine, German Sport University, Cologne, Germany
© The Authors
"Exercise is medicine" has gained popularity worldwide after the American Medical Association and the American College of Sports Medicine co-launched their ground-breaking health initiative in 20071 . This initiative was aimed at improving population health and well-being, mainly by raising the awareness of healthcare providers to regard performing physical activity (PA) as one of the vital signs. Ever since, this concept has spread worldwide and PA has been proposed as an essential part of treatment for chronic diseases2 . In their pioneering work, Pedersen and Saltin provided compelling evidence for the role of exercise as the first- or second-line therapy for at least 26 diseases2 . These findings are further corroborated by meta-epidemiological data, indicating exercise interventions to be as effective as drug interventions, such as during rehabilitation after stroke and for the treatment of heart failure3 . However, the overall effect appears to be strongly correlated with important determinants of the exercise program performed (i.e. dose of training [frequency, volume, intensity], type of exercise and adherence to the training program) and disease-related specifics4 , thus requiring not only clinical expertise but also an in-depth understanding of exercise physiology and biology.
In this new journal-Translational Medicine and Exercise Prescription (TMEP), we are aiming to bring together the fields of exercise physiology and biology, sports medicine and the science of physical training and testing to bridge the gap between mechanistic research and clinical practice. The journal covers nine sections, including obesity, diabetes, cancer, cardiovascular diseases, neurological and psychiatric diseases, pulmonary diseases, musculoskeletal diseases, endocrine disorders as well as advanced exercise prescription and health maintenance. In this first issue of TMEP, we are delighted to present seven papers from different areas of translational research performed in humans on specific themes related to the treatment and prevention of chronic diseases.
Appropriate selection of primary and secondary endpoints is critical for successfully designing translational studies. In the first paper of this issue, TMEP Section Editor, Jörn Rittweger provides his thoughts on "What Are Good Muscle Endpoints for Translational Studies?". In his important work, he highlights the importance of muscles for our health because of their size, their involvement in energy metabolism and their relevance for locomotion. He further suggests that at least eight different muscle functions are important to health. Well accepted methods exist for three relevant muscular endpoints, namely for power, strength and muscle mass, and these endpoints are utilized in clinical studies. However, such validated methods lack a number of additional muscle functions that are not yet fully scientifically explored. This applies foremost to not only the metabolic functions of muscles, but also to their role in storage and dissipation of mechanical energy. His work concludes by emphasizing how physiological knowledge can be an important base for the guidance of clinical diagnostics.
Following this important message, the group of TMEP Section Editor Pieter de Lange shares their work entitled "Exercise with Energy Restriction as a Means of Losing Body Mass While Preserving Muscle Quality and Ameliorating Comorbidities: Towards A Therapy for Obesity?". Obesity and related comorbidities have reached pandemic proportions worldwide, particularly during the past decade. Therefore, finding effective intervention strategies not only requires scientific focus but these strategies are also of public interest. Based on both human and animal studies, this narrative review summarizes the effects of dietary and exercise-based programs on loss of different body mass components. Furthermore, both the gain and lack of loss of lean mass in view of muscle quality maintenance are discussed and data related to the mechanisms underlying the conservation of functional muscle mass provided. They also provide evidence of the interaction between energy restriction by diet and exercise-induced metabolic demands at the molecular level. This insight into the mechanisms underlines the relevance of translational considerations for personalized exercise prescription.
Obesity and an unhealthy lifestyle are also known to be among the risk factors for type 2 diabetes (T2DM). The research group of TMEP Section Editor Thomas Yates highlights research opportunities and challenges for combining exercise and medical therapies by means of a narrative review entitled "Exercise, Pharmaceutical Therapies and Type 2 Diabetes: Looking beyond Glycemic Control to Whole Body Health and Function". The authors provide evidence on newer generations of glucose-lowering therapies that also induce concomitant weight loss, particularly on glucagon-like peptide-1 receptor agonists (GLP-1RAs) and sodium-glucose cotransporter 2 inhibitors (SGLT2is). Based on current knowledge, they stress the importance of investigating the interaction or synergy between exercise and other glucose-lowering or weight loss therapies, to make exercise a tailored therapy rather than a generic treatment in the management of T2DM. This review, therefore, clearly highlights the need of precise exercise prescription, originating from an in-depth mechanistic understanding of the effects of exercise.
Cancer is another important metabolic and chronic inflammatory disease that may also be associated with obesity. TMEP Section Editor Jesper F Christensen and Associate Editor Ciaran M Fairman provide a very interesting viewpoint in their article,"Targeted Exercise Training for Cancer Patients: Moving beyond Generic Exercise Guidelines in Clinical Oncology". This paper aims to update the current knowledge and the clinical rationale for targeted exercise interventions in exercise oncology. Moreover, a framework for systematic guidance of the design and execution of targeted exercise interventions in oncology is presented. The authors hope that their framework can encourage further research into targeted exercise interventions in oncology and may also be used as a guideline for the design of future trials to increase quality and impact.
The group of TMEP Section Editor Helen Dawes, shares their original data in the context of neurological and psychiatric diseases in the article entitled "Physical Activity and Fatigue in Multiple Sclerosis: Secondary Outcomes from a Double-blinded Randomized Controlled Trial of Cocoa Flavonoid Drinks". In this study, they performed intensive phenotyping of the inter-relationships of the time of day, physical activity levels and fatigue to determine exercise prescription in a group of people with multiple sclerosis (MS) participating in a six-week randomized controlled trial of morning flavonoid intake. It was found that fatigue levels increased during the day and higher levels of fatigue reduced physical activity; yet physical activity itself did not lead to increased fatigue. Additionally, morning cocoa intake reduced daytime fatigue and fatigue related to subsequent physical activity. Therefore, combined prescription of morning exercise and dietary flavonoids may optimize the exercise and physical activity potential in people with MS. This study nicely demonstrates the importance of understanding and considering possible covariants such as nutrition and chronobiology to determine an optimal exercise prescription model.
TMEP Section Editor Jonathan Myers and colleague Baruch Vainshelboim present a narrative review on "Resistance Training for Rehabilitation of Patients with Idiopathic Pulmonary Fibrosis". In this paper, the pathophysiology and clinical manifestations of Idiopathic Pulmonary Fibrosis (IPF) are summarized with an emphasis on the numerous health and clinical benefits of resistance training among older adults and patients with this respiratory disease. This article effectively explores the potential mechanisms by which systematic resistance training may help overcome exercise limitations in IPF, providing a therapeutic opportunity for rehabilitation. Furthermore, the authors provide important recommendations for pulmonary rehabilitation programs that are based on resistance training for patients with IPF. With this paper, the authors highlight that disease-adapted exercise prescription requires a pathophysiological understanding to justify the inclusion of specific exercise regimens.
In the final paper of this special issue, the research group of Section Editor Anthony C Hackney shares their original data on the "Energy Availability and RED-S Risk Factors in Competitive, Non-elite Male Endurance Athletes". This paper particularly emphasizes the entire spectrum of TMEP, that is more than just the most common types of non-communicable diseases, but also includes chronic conditions that may be for example induced by athletic training. In this study, the authors assessed the associations of energy availability and risk factors of relative energy deficiency in sport (RED-S) in 60 competitive, recreationally trained male endurance athletes. They found that hormonal and bone biomarkers were within normal clinical ranges, even when the energy availability was low. The authors further state that athletes are
转化医学和运动处方(TMEP):推进运动医学时代
肥胖和不健康的生活方式也是2型糖尿病(T2DM)的危险因素。TMEP部分编辑Thomas Yates的研究小组通过题为“运动、药物治疗和2型糖尿病:从血糖控制到全身健康和功能”的叙述综述,强调了运动和医学治疗相结合的研究机遇和挑战。作者提供了新一代降糖疗法的证据,这些疗法也能诱导伴随的体重减轻,特别是胰高血糖素样肽-1受体激动剂(GLP-1RAs)和钠-葡萄糖共转运蛋白2抑制剂(SGLT2is)。基于目前的知识,他们强调了研究运动与其他降糖或减肥疗法之间的相互作用或协同作用的重要性,使运动成为治疗2型糖尿病的量身定制的治疗方法,而不是通用的治疗方法。因此,这篇综述清楚地强调了精确运动处方的必要性,这源于对运动效果的深入机制理解。癌症是另一种重要的代谢和慢性炎症性疾病,也可能与肥胖有关。TMEP部分编辑Jesper F Christensen和副编辑Ciaran M Fairman在他们的文章《针对癌症患者的运动训练:超越临床肿瘤学的一般运动指南》中提供了一个非常有趣的观点。本文旨在更新运动肿瘤学中有针对性的运动干预的现有知识和临床依据。此外,本文还提出了一个系统指导肿瘤学中有针对性的运动干预的设计和执行的框架。作者希望他们的框架可以鼓励对肿瘤中有针对性的运动干预的进一步研究,也可以作为未来试验设计的指导方针,以提高质量和影响。TMEP章节编辑Helen Dawes小组在题为“多发性硬化症中的体力活动和疲劳:可可类黄酮饮料双盲随机对照试验的次要结果”的文章中分享了他们在神经和精神疾病背景下的原始数据。在这项研究中,他们对一天中的时间、身体活动水平和疲劳之间的相互关系进行了密集的表型分析,以确定一组多发性硬化症(MS)患者的运动处方,这些患者参加了一项为期六周的早晨类黄酮摄入量随机对照试验。研究发现,白天的疲劳程度会增加,而疲劳程度越高,体力活动就越少;然而,体育活动本身并不会增加疲劳。此外,早上摄入可可可以减少白天的疲劳和随后的体力活动引起的疲劳。因此,晨操和膳食黄酮类化合物的联合处方可能会优化ms患者的运动和身体活动潜力。这项研究很好地说明了理解和考虑营养和时间生物学等可能的协变量对于确定最佳运动处方模型的重要性。TMEP部分编辑Jonathan Myers和同事Baruch Vainshelboim对“特发性肺纤维化患者康复的阻力训练”进行了叙述性回顾。本文综述了特发性肺纤维化(IPF)的病理生理学和临床表现,重点介绍了老年人和患有这种呼吸系统疾病的患者进行抗阻训练的众多健康和临床益处。本文有效地探讨了系统阻力训练可能有助于克服IPF运动限制的潜在机制,为康复提供治疗机会。此外,作者还为IPF患者提供了基于阻力训练的肺康复方案的重要建议。在这篇论文中,作者强调,适应疾病的运动处方需要病理生理学的理解来证明特定运动方案的合理性。在本期特刊的最后一篇论文中,章节编辑Anthony C Hackney的研究小组分享了他们关于“竞技、非精英男性耐力运动员的能量可用性和RED-S风险因素”的原始数据。本文特别强调了TMEP的整个范围,即不仅仅是最常见的非传染性疾病类型,还包括可能由运动训练引起的慢性病。在这项研究中,作者评估了60名竞技性、娱乐性训练的男性耐力运动员的能量可用性和运动中相对能量缺乏(RED-S)的风险因素之间的关系。他们发现,即使在能量可用性较低的情况下,激素和骨骼生物标志物也在正常的临床范围内。
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