Cardiovascular and skeletal muscle health with lifelong exercise

Gries, Kevin J.; Raue, Ulrika; Perkins, Ryan; Lavin, Kaleen M.; Overstreet, Brittany S.; D'Acquisto, Leonardo J.; Graham, Bruce; Finch, W. Holmes; Kaminsky, Leonard A.; Trappe, Todd A.; Trappe, Scott

doi:10.1152/japplphysiol.00174.2018

Cited by 81 publications

(84 citation statements)

References 58 publications

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“…Nevertheless, it is clear from our results that chronic endurance exercise training leads to greater MHC I and II fibre capilliarisation in MA compared with OC and, in some cases, YC. These findings are consistent with recent evidence that the continuation of endurance training into older age maintains skeletal muscle capilliarisation47 .However, recent evidence from a cross-sectional analysis of highly trained MA (55-79 y)suggests that chronic endurance training does not completely prevent the decline in capillary density12 . Nevertheless, the greater muscle fibre capilliarisation and MHC I fibre area observed in our cohort of endurance-trained MA may, at least partly, explain their superior aerobic fitness levels.Whilst our findings clearly demonstrate superior indices of physiological function and muscle morphology in MA compared with OC, we are unable to determine whether chronic endurance exercise offsets the trajectory of age-related physiological deterioration.…”

supporting

confidence: 89%

Superior Aerobic Capacity and Indices of Skeletal Muscle Morphology in Chronically Trained Master Endurance Athletes Compared With Untrained Older Adults

McKendry¹,

Joanisse

Baig

et al. 2019

The Journals of Gerontology: Series A

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The study aim was to comprehensively assess physiological function and muscle morphology in chronically trained older individuals against untrained young and older individuals. In a cross-sectional design, 15 young untrained controls (YC) (20 ± 2.7 years, 78.9 ± 13.3 kg), 12 untrained older controls (OC) (69.8 ± 4.1 years, 77.5 ± 14.2 kg), and 14 endurance-trained master athletes (MA) (67.1 ± 4.1 years, 68.7 ± 6.5 kg) underwent assessments of body composition, aerobic capacity, strength, muscle architecture, and fiber-type morphology. Skeletal muscle index was lower and body fat greater in OC versus MA. Estimated VO2max (mL·kg−1·minute−1) was similar between MA and YC, but lower in OC. Isometric leg strength normalized to fat-free mass was similar between groups, whereas normalized isometric arm strength was greater in YC than MA. Myosin heavy chain (MHC) I fiber area was greater in MA than OC, while MHC II fiber area was greater in YC than OC. MHC II fiber myonuclear domain size was greater in YC than OC and MA, whereas MA had greater MHC I and MHC II fiber capillarization than OC and YC. Satellite cell content was similar between groups. Chronic endurance training enhances indices of muscle morphology and improves body composition and aerobic capacity in older age, with potentially important implications for healthspan extension.

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supporting

confidence: 89%

Superior Aerobic Capacity and Indices of Skeletal Muscle Morphology in Chronically Trained Master Endurance Athletes Compared With Untrained Older Adults

McKendry¹,

Joanisse

Baig

et al. 2019

The Journals of Gerontology: Series A

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“…Prior research has found that that sedentary elderly subjects have ~25% lower capillarization than sedentary young subjects, while elderly master athletes (i.e. lifelong exercisers) have similar capillarization to young athletes [50][51][52] ; we find a similar pattern in endothelial cell compartment changes with training. Although there is little data regarding levels of immune cells in skeletal muscle during the menstrual-cycle, there are menstrual-cycle related differences in the proportions of circulating immune cell types 53 .…”

Section: Discussionsupporting

confidence: 67%

“…All procedures associated with the research were approved by the Institutional Review Board at Ball State University and performed in accordance with relevant guidelines and regulations. Subjects 8,52 provided written informed consent prior to participation. Muscle biopsies were obtained from the vastus lateralis as we have previously described 8,52 .…”

Section: Methodsmentioning

confidence: 99%

Single-cell transcriptional profiles in human skeletal muscle

Rubenstein

Smith

Raue

et al. 2020

Sci Rep

Self Cite

216

211

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Skeletal muscle is a heterogeneous tissue comprised of muscle fiber and mononuclear cell types that, in addition to movement, influences immunity, metabolism and cognition. We investigated the gene expression patterns of skeletal muscle cells using RNA-seq of subtype-pooled single human muscle fibers and single cell RNA-seq of mononuclear cells from human vastus lateralis, mouse quadriceps, and mouse diaphragm. We identified 11 human skeletal muscle mononuclear cell types, including two fibro-adipogenic progenitor (FAP) cell subtypes. The human FBN1+ FAP cell subtype is novel and a corresponding FBN1+ FAP cell type was also found in single cell RNA-seq analysis in mouse. Transcriptome exercise studies using bulk tissue analysis do not resolve changes in individual cell-type proportion or gene expression. The cell-type gene signatures provide the means to use computational methods to identify cell-type level changes in bulk studies. As an example, we analyzed public transcriptome data from an exercise training study and revealed significant changes in specific mononuclear cell-type proportions related to age, sex, acute exercise and training. Our single-cell expression map of skeletal muscle cell types will further the understanding of the diverse effects of exercise and the pathophysiology of muscle disease.Skeletal muscle is a complex heterogeneous tissue consisting of multinucleated muscle fibers, immune cells, endothelial cells, muscle stem cells (satellite cells), non-myogenic mesenchymal progenitors (e.g., fibro-adipogenic progenitors, or FAPs), and other mononuclear cells 1 . To improve the understanding of skeletal muscle cell types and their transcriptional signatures, we studied human and mouse skeletal muscle mononuclear cells by single-cell RNA-sequencing and single human muscle fiber subtypes by RNA-seq.The majority of skeletal muscle is composed of the multinucleated fibers that facilitate movement. These muscle fibers include several fiber types of differing metabolic and functional properties 2-4 . While slow-twitch (or Type I) muscle fibers possess high oxidative capacity, fast-twitch (or Type II) muscle fibers have a high glycolytic capacity and are capable of supplying more power than Type I fibers 2-4 . Fiber-type composition differs across individuals and can change by as much as 10-30% during exercise training regimens 5-7 . Furthermore, the transcriptomic response to physical activity is different in each fiber-type as each fiber-type responds differently to different modes of exercise 8,9 . Crucially, muscle fibers secrete myokines, which both act locally within muscle tissue as well as influence other organs and tissues via hormone-like signaling 10 . Myokines may be responsible for the immune-, metabolism-, and cognition-related benefits of physical activity, as well as the chronic diseases that are caused by lack of physical activity (insulin resistance, cardiovascular disease, etc.) 10 .Besides multinucleated fibers, skeletal muscle contains many mononuclear cells, such as immune cells,...

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“…Similar to Section 4.1, we successively consider the cases where the coupling constraint in (P × ′ ) is loose or tight. In both cases, we will show that the optimal practice process can be structured in cycles, demonstrating the power of habit for skill retention, consistent with the empirical evidence of the benefits of lifelong exercise (Gries et al 2018).…”

Section: Multiplicative Model (Skill Retention)supporting

confidence: 77%

“…In addition to developing mathematical models, the physiology literature provides ample evidence of high-performance strategies such as "tapering" (i.e., progressively reducing the training load before a race [Mujika and Padilla 2003]), "periodization" (i.e., structuring the training program in cycles of highintensity sessions followed by periods of recovery [Bompa and Haff 2009]), and lifelong exercise for long-term benefits (Gries et al 2018). However, few attempts have been made to demonstrate the optimality of such strategies besides Morton (1991) and Banister et al (1999), who evaluated the performance of a specific set of training profiles via simulation.…”

Section: Training For Endurance Sportsmentioning

confidence: 99%

High-Performance Practice Processes

Roels

2020

Management Science

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Despite their idiosyncrasies, motor and cognitive learning and endurance sports training have in common that they involve repeated practice. While considerable research has been devoted to the effect of practice on performance, little is known about optimal practice strategies. In this paper, we model the practice process for both skill acquisition and retention, and optimize its profile to maximize performance on a predefined date. For skill acquisition, we find that the optimal process involves multiple phases of practice increase and decrease, yielding U-shaped effort consistent with the principle of distributing practice, and that the transitions between phases are smoother for skills that are easily forgotten (e.g., cognitive skills) than for those that are easily retained (e.g., continuous motor skills). In particular for the latter, an extended period of rest should precede an ultimate high-intensity stress. For skill retention, the optimal practice strategy consists of cycles of either constant effort (for skills that are easily forgotten) or pulsed effort (for skills that are easily retained) consistent with the principle of alternating stress and rest. Our parametric model thus indicates when commonly used high-performance practice strategies are indeed optimal. This paper was accepted by Serguei Netessine, operations management.

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Cardiovascular and skeletal muscle health with lifelong exercise

Cited by 81 publications

References 58 publications

Superior Aerobic Capacity and Indices of Skeletal Muscle Morphology in Chronically Trained Master Endurance Athletes Compared With Untrained Older Adults

Superior Aerobic Capacity and Indices of Skeletal Muscle Morphology in Chronically Trained Master Endurance Athletes Compared With Untrained Older Adults

Single-cell transcriptional profiles in human skeletal muscle

High-Performance Practice Processes

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