Scientific reports

journal of proteomics

PloS one

International journal of molecular sciences

ACS omega

the international journal of biochemistry & cell biology

current pharmaceutical design

Animals : an open access journal from MDPI

The Journal of frailty & aging

acta physiologica (oxford, england)

animal genetics

porcine health management

journal of applied physiology (bethesda, md : 1985)

Endocrine research

[1] Trehalose Protects against Insulin Resistance-Induced Tissue Injury and Excessive Autophagy in Skeletal Muscles and Kidney.

[2] Analysis of genetic variation contributing to measured speed in Thoroughbreds identifies genomic regions involved in the transcriptional response to exercise.

[3] Doxorubicin-induced skeletal muscle atrophy: elucidating the underlying molecular pathways.

[4] Naturally Produced Lovastatin Modifies the Histology and Proteome Profile of Goat Skeletal Muscle.

[5] Single muscle fibre biomechanics and biomechatronics - The challenges, the pitfalls and the future.

[6] Epigenome- and Transcriptome-wide Changes in Muscle Stem Cells from Low Birth Weight Men.

[7] Study of the AMP-Activated Protein Kinase Role in Energy Metabolism Changes during the Postmortem Aging of Yak .

[8] Resistance exercise training promotes fiber type-specific myonuclear adaptations in older adults.

[9] als as a distal axonopathy: molecular mechanisms affecting neuromuscular junction stability in the presymptomatic stages of the disease.

[10] creatine transporter (slc6a8) knock out mice display an increased capacity for in vitro creatine biosynthesis in skeletal muscle

[11] isquemia e reperfusão de músculo sóleo de ratos sob ação da pentoxifilina ischemia and reperfusion of the soleus muscle of rats with pentoxifylline

[12] effect of perimuscular injection of bothrops jararacussu venom on plasma creatine kinase levels in mice: influence of dose and volume

[13] skeletal muscle satellite cells, mitochondria and micrornas: their involvement in the pathogenesis of als

[14] muscle pathology in upper motor neuron paraplegia

[15] microtubule organization in striated muscle cells

[16] acute endurance exercises induces nuclear p53 abundance in human skeletal muscle

[17] antisense oligonucleotide-mediated suppression of muscle glycogen synthase 1 synthesis as an approach for substrate reduction therapy of pompe disease

[18] impaired exercise performance and skeletal muscle mitochondrial function in rats with secondary carnitine deficiency

[19] yap-mediated mechanotransduction in skeletal muscle

[20] the role of vitamin d in skeletal and cardiac muscle function

[21] vascular endothelial regulation of obesity-associated insulin resistance

[22] the progress of tio𝟐 nanocrystals doped with rare earth ions

[23] muscle specific mirnas are induced by testosterone and independently upregulated by age.

[24] qtl analysis of type i and type iia fibers in soleus muscle in a cross between lg/j and sm/j mouse strains

[25] thyroid hormones play role in sarcopenia and myopathies

[26] chronic administration of a leupeptin-derived calpain inhibitor fails to ameliorate severe muscle pathology in a canine model of duchenne muscular dystrophy

[27] ablation of protein kinase ck2β in skeletal muscle fibers interferes with their oxidative capacity

[28] risk of myopathy in patients in therapy with statins: identification of biological markers in a pilot study

[29] circular rna circsvil promotes myoblast proliferation and differentiation by sponging mir-203 in chicken

[30] Impaired Orai1-mediated Resting Ca2+ Entry Reduces the Cytosolic [Ca2+] and Sarcoplasmic Reticulum Ca2+ Loading in Quiescent Junctophilin 1 Knock-out Myotubes

[31] Mahanine enhances the glucose-lowering mechanisms in skeletal muscle and adipocyte cells.

[32] HIIT changes the expression of MuRF1 and MAFBx proteins and proteins involved in the mTOR pathway and autophagy in rat skeletal muscle.

[33] The hepatic and skeletal muscle ovine metabolomes as affected by weight loss: a study in three sheep breeds using NMR-metabolomics.

[34] Nobiletin fortifies mitochondrial respiration in skeletal muscle to promote healthy aging against metabolic challenge.

[35] Engineered skeletal muscles for disease modeling and drug discovery

[36] Skeletal muscle differentiation drives a dramatic downregulation of RNA polymerase III activity and differential expression of Polr3g isoforms

[37] Trehalose Protects against Insulin Resistance-Induced Tissue Injury and Excessive Autophagy in Skeletal Muscles and Kidney.

[38] Cold water immersion attenuates anabolic signalling and skeletal muscle fiber hypertrophy, but not strength gain, following whole-body resistance training.

[39] Dynamic enhancers control skeletal muscle identity and reprogramming.

[40] [Effect of electroacupuncture combined with treadmill exercise on body weight and expression of PGC-1α， Irisin and AMPK in skeletal muscle of diet-induced obesity rats].

[41] Doxorubicin-induced skeletal muscle atrophy: elucidating the underlying molecular pathways.

[42] Doxorubicin chemotherapy affects the intracellular and interstitial free amino acid pools in skeletal muscle.

[43] Nitrate uptake and metabolism in human skeletal muscle cell cultures

[44] The Role of the Gut Microbiome on Skeletal Muscle Mass and Physical Function: 2019 Update

[45] Skeletal Muscle Function during Exercise—Fine-Tuning of Diverse Subsystems by Nitric Oxide

[46] Concurrent Label-Free Mass Spectrometric Analysis of Dystrophin Isoform Dp427 and the Myofibrosis Marker Collagen in Crude Extracts from mdx-4cv Skeletal Muscles

[47] Correlation between Ribosome Biogenesis and the Magnitude of Hypertrophy in Overloaded Skeletal Muscle.

[48] Ultrasound image processing to estimate the structural and functional properties of mouse skeletal muscle

[49] Naturally Produced Lovastatin Modifies the Histology and Proteome Profile of Goat Skeletal Muscle.

[50] Cardiovascular Control During Exercise: the Connectivity of Skeletal Muscle Afferents to the Brain.

[51] [Formula: see text] Accelerated quantification of tissue sodium concentration in skeletal muscle tissue: quantitative capability of dictionary learning compressed sensing.

[52] Effects of long-term feeding of rapeseed meal on skeletal muscle transcriptome, production efficiency and meat quality traits in Norwegian Landrace growing-finishing pigs.

[53] Influence of cannabinoids upon nerve-evoked skeletal muscle contraction.

[54] MicroRNA-34a causes ceramide accumulation and effects insulin signaling pathway by targeting ceramide kinase (CERK) in aging skeletal muscle.

[55] Nerve damage induced skeletal muscle atrophy is associated with increased accumulation of intramuscular glucose and polyol pathway intermediates.

[56] Proteomic analysis of the sarcolemma-enriched fraction from dystrophic mdx-4cv skeletal muscle

[57] Defects in sarcolemma repair and skeletal muscle function after injury in a mouse model of Niemann-Pick type A/B disease

[58] Subproteomic profiling of sarcolemma from dystrophic mdx-4cv skeletal muscle

[59] Erratum to: Impact of repeated bouts of eccentric exercise on sarcolemma disruption in human skeletal muscle (Acta Physiologica Hungarica (2009) 96:2 (189–202) DOI: 10.1556/APhysiol.96.2009.2.4)

[60] Mitochondrial oxidative phosphorylation complexes exist in the sarcolemma of skeletal muscle

[61] Expression of dystrophin -glycoprotein complex at the skeletal muscle sarcolemma in Duchenne muscular dystrophy

[62] In Vivo microscopy reveals extensive embedding of capillaries within the sarcolemma of skeletal muscle fibers

[63] Cytoskeleton, L-type Ca2+ and stretch activated channels in injured skeletal muscle

[64] Phorbol ester treatment inhibits proliferation and differentiation of cultured human skeletal muscle satellite cells by differentially acting on protein kinase C isoforms

[65] Acute ethanol administration oxidatively damages and depletes mitochondrial dna in mouse liver, brain, heart, and skeletal muscles: protective effects of antioxidants

[66] Skeletal muscle pathology in ovine congenital progressive muscular dystrophy

[67] Structural and functional changes in skeletal muscle in anorexia nervosa

[68] Electron microscopic and enzyme histochemical studies of cerebellum, ocular and skeletal muscles in chronic progressive ophthalmoplegia with cerebellar ataxia

[69] Comparative Analysis of Skeletal Muscle Metabolites of Fish with Various Rates of Aging

[70] variability in myosteatosis and insulin resistance induced by high-fat diet in mouse skeletal muscles

[71] myricetin ameliorates defective post-receptor insulin signaling via β-endorphin signaling in the skeletal muscles of fructose-fed rats

[72] evidence for a non-genomic action of testosterone in skeletal muscle which may improve athletic performance: implications for the female athlete

[73] effect of tramadol on lung injury induced by skeletal muscle ischemia-reperfusion: an experimental study

[74] creatine transporter (slc6a8) knock out mice display an increased capacity for in vitro creatine biosynthesis in skeletal muscle

[75] differential effects of diet composition and timing of feeding behavior on rat brown adipose tissue and skeletal muscle peripheral clocks

[76] a dic based technique to measure the contraction of a skeletal muscle engineered tissue

[77] the effects of exercise and conjugated linoleic acid intake on igf-1 and pro-inflammatory cytokines in atrophied skeletal muscle of rats

[78] fifteen days of 3,200 m simulated hypoxia marginally regulates markers for protein synthesis and degradation in human skeletal muscle

[79] label-free lc-ms profiling of skeletal muscle reveals heart-type fatty acid binding protein as a candidate biomarker of aerobic capacity

[80] the process of engraftment of myogenic cells in skeletal muscles of primates

[81] plasma cytokine response, lipid peroxidation and nf-κb activation in skeletal muscle following maximum progressive swimming

[82] skeletal muscle satellite cells, mitochondria and micrornas: their involvement in the pathogenesis of als

[83] loss of myod and myf5 in skeletal muscle stem cells results in altered myogenic programming and failed regeneration

[84] acute endurance exercises induces nuclear p53 abundance in human skeletal muscle

[85] the cross-bridge of skeletal muscle is not synchronized either by length or force step

[86] simple silicone chamber system for 3d skeletal muscle tissue formation

[87] inhibition of the activin receptor type-2b pathway restores regenerative capacity in satellite cell-depleted skeletal muscle

[88] circadian rhythm of intracellular protein synthesis signaling in rat cardiac and skeletal muscles

[89] nutritional interventions to augment resistance training-induced skeletal muscle hypertrophy

[90] neuromuscular electrical stimulation as a potential countermeasure for skeletal muscle atrophy and weakness during human spaceflight

[91] syngeneic b16f10 melanoma causes cachexia and impaired skeletal muscle strength and locomotor activity in mice

[92] aerobic exercise training in heart failure: impact on sympathetic hyperactivity and cardiac and skeletal muscle function

[93] co-expression network approach reveals functional similarities among diseases affecting human skeletal muscle

[94] maternal obesity and the development of skeletal muscle in offspring – fetal origin of metabolic disorders

[95] experimental studies of the molecular pathways regulated by exercise and resveratrol in heart, skeletal muscle and the vasculature

[96] the hypobaric hypoxia affects the oxidant balance in skeletal muscle regeneration of women

[97] impaired exercise performance and skeletal muscle mitochondrial function in rats with secondary carnitine deficiency

[98] yap-mediated mechanotransduction in skeletal muscle

[99] a metabolic link to skeletal muscle wasting and regeneration

[100] high fat diet-induced skeletal muscle wasting is decreased by mesenchymal stem cells administration: implications on oxidative stress, ubiquitin proteasome pathway activation, and myonuclear apoptosis

[101] erratum to “overexpression of pgc-1 increases fatty acid oxidative capacity of human skeletal muscle cells”