| Q37065378 | 'From death, lead me to immortality' - mantra of ageing skeletal muscle |
| Q47675142 | * The Impact of Age on Skeletal Muscle Progenitor Cell Survival and Fate After Injury |
| Q34312735 | A simplified but robust method for the isolation of avian and mammalian muscle satellite cells |
| Q42707203 | Absence of CCR2 results in an inflammaging environment in young mice with age-independent impairments in muscle regeneration |
| Q37034374 | Age-dependent alteration in muscle regeneration: the critical role of tissue niche |
| Q37671517 | Age-dependent changes in mitochondrial morphology and volume are not predictors of lifespan |
| Q59132186 | Age-related changes in skeletal muscle: changes to life-style as a therapy |
| Q47131388 | Age-related gene expression in luminal epithelial cells is driven by a microenvironment made from myoepithelial cells |
| Q52129352 | Age-related loss of skeletal muscle function and the inability to express the autocrine form of insulin-like growth factor-1 (MGF) in response to mechanical overload. |
| Q35211860 | Ageing and physiological functions |
| Q45826802 | Ageing is associated with diminished muscle re-growth and myogenic precursor cell expansion early after immobility-induced atrophy in human skeletal muscle. |
| Q37575251 | Aging increases CCN1 expression leading to muscle senescence |
| Q41995562 | Aging-associated exacerbation in fatty degeneration and infiltration after rotator cuff tear. |
| Q90255264 | An Overview about the Biology of Skeletal Muscle Satellite Cells |
| Q80434452 | Antagonism of myostatin enhances muscle regeneration during sarcopenia |
| Q35437651 | Anti-inflammatory macrophages improve skeletal muscle recovery from ischemia-reperfusion |
| Q36651458 | Atrogin-1, MuRF-1, and sarcopenia |
| Q36904095 | Biological basis of exercise-based treatments for musculoskeletal conditions |
| Q36968228 | Bone and skeletal muscle: neighbors with close ties |
| Q42597974 | Brain Aging and Regeneration after Injuries: an Organismal approach |
| Q24620519 | CCAAT-enhancer-binding protein-beta expression in vivo is associated with muscle strength |
| Q39559082 | CDK4 and cyclin D1 allow human myogenic cells to recapture growth property without compromising differentiation potential |
| Q37696180 | Cellular mechanisms of somatic stem cell aging |
| Q26778013 | Changes in Regenerative Capacity through Lifespan |
| Q34964840 | Coaxing stem cells for skeletal muscle repair |
| Q38198994 | Comparative myogenesis in teleosts and mammals |
| Q48357501 | Concise Review: Translating Regenerative Biology into Clinically Relevant Therapies: Are We on the Right Path? |
| Q37256654 | Context matters: in vivo and in vitro influences on muscle satellite cell activity |
| Q37365630 | Decline in muscle strength and running endurance in klotho deficient C57BL/6 mice |
| Q36446664 | Declining cellular fitness with age promotes cancer initiation by selecting for adaptive oncogenic mutations. |
| Q36875163 | Developmental Biology and Regenerative Medicine: Addressing the Vexing Problem of Persistent Muscle Atrophy in the Chronically Torn Human Rotator Cuff |
| Q89964419 | Divergent Roles of Inflammation in Skeletal Muscle Recovery From Injury |
| Q33708184 | Eccentric exercise in aging and diseased skeletal muscle: good or bad? |
| Q70917682 | Effects of age on aneural regeneration of soleus muscle in rat |
| Q35325915 | Effects of high- and low-velocity resistance training on the contractile properties of skeletal muscle fibers from young and older humans |
| Q39740143 | Embryonic anti-aging niche |
| Q35671770 | Emerging models and paradigms for stem cell ageing |
| Q38857342 | Engineered matrices for skeletal muscle satellite cell engraftment and function |
| Q45057729 | Extraocular muscle regeneration in primates. Local anesthetic-induced lesions |
| Q38200095 | Extrinsic Regulation of Satellite Cell Function and Muscle Regeneration Capacity during Aging |
| Q34135241 | Extrinsic regulation of satellite cell specification |
| Q38784876 | Function of Membrane-Associated Proteoglycans in the Regulation of Satellite Cell Growth |
| Q36956383 | Functional deficits and insulin-like growth factor-I gene expression following tourniquet-induced injury of skeletal muscle in young and old rats |
| Q34774475 | Gene therapy for cardiac cachexia? |
| Q30713071 | Gene transcripts associated with muscle strength: a CHARGE meta-analysis of 7,781 persons |
| Q35163122 | Genome instability, cancer and aging |
| Q42041555 | Geroconversion of aged muscle stem cells under regenerative pressure |
| Q36059679 | Heterochronic parabiosis for the study of the effects of aging on stem cells and their niches |
| Q37789857 | Heterogeneity in the muscle satellite cell population |
| Q38124296 | How sex hormones promote skeletal muscle regeneration |
| Q42701900 | Impairment of IGF-I expression and anabolic signaling following ischemia/reperfusion in skeletal muscle of old mice |
| Q42419013 | Increased Adipocyte Area in Injured Muscle With Aging and Impaired Remodeling in Female Mice. |
| Q28084614 | Intrinsic and extrinsic mechanisms regulating satellite cell function |
| Q36961239 | Intrinsic changes and extrinsic influences of myogenic stem cell function during aging |
| Q36117006 | Loss of stem cell regenerative capacity within aged niches |
| Q37331561 | Mature adult dystrophic mouse muscle environment does not impede efficient engrafted satellite cell regeneration and self-renewal. |
| Q26824418 | Meat Science and Muscle Biology Symposium: stem cell niche and postnatal muscle growth |
| Q37287412 | Mechanisms of skeletal muscle aging: insights from Drosophila and mammalian models |
| Q39355079 | Mechanosensing of matrix by stem cells: From matrix heterogeneity, contractility, and the nucleus in pore-migration to cardiogenesis and muscle stem cells in vivo. |
| Q92040803 | Mesenchymal Stromal Cells Are Required for Regeneration and Homeostatic Maintenance of Skeletal Muscle |
| Q27022354 | Mitochondrial dysfunction and sarcopenia of aging: from signaling pathways to clinical trials |
| Q53942492 | Mitogen-activated protein kinase (MAPK) pathway activation: effects of age and acute exercise on human skeletal muscle. |
| Q33349016 | Models of accelerated sarcopenia: critical pieces for solving the puzzle of age-related muscle atrophy |
| Q37014708 | Moderate-intensity treadmill running promotes expansion of the satellite cell pool in young and old mice |
| Q36941459 | Murine models of atrophy, cachexia, and sarcopenia in skeletal muscle |
| Q67767062 | Muscle fiber branching — difference between grafts in old and young rats |
| Q33648473 | Muscle precursor cells isolated from aged rats exhibit an increased tumor necrosis factor- alpha response |
| Q35056437 | Muscle regeneration in amphibians and mammals: passing the torch |
| Q38508660 | Muscle satellite cells are a functionally heterogeneous population in both somite-derived and branchiomeric muscles. |
| Q36802239 | Muscle satellite cells from GRMD dystrophic dogs are not phenotypically distinguishable from wild type satellite cells in ex vivo culture. |
| Q88441149 | Myeloid Cell Responses to Contraction-induced Injury Differ in Muscles of Young and Old Mice |
| Q91760092 | Myeloid cell-derived tumor necrosis factor-alpha promotes sarcopenia and regulates muscle cell fusion with aging muscle fibers |
| Q67715374 | Myosin light chain 1 isoform expression remains constant during ageing in Wistar F455 rats |
| Q34655535 | No place like home: anatomy and function of the stem cell niche |
| Q37278543 | Osteocalcin is necessary and sufficient to maintain muscle mass in older mice. |
| Q34357219 | Pericytes at the intersection between tissue regeneration and pathology |
| Q42328789 | Preventing aging with stem cell rejuvenation: Feasible or infeasible? |
| Q35627456 | Prevention of muscle aging by myofiber-associated satellite cell transplantation |
| Q35213447 | Prospective isolation of skeletal muscle stem cells with a Pax7 reporter |
| Q27318138 | Reduced Satellite Cell Numbers and Myogenic Capacity in Aging Can Be Alleviated by Endurance Exercise |
| Q37121853 | Regulation of muscle growth in neonates |
| Q39121185 | Rejuvenating stem cells to restore muscle regeneration in aging |
| Q29615250 | Rejuvenation of aged progenitor cells by exposure to a young systemic environment |
| Q42264762 | Relative roles of TGF-beta1 and Wnt in the systemic regulation and aging of satellite cell responses |
| Q72312550 | Retarded myogenic cell replication in regenerating skeletal muscles of old mice: an autoradiographic study in young and old BALBc and SJL/J mice |
| Q26778322 | Role of Inflammation in Muscle Homeostasis and Myogenesis |
| Q38542445 | Satellite Cells and Skeletal Muscle Regeneration. |
| Q73484092 | Satellite cell numbers in senile rat levator ani muscle |
| Q38078129 | Satellite cell therapy - from mice to men |
| Q26777962 | Satellite cells in human skeletal muscle plasticity |
| Q37261298 | Satellite-cell pool size does matter: defining the myogenic potency of aging skeletal muscle |
| Q37371320 | Sca-1-expressing nonmyogenic cells contribute to fibrosis in aged skeletal muscle |
| Q33766697 | Skeletal muscle as a regulator of the longevity protein, Klotho |
| Q89599729 | Skeletal muscle as an experimental model of choice to study tissue aging and rejuvenation |
| Q36128743 | Skeletal muscle damage with exercise and aging. |
| Q35885657 | Skeletal muscle satellite cells: background and methods for isolation and analysis in a primary culture system |
| Q42159938 | Sources for skeletal muscle repair: from satellite cells to reprogramming |
| Q90190005 | Stem Cell Aging in Skeletal Muscle Regeneration and Disease |
| Q40966771 | Stem Cells and Tissue Niche: Two Faces of the Same Coin of Muscle Regeneration. |
| Q26828390 | Stem cells for skeletal muscle regeneration: therapeutic potential and roadblocks |
| Q36523915 | Stem cells, ageing and the quest for immortality. |
| Q38625964 | Systemic Problems: A perspective on stem cell aging and rejuvenation |
| Q92453264 | Systemic milieu and age-related deterioration |
| Q51786747 | The Fountain of Youth: A Tale of Parabiosis, Stem Cells, and Rejuvenation. |
| Q34302715 | The aged niche disrupts muscle stem cell quiescence. |
| Q26801427 | The central role of muscle stem cells in regenerative failure with aging |
| Q33788099 | The depletion of skeletal muscle satellite cells with age is concomitant with reduced capacity of single progenitors to produce reserve progeny |
| Q33894950 | The effect of calorie restriction on mouse skeletal muscle is sex, strain and time-dependent |
| Q36915911 | The effect of muscle loading on skeletal muscle regenerative potential: an update of current research findings relating to aging and neuromuscular pathology |
| Q27008819 | The effect of physiological stimuli on sarcopenia; impact of Notch and Wnt signaling on impaired aged skeletal muscle repair |
| Q34376468 | The emerging relationship between regenerative medicine and physical therapeutics. |
| Q74115020 | The host environment determines strain-specific differences in the timing of skeletal muscle regeneration: cross-transplantation studies between SJL/J and BALB/c mice |
| Q26771242 | The ins and outs of muscle stem cell aging |
| Q36357449 | The lymphocyte secretome from young adults enhances skeletal muscle proliferation and migration, but effects are attenuated in the secretome of older adults |
| Q34248711 | The p53 network: cellular and systemic DNA damage responses in aging and cancer |
| Q35767940 | The skeletal muscle satellite cell: still young and fascinating at 50 |
| Q64894373 | The transcription factor Slug represses p16Ink4a and regulates murine muscle stem cell aging. |
| Q89123769 | Tissue aging: the integration of collective and variant responses of cells to entropic forces over time |
| Q37429379 | Tissue resident stem cells: till death do us part |
| Q36601648 | Vesicular Galectin-3 levels decrease with donor age and contribute to the reduced osteo-inductive potential of human plasma derived extracellular vesicles |
| Q26770845 | When stem cells grow old: phenotypes and mechanisms of stem cell aging |
| Q33806427 | p38 MAPK signaling underlies a cell-autonomous loss of stem cell self-renewal in skeletal muscle of aged mice |