326 results on '"Murach, Kevin"'
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52. Exercise Counteracts the Deleterious Effects of Cancer Cachexia
53. Epigenetic Evidence for Distinct Contributions of Resident and Acquired Myonuclei During Long‐Term Exercise Adaptation Using Timed In Vivo Myonuclear Labeling
54. Depletion of Pax7+ satellite cells does not affect diaphragm adaptations to running in young or aged mice
55. Going nuclear: Molecular adaptations to exercise mediated by myonuclei.
56. sj-pdf-1-ajs-10.1177_03635465221135769 – Supplemental material for Depressed Protein Synthesis and Anabolic Signaling Potentiate ACL Tear–Resultant Quadriceps Atrophy
57. A muscle cell‐macrophage axis involving matrix metalloproteinase 14 facilitates extracellular matrix remodeling with mechanical loading
58. Muscle-Specific Cellular and Molecular Adaptations to Late-Life Voluntary Concurrent Exercise
59. Epigenetic evidence for distinct contributions of resident and acquired myonuclei during long-term exercise adaptation using timed in vivo myonuclear labeling
60. Late‐life exercise mitigates skeletal muscle epigenetic aging
61. Deletion of SA β‐Gal+ cells using senolytics improves muscle regeneration in old mice
62. Depressed Protein Synthesis and Anabolic Signaling Potentiate ACL Tear–Resultant Quadriceps Atrophy.
63. Fusion and beyond: Satellite cell contributions to loading‐induced skeletal muscle adaptation
64. Reduced mitochondrial DNA and OXPHOS protein content in skeletal muscle of children with cerebral palsy
65. Genetic and epigenetic regulation of skeletal muscle ribosome biogenesis with exercise
66. Reduced mitochondrial DNA and OXPHOS protein content in skeletal muscle of children with cerebral palsy
67. Genetic and epigenetic regulation of skeletal muscle ribosome biogenesis with exercise
68. Nucleus Type-Specific DNA Methylomics Reveals Epigenetic “Memory” of Prior Adaptation in Skeletal Muscle
69. Genetic and Epigenetic Regulation of Skeletal Muscle Ribosome Biogenesis with Exercise
70. Satellite Cell Depletion Disrupts Transcriptional Coordination and Muscle Adaptation to Exercise
71. Muscle memory: myonuclear accretion, maintenance, morphology, and miRNA levels with training and detraining in adult mice
72. Making Mice Mighty: recent advances in translational models of load-induced muscle hypertrophy
73. Depletion of resident muscle stem cells negatively impacts running volume, physical function, and muscle fiber hypertrophy in response to lifelong physical activity
74. The myonuclear DNA methylome in response to an acute hypertrophic stimulus
75. Ribosomal DNA Transcription Induced by Acute Resistance Exercise is Dependent on rDNA Gene Dosage but not Promoter Methylation
76. Transcriptional profiling of skeletal muscle during hypertrophy in the absence of satellite cell participation reveals muscle‐specific diversity and satellite cell dependent signaling networks
77. Fusion-Independent Satellite Cell Communication to Muscle Fibers During Load-Induced Hypertrophy
78. “Muscle memory” not mediated by myonuclear number? Secondary analysis of human detraining data
79. Fiber typing human skeletal muscle with fluorescent immunohistochemistry
80. Deletion of SA β‐Gal+ cells using senolytics improves muscle regeneration in old mice.
81. Late‐life exercise mitigates skeletal muscle epigenetic aging.
82. Life-long reduction in myomiR expression does not adversely affect skeletal muscle morphology
83. Resident muscle stem cells are not required for testosterone-induced skeletal muscle hypertrophy
84. Elevated myonuclear density during skeletal muscle hypertrophy in response to training is reversed during detraining
85. Depletion of resident muscle stem cells inhibits muscle fiber hypertrophy induced by lifelong physical activity
86. Additional file 4: of Differential requirement for satellite cells during overload-induced muscle hypertrophy in growing versus mature mice
87. Additional file 1: of Differential requirement for satellite cells during overload-induced muscle hypertrophy in growing versus mature mice
88. Additional file 2: of Differential requirement for satellite cells during overload-induced muscle hypertrophy in growing versus mature mice
89. Additional file 5: of Differential requirement for satellite cells during overload-induced muscle hypertrophy in growing versus mature mice
90. Additional file 3: of Differential requirement for satellite cells during overload-induced muscle hypertrophy in growing versus mature mice
91. Fusion-Independent Satellite Cell Communication to Muscle Fibers During Load-Induced Hypertrophy.
92. Myocellular Responses to Concurrent Flywheel Training during 70 Days of Bed Rest
93. To hypertrophy and beyond! Myostatin and its association to intermuscular adipose tissue with exercise and aging
94. Myonuclear Domain Flexibility Challenges Rigid Assumptions on Satellite Cell Contribution to Skeletal Muscle Fiber Hypertrophy
95. Skeletal Muscle Gene Expression Study of Monozygous Twins with 35 Years of Divergent Exercise History
96. Myonuclear Transcriptional Rate Differs in Young versus Mature Mice
97. MyoVision: software for automated high-content analysis of skeletal muscle immunohistochemistry
98. Starring or Supporting Role? Satellite Cells and Skeletal Muscle Fiber Size Regulation
99. Differential requirement for satellite cells during overload-induced muscle hypertrophy in growing versus mature mice
100. Methodological issues limit interpretation of negative effects of satellite cell depletion on adult muscle hypertrophy
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