Pages that link to "Q33427249"

The following pages link to Performing at extreme altitude: muscle cellular and subcellular adaptations (Q33427249):

Displaying 31 items.

• Molecular networks in skeletal muscle plasticity (Q26770564) (← links)
• Ultrastructural modifications in the mitochondria of hypoxia-adapted Drosophila melanogaster (Q27318305) (← links)
• Unsupervised clustering of gene expression data points at hypoxia as possible trigger for metabolic syndrome (Q30478807) (← links)
• Changes in mitochondrial enzymatic activities of monocytes during prolonged hypobaric hypoxia and influence of antioxidants: A randomized controlled study. (Q33464764) (← links)
• Oral Coenzyme Q10 supplementation does not prevent cardiac alterations during a high altitude trek to everest base cAMP. (Q34751199) (← links)
• High-altitude physiology and pathophysiology: implications and relevance for intensive care medicine (Q36296544) (← links)
• Upper airway myopathy is not important in the pathophysiology of obstructive sleep apnea (Q36997370) (← links)
• Load management in elite German distance runners during 3-weeks of high-altitude training (Q37049557) (← links)
• Hypoxia: the third wheel between nerve and muscle. (Q37132429) (← links)
• Developmental plasticity of mitochondrial function in American alligators, Alligator mississippiensis (Q37600625) (← links)
• Muscle wasting in disease: molecular mechanisms and promising therapies (Q38303979) (← links)
• Mitochondrial function at extreme high altitude (Q38512125) (← links)
• HIF-1-driven skeletal muscle adaptations to chronic hypoxia: molecular insights into muscle physiology. (Q38571761) (← links)
• Physiological and ecological implications of ocean deoxygenation for vision in marine organisms (Q38645781) (← links)
• Caudwell Xtreme Everest: An Overview (Q38876627) (← links)
• Metabolic adaptation of skeletal muscle to high altitude hypoxia: how new technologies could resolve the controversies. (Q39908093) (← links)
• Adaptive myogenesis under hypoxia (Q40441256) (← links)
• Serum irisin and myostatin levels after 2 weeks of high-altitude climbing (Q41090194) (← links)
• Myostatin up-regulation is associated with the skeletal muscle response to hypoxic stimuli (Q42872681) (← links)
• Postural instability at a simulated altitude of 5,000 m before and after an expedition to Mt. Cho-Oyu (8,201 m). (Q43022478) (← links)
• Molecular factors involved in the control of muscle mass during hypoxia-exposure: the main hypotheses are revisited (Q43793580) (← links)
• Gokyo Khumbu/Ama Dablam Trek 2012: effects of physical training and high-altitude exposure on oxidative metabolism, muscle composition, and metabolic cost of walking in women (Q48045042) (← links)
• Endurance training prevents negative effects of the hypoxia mimetic dimethyloxalylglycine on cardiac and skeletal muscle function. (Q48278750) (← links)
• Twenty-eight days of exposure to 3454 m increases mitochondrial volume density in human skeletal muscle (Q50564221) (← links)
• Effect of hypoxia exposure on the phenotypic adaptation in remodelling skeletal muscle submitted to functional overload. (Q51038293) (← links)
• Effect of hypoxia exposure on the recovery of skeletal muscle phenotype during regeneration. (Q51171170) (← links)
• PEDF protects cardiomyocytes by promoting FUNDC1‑mediated mitophagy via PEDF-R under hypoxic condition (Q51735660) (← links)
• Effects of high altitude on sleep and respiratory system and theirs adaptations. (Q55601228) (← links)
• Comments on Point:Counterpoint “Positive effects of intermittent hypoxia (live high:train low) on exercise performance are/are not mediated primarily by augmented red cell volume” (Q56964893) (← links)
• Acclimatization of skeletal muscle mitochondria to high‐altitude hypoxia during an ascent of Everest (Q57099019) (← links)
• Comparative microRNA Transcriptomes in Domestic Goats Reveal Acclimatization to High Altitude (Q98735775) (← links)