Hypoxia-induced skeletal muscle fiber dysfunction: role for reactive nitrogen species

Ottenheijm, Coen A.C.; Heunks, Leo; Geraedts, Maartje C. P.; Dekhuijzen, P.N.R.

doi:10.1152/ajplung.00073.2005

Cited by 26 publications

(41 citation statements)

References 46 publications

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“…Intrapartum hypoxia caused contractile dysfunction in the neonatal diaphragm, significantly reducing the force-generating capacity and sensitivity to Ca 2ϩ . This finding is in agreement with studies in the adult diaphragm (9,10). Supplementation of the maternal diet with creatine completely prevented contractile dysfunction in offspring from hypoxic births.…”

Section: Discussionsupporting

confidence: 91%

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Maternal creatine supplementation from mid-pregnancy protects the newborn spiny mouse diaphragm from intrapartum hypoxia-induced damage

et al. 2010

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ABSTRACT:We hypothesized that maternal creatine supplementation from mid-pregnancy would protect the diaphragm of the newborn spiny mouse from the effects of intrapartum hypoxia. Pregnant mice were fed a control or 5% creatine-supplemented diet from mid-gestation. On the day before term, intrapartum hypoxia was induced by isolating the pregnant uterus in a saline bath for 7.5-8 min before releasing and resuscitating the fetuses. Surviving pups were placed with a cross-foster dam, and diaphragm tissue was collected at 24 h postnatal age. Hypoxia caused a significant decrease in the cross-sectional area (ϳ19%) and contractile function (26.6% decrease in maximum Ca 2ϩ -activated force) of diaphragm fibers. The mRNA levels of the muscle mass-regulating genes MuRF1 and myostatin were significantly increased (2-fold). Maternal creatine significantly attenuated hypoxia-induced fiber atrophy, contractile dysfunction, and changes in mRNA levels. This study demonstrates that creatine loading before birth significantly protects the diaphragm from hypoxiainduced damage at birth. (Pediatr Res 68: 393-398, 2010)

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Section: Discussionsupporting

confidence: 91%

“…Excessive production of reactive oxygen species occurs and promotes myosin and actin degradation (7), leading to damage of myofibrillar proteins (8) and reduced functional capacity of skeletal muscles (9). These changes occur at the single fiber level of adult diaphragm (10). Hypoxia can also result in muscle fiber atrophy in skeletal muscle (11).…”

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confidence: 99%

Maternal creatine supplementation from mid-pregnancy protects the newborn spiny mouse diaphragm from intrapartum hypoxia-induced damage

et al. 2010

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“…single fibers are altered during hypoxia. 20 The decline in maximal and submaximal force was at least partly related to protein modifications, 2 such as increased nitrotyrosine formation. 20 Indeed, hemoglobin, a scavenger of nitric oxide (NO), in the incubation medium alleviated the effects of an NO donor on in vitro diaphragm contractility during hypoxia.…”

Section: Discussionmentioning

confidence: 98%

“…It is also unlikely that the duration of exposure to hypoxia plays a role as a decline in force was already detected after 2 min of hypoxia, 6 whereas others found no change in MVC even after a 40-day simulated climb. 10 Whereas in vivo force-generating capacity of the muscle tissue itself seems to be maintained during hypoxia, in vitro studies generally show a decline in force-generating capacity 2,17,20,26 and a downward shift of the force-frequency relation. 18 We did not find such a depression of force or shift in the forcefrequency relation in the in vivo situation.…”

Section: Discussionmentioning

confidence: 99%

“…Indeed, hypoxia is thought to be a contributing factor to skeletal muscle dysfunction and remodeling during chronic heart failure and chronic obstructive pulmonary disease. 3,13,25 Moreover, the accelerated production of reactive oxygen species during acute hypoxia affects the contractile properties of the diaphragm in vitro, 14,18,20,26 but little is known about the effects of acute hypoxia on the in vivo contractile properties of skeletal muscle.Most human studies on in vivo skeletal muscle function during hypoxia are performed with voluntary contractions. 8,9 Skeletal muscle function, howAbbreviations: ATP, adenosine 5Ј-triphosphate; FIO 2 , fraction of inspired air consisting of oxygen; MVC, maximal voluntary contraction; NO, nitric oxide; P/Po, for the fatigue test, force at a certain time point as a percentage of the force at the onset of the fatigue test; P/Po, for the force-frequency relation, force at a given stimulation frequency as a percentage of the force generated during 100-HZ stimulation; PaO 2 , arterial oxygen partial pressure; ROS, reactive oxygen species; SaO 2 , oxygen saturation of hemoglobin…”

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confidence: 99%

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Acute hypoxia limits endurance but does not affect muscle contractile properties

2005

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Acute hypoxia causes skeletal muscle dysfunction in vitro, but little is known about its effect on muscle function in vivo. In 10 healthy male subjects, isometric contractile properties and fatigue resistance of the quadriceps muscle were determined during normoxia and hypoxia using electrically evoked and voluntary contractions. The oxygen saturation (SaO(2); 96.9 +/- 0.7 vs. 79.9 +/- 3.0%; P < 0.001) was reduced during hypoxia. The maximal voluntary contraction (MVC), force-frequency relation, and contraction and relaxation times were unaffected by hypoxia. The endurance time of a sustained 30% MVC was reduced in hypoxia (248 +/- 104 vs. 217 +/- 76 s; P < 0.05), but not that of a sustained 70% MVC. Fatigue induced by electrically evoked intermittent contractions was unaltered. Thus, acute hypoxia has no significant impact on contractile properties of skeletal muscle in vivo but causes reduced endurance during low-level sustained voluntary contractions. This indicates that skeletal muscle dysfunction during conditions associated with prolonged hypoxemia, except for limited endurance, is not due to acute effects of hypoxemia.

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Changes in contractile properties of skinned single rat soleus and diaphragm fibres after chronic hypoxia

Degens

Bosutti

Gilliver

et al. 2010

Pflugers Arch - Eur J Physiol

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Hypoxia may be one of the factors underlying muscle dysfunction during ageing and chronic lung and heart failure. Here we tested the hypothesis that chronic hypoxia per se affects contractile properties of single fibres of the soleus and diaphragm muscle. To do this, the force-velocity relationship, rate of force redevelopment and calcium sensitivity of single skinned fibres from normoxic rats and rats exposed to 4 weeks of hypobaric hypoxia (410 mmHg) were investigated. The reduction in maximal force (P(0)) after hypoxia (p=0.031) was more pronounced in type IIa than type I fibres and was mainly attributable to a reduction in fibre cross-sectional area (p=0.044). In type IIa fibres this was aggravated by a reduction in specific tension (p=0.001). The maximal velocity of shortening (V (max)) and shape of the force velocity relation (a/P(0)), however, did not differ between normoxic and hypoxic muscle fibres and the reduction in maximal power of hypoxic fibres (p=0.012) was mainly due to a reduction in P(0). In conclusion, chronic hypoxia causes muscle fibre dysfunction which is not only due to a loss of muscle mass, but also to a diminished force generating capacity of the remaining contractile material. These effects are similar in the soleus and diaphragm muscle, but more pronounced in type IIa than I fibres.

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Hypoxia-induced skeletal muscle fiber dysfunction: role for reactive nitrogen species

Cited by 26 publications

References 46 publications

Maternal creatine supplementation from mid-pregnancy protects the newborn spiny mouse diaphragm from intrapartum hypoxia-induced damage

Maternal creatine supplementation from mid-pregnancy protects the newborn spiny mouse diaphragm from intrapartum hypoxia-induced damage

Acute hypoxia limits endurance but does not affect muscle contractile properties

Changes in contractile properties of skinned single rat soleus and diaphragm fibres after chronic hypoxia

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