Regulation of cerebral blood flow in mammals during chronic hypoxia: a matter of balance

Ainslie, Philip N.; Ogoh, Shigehiko

doi:10.1113/expphysiol.2008.045575

Cited by 136 publications

(157 citation statements)

References 79 publications

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“…An important consideration is that, in addition to blood velocity, changes in diameter of insonated blood vessels could modulate CBF. The middle cerebral artery diameter (the most frequently measured) is nevertheless assumed to remain relatively constant with changes in blood gases and during exercise (4,96), although recent data challenge this assumption in severe hypoxia (118).…”

Section: Cerebral Blood Flowmentioning

confidence: 99%

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Cerebral perturbations during exercise in hypoxia

Vergès

Rupp

Jubeau

et al. 2012

American Journal of Physiology-Regulatory, Integrative and Comp

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Reduction of aerobic exercise performance observed under hypoxic conditions is mainly attributed to altered muscle metabolism due to impaired O 2 delivery. It has been recently proposed that hypoxia-induced cerebral perturbations may also contribute to exercise performance limitation. A significant reduction in cerebral oxygenation during whole body exercise has been reported in hypoxia compared with normoxia, while changes in cerebral perfusion may depend on the brain region, the level of arterial oxygenation and hyperventilation induced alterations in arterial CO 2. With the use of transcranial magnetic stimulation, inconsistent changes in cortical excitability have been reported in hypoxia, whereas a greater impairment in maximal voluntary activation following a fatiguing exercise has been suggested when arterial O 2 content is reduced. Electromyographic recordings during exercise showed an accelerated rise in central motor drive in hypoxia, probably to compensate for greater muscle contractile fatigue. This accelerated development of muscle fatigue in moderate hypoxia may be responsible for increased inhibitory afferent signals to the central nervous system leading to impaired central drive. In severe hypoxia (arterial O 2 saturation Ͻ70 -75%), cerebral hypoxia per se may become an important contributor to impaired performance and reduced motor drive during prolonged exercise. This review examines the effects of acute and chronic reduction in arterial O 2 (and CO2) on cerebral blood flow and cerebral oxygenation, neuronal function, and central drive to the muscles. Direct and indirect influences of arterial deoxygenation on central command are separated. Methodological concerns as well as future research avenues are also considered. cerebral perfusion; cerebral oxygenation; cortex excitability; central motor command; endurance WITH THE EXCEPTION of very short or static exercises performed at a high percentage of maximal power (15,19,83), hypoxia deteriorates exercise performance (7, 82). In particular, the maximal aerobic workload (Ẇ max ) that can be sustained during exercise involving large muscle groups (e.g., cycling) is considerably lower in hypoxia compared with normoxia. The difference between these two environmental conditions increases progressively with the reduction in oxygen inspiratory pressure (PI O 2 ) (36) and is affected by subjects' fitness so that subjects with elevated maximal aerobic capacity are more affected by hypoxia (41).The origin of exercise performance limitation in hypoxia is still under debate, since the consequences of reduced blood O 2 affect the whole organism. This limitation has been attributed to a lowered O 2 partial pressure in arterial blood (Pa O 2 ) reducing arterial O 2 content and O 2 delivery to tissues with critical consequences on muscle metabolism and contraction (1, 46). Magnetic nerve stimulation has confirmed the effects of reduced arterial oxygenation on dynamic (12, 111) and static (54) exercise-induced alterations in muscle contractility. Reduced muscle O...

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Section: Cerebral Blood Flowmentioning

confidence: 99%

“…Hypoxia per se is a cerebral vasodilator that increases CBF (24), at least beyond a certain threshold, i.e., arterial oxygen saturation (Sp O 2 )Ͻ 90% or Pa O 2 Ͻ 40 -45 mmHg (4). Hypoxic exposure at rest is associated with some degree of hyperventilation that results in hypocapnia.…”

Section: Cerebral Blood Flowmentioning

confidence: 99%

Cerebral perturbations during exercise in hypoxia

Vergès

Rupp

Jubeau

et al. 2012

American Journal of Physiology-Regulatory, Integrative and Comp

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“…In response to acute exposure to high altitude, cerebral blood flow (CBF) rises significantly to ensure an adequate supply of O 2 to meet the brain tissues' large and consistent demand [26][27][28]. The mechanisms underlying the regulation of CBF during short-term HAH are complex and depend partly on the degree of hypoxia per se and on the partial pressures of arterial oxygen (PaO 2 ) and arterial carbon dioxide (PaCO 2 ) [29]. Upon ascent to high altitude, a severe drop in PaO 2 (to <40-45 mmHg) induces a cerebral vasodilation, which suggests that altitude-mediated reduced PaO 2 may act as a cerebral vasodilator.…”

Section: Cerebrovascular Systemmentioning

confidence: 99%

“…In addition to these reflex responses, CBF is also regulated by some other hypoxia-induced changes. For example, high-altitude hypoxia-induced changes of cerebral capillary density, hypoxiainduced factor (HIF), nitric oxide, endothelin-1, reactive oxygen species (ROS), and neurotransmitters may be responsible for the falling CBF during long-term HAH [29].…”

Section: Cerebrovascular Systemmentioning

confidence: 99%

Cardiovascular Adaptation to High-Altitude Hypoxia

Ji¹,

Wang²,

Xiao³

2017

Hypoxia and Human Diseases

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High-altitude exposure has been well recognized as a hypoxia exposure that significantly affects cardiovascular function. However, the pathophysiologic adaptation of cardiovascular system to high-altitude hypoxia (HAH) varies remarkably. It may depend on the exposed time and oxygen partial pressure in the altitude place. In short-term HAH, cardiovascular adaptation is mainly characterized by functional alteration, including cardiac functional adjustments, pulmonary vascular constriction, transient pulmonary hypertension, and changes in cerebral blood flow (CBF). These changes may be explained mainly by ventilatory acclimatization and variation of autonomic nervous activity. In long-term HAH, cardiovascular adaptation is mainly characterized by both functional and structural alterations. These changes include right ventricle (RV) hypertrophy, persistent pulmonary hypertension, lower CBF and reduced uteroplacental and fetal volumetric blood flows.

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“…The precise pathogenesis of AMS is not well understood, but hypoxia which affects the regulation of angiogenesis [12] and erythropoietin [13] is likely to be a major factor [14][15][16].…”

Section: Introductionmentioning

confidence: 99%

Circulating miRNAs from Dried Blood Spots are Associated with High Altitude Sickness

Buroker

Ning²,

Zhou³

et al. 2013

J Med Diagn Meth

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Circulating miRNAs isolated from dried blood spots (DBS) were found to be associated with high altitude sickness (HAS) patients in Tibet. HAS arises from two different diseases which are acute (AMS) and chronic (CMS) mountain sickness. Circulating miRNAs differences were found between AMS Han Chinese patients and normal Han controls and between CMS Tibetan Chinese patients and normal Tibetan controls. HAS arises from hypoxia which afflicts some high altitude inhabitants or visitors and not others. The difference results from each individual's genetic makeup where hypoxia related genes have been shown to be a major contributor to these sicknesses. Several fold changes increases (up regulation) were found in the hypoxia associated miRNAs let-7f-5p, miR-9-5p, miR-19a-3p, miR-23a-3p, miR-98-5p, miR-125a-5p, miR-181b-5p, mir-202-3p, miR-372, miR-381-3p, miR-519d, miR-520d-3p, and miR-656 for both HAS groups compared to their controls. Other miRNAs (miR-19a-3p, 302c-3p and 875-3p) were found to be up regulated in one HAS group and down regulated in the other HAS group indicating the genetic differences between the two sickness groups.

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Regulation of cerebral blood flow in mammals during chronic hypoxia: a matter of balance

Cited by 136 publications

References 79 publications

Cerebral perturbations during exercise in hypoxia

Cerebral perturbations during exercise in hypoxia

Cardiovascular Adaptation to High-Altitude Hypoxia

Circulating miRNAs from Dried Blood Spots are Associated with High Altitude Sickness

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