Hypoxia, Altitude Clinical Trial
Official title:
The Effect of Cocoa Flavanol Intake on Cerebral and Muscle Perfusion and Oxygenation in Hypoxia - Implications for Cognitive and Exercise Performance
Verified date | May 2017 |
Source | Vrije Universiteit Brussel |
Contact | n/a |
Is FDA regulated | No |
Health authority | |
Study type | Interventional |
Not uncommonly, sports events take place or finish at high altitude, where physical and
cognitive (e.g. decision-making, motor control) performance in hypoxia is determining the
outcome of sports performance. With nutritional supplements growing in popularity in the
athletic and non-athletic population, research is increasingly focussing on dietary
constituents which can improve cognitive and exercise performance.
Flavonoids, a subgroup of polyphenols, are a class of natural compounds found in the human
diet and include subcategories of flavanols, flavonols, iso-flavones, flavones, and
anthocyanidins. Intake of flavanols, found in grapes, tea, red wine, apples and especially
cocoa, causes an nitric oxide (NO)-mediated vasodilatation and can improve peripheral and
cerebral blood flow (CBF).
For cocoa flavanol (CF), there is evidence that both long term and acute intake can improve
cognitive function, with the quantity and bioavailability of the consumed CF highly
influencing its beneficial effects and with higher doses eliciting greater effects on
cognition. Increased CBF following acute and chronic (3 months) CF intake has been
demonstrated in healthy young subjects. Moreover, cognitive performance and mood during
sustained mental efforts are improved after acute CF intake in healthy subjects and CF
intake can increase prefrontal oxygenation during cognitive tasks in well-trained athletes.
Moreover, CF intake is not only associated with an improved blood flow, but it might also
improve exercise performance following 2 weeks of dark chocolate intake. On top of that, CF
is known to have anti-oxidant properties and 2 week CF intake has been associated with
reduced oxidative-stress markers following exercise.
In hypoxic conditions, arterial pressure of oxygen (PaO2) and arterial saturation of O2
(SaO2) are decreased, compromising tissue oxygen delivery. Since brain function and brain
integrity are dependent on continuous oxygen supply, brain desaturation may result in an
impaired cognitive function in hypoxia. The severity of the impairment is related to the
extent of high altitude, with at 3000m (=14.3 % oxygen (O2); = 71% of oxygen available at
sea level) psychomotor impairments being visible. Cerebral oxygenation, which can be
measured by Near-infrared spectroscopy, is lowered in hypoxia.
It remains unclear whether CF intake can influence cerebral oxygenation and perfusion in
hypoxic conditions and whether CF intake could (partially) counteract hypoxia-induced
cognitive impairments. Therefore, the first aim of this study was to investigate whether
cognitive function and prefrontal oxygenation during a mental demanding task will be
impaired by hypoxic conditions (3000m altitude; 14.3% O2) and whether these impairments can
be partially restored by subchronic CF intake (7 days, 900 mg/day).
Hypoxia also impairs physical performance. Hypoxia-induced reductions in cerebral
oxygenation may favour central fatigue, i.e. the failure of the central nervous system to
excite the motoneurons adequately, hence impairing exercise performance in hypoxic
conditions. Since hypoxia also impairs oxygen delivery to muscle tissue, the decreased
oxygen supply to and impaired oxidative energy production in the exercising muscle is a
second factor negatively affecting exercise performance.
Besides the aforementioned effects of altitude on O2 delivery, hypoxia also results in
increased oxidative stress. Oxidative stress refers to the imbalance between prooxidant and
antioxidant levels in favor of prooxidants in cells and tissues and can result from
diminished antioxidant levels or increased production of reactive oxygen species. The latter
can be induced by both exhaustive exercise and high altitude. Since oxidative stress can be
counteracted by CF, we also aim to investigate how markers of oxidative stress can be
affected by CF intake by exercise in hypoxia. Therefore, the second aim of this study was to
investigate possible beneficial effects of CF intake on changes in cerebral and muscle
vasoreactivity and oxidative stress during exercise in hypoxia and its implications on
exercise performance.
Status | Completed |
Enrollment | 15 |
Est. completion date | July 30, 2016 |
Est. primary completion date | July 30, 2016 |
Accepts healthy volunteers | Accepts Healthy Volunteers |
Gender | Male |
Age group | 18 Years to 36 Years |
Eligibility |
Inclusion Criteria: - train more than 10 hours/week Exclusion Criteria: - severe head injuries in the past - hypertensive - with cardiovascular disease / take medication for cardiovascular disease - smokers - take nutritional supplements - had stayed at high altitude (>3000m) for 3 weeks during the last 6 months |
Country | Name | City | State |
---|---|---|---|
n/a |
Lead Sponsor | Collaborator |
---|---|
Vrije Universiteit Brussel |
Type | Measure | Description | Time frame | Safety issue |
---|---|---|---|---|
Primary | prefrontal/muscular oxygenation | change from baseline (pre-exercise) at post-exercise after 7 days of intake | ||
Primary | work (kj) performed during 20 minute time trial | after 7 days of intake | ||
Secondary | Flow mediated dilation | after 6 days of intake | ||
Secondary | oxidative stress | change from baseline (pre-exercise) at post-exercise after 7 days of intake |
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