Reduced Hypoxic Ventilatory Response (HVR) and systemic O2 saturation subsequently leading to blunted aerobic capacity as well as decreased overall physical and cognitive performance are the main physiological challenges faced by prematurely born individuals in hypobaric hypoxia (i.e. during high altitude sojourn). While these phenomena have been described previously, the underlying mechanisms are currently unresolved. Given that the reduction in altitude-performance and its underlying mechanisms are not well understood, it is currently impossible to give evidence-based recommendation for altitude sojourns in this cohort. It is also of note, that even hypobaric hypoxia exposure during long-haul flights might be detrimental to well-being of pre-term born individuals. The present project aims to comprehensively investigate physiological responses to altitude/hypoxia during rest and exercise in prematurely born, but otherwise healthy adults. Specifically, the investigators aim to elucidate the underlying mechanisms of the altered resting and exercise cardiovascular, respiratory, cerebral and hematological responses to hypoxia in prematurely born individuals. The obtained results from this cohort will be compared to the data from a control groups consisting of healthy, age and aerobic capacity-matched individuals born at full-term. While acute hypoxic effects will be the focus of the project's first phase, the researchers will test the effect of prolonged terrestrial (real) or simulated (normobaric hypoxia) altitude exposures in the second part. This phase will, in addition to the insight into the prolonged altitude acclimatization modulation in prematurely born individuals, also enable the potential differences between the effects of normobaric (simulated) and hypobaric (terrestrial) hypoxia in this cohort to be investigated.
Study Type
OBSERVATIONAL
Enrollment
36
48 hours experimental protocol conducted at sea level
24 hours experimental protocol conducted in a normobaric hypoxic facility
72 hours experimental protocol conducted at terrestrial altitude
Jozef Stefan Institute
Ljubljana, Slovenia
University of Ljubljana
Ljubljana, Slovenia
Institute of Sport Sciences of the University of Lausanne
Lausanne, Canton of Vaud, Switzerland
Cerebrovascular reactivity to carbon dioxide (CO2)
Subjects will breath 4 min 3% CO2 and 4 min 6% CO2 separated by 4 min of breathing ambient air. Gas exchange, blood flow in the middle cerebral artery and peripheral oxygen saturation will be continuously recorded by metabolic cart, transcranial doppler, and finger pulse oximeter, respectively.
Time frame: 48 hours after exposure to normoxia and hypobaric hypoxia, respectively.
Cognitive function
Cognitive function will be assessed by a computerized psychometric test battery previously used by our research group. These will assess working memory and visuo-motor coordination.
Time frame: 24 hours after exposure to normoxia, hypobaric hypoxia, and normobaric hypoxia, respectively
Acute Mountain Sickness (AMS)
AMS will be assessed by Lake Louise scale. AMS will be diagnosed if the Lake Louise score is 3 or higher.
Time frame: 8 hours (prior to sleep) and 16 hours (upon waking) after exposure to hypobaric and normobaric hypoxia
Change in respiratory function
Respiratory function will be assessed by spirometry.
Time frame: Immediately after exposure to hypobaric and normobaric hypoxia, relative to baseline.
Lung comets
Lung comets will be assessed by counting the number of B-lines present, which will be measured using Doppler ultrasound.
Time frame: Every day before and immediately after each exercise bout.
Heart rate response to exercise
Heart rate (HR, bpm) will be continuously monitored during different exercise bouts of variety intensities (moderate and heavy intensities will be used).
Time frame: Every day before exercise, during exercise and at the instant of volitional exhaustion.
Respiratory response to exercise
Oxygen consumption (VO2, L/min and mL/min/kg) will be continuously monitored during different exercise bouts of variety intensities (moderate and heavy intensities will be used).
Time frame: Every day before exercise, during exercise and at the instant of volitional exhaustion.
Changes in muscular oxygenation during exercise
Muscle oxygenation/deoxygenation will be continuously recorded during each exercise bout by Near Infra-Red Spectroscopy (NIRS) placed on the vastus lateralis. NIRS measure the quantity of oxygenated and deoxygenated haemoglobin and myoglobin (microM) in the investigated areas (vastus lateralis).
Time frame: Every day before exercise, during exercise and at the instant of volitional exhaustion.
Changes in cerebral oxygenation during exercise
Brain oxygenation/deoxygenation will be continuously recorded during each exercise bout by Near Infra-Red Spectroscopy (NIRS) placed at the frontal levels. NIRS measure the quantity of oxygenated and deoxygenated haemoglobin (microM) in the investigated areas (prefrontal cortex).
Time frame: Every day before exercise, during exercise and at the instant of volitional exhaustion.
Changes in the rate of muscular oxygen consumption (mV̇O2)
Muscle oxygen consumption will be assessed using a previously validated protocol. Briefly, a Near Infra-Red Spectroscopy (NIRS) optode will be placed on the vastus lateralis muscle. Before the protocol, an ischemic calibration will be performed to normalize the NIRS signals by inflating the blood pressure cuff to 250-300 mmHg for a maximum of 5 min. Resting mV̇O2 will be assessed from the decrease in muscle oxygenation which accompanies the arterial occlusion. Four resting measurements will be performed using 10 sec of arterial occlusion. Then, each subject will perform a voluntary knee extension exercise for 15 sec. To measure the recovery of oxygen consumption after exercise, subject will have a series of arterial occlusion as follows: 5 occlusions 5sec on-5sec off, 5 occlusions 5sec on-5sec off, and 8 occlusions 10 sec on-20 sec off.
Time frame: Before each exercise bouts.
Acute change in sleep quality
Polysomnography will be used to assess sleep quality. Measurements will include electroencephalography (EEG), electrooculography (EOG), chin and tibial surface electromyography (EMG), electrocardiography (ECG), nasal pressure (nasal pressure cannula), respiratory movements (chest and abdominal belts) as well as capillary oxygenated haemoglobin saturation measurement.
Time frame: On the first night in normoxia, normobaric hypoxia and hypobaric hypoxia.
Change in sleep quality after prolonged exposure to hypobaric hypoxia
Polysomnography will be used to assess sleep quality. Measurements will include electroencephalography (EEG), electrooculography (EOG), chin and tibial surface electromyography (EMG), electrocardiography (ECG), nasal pressure (nasal pressure cannula), respiratory movements (chest and abdominal belts) as well as capillary oxygenated haemoglobin saturation measurement.
Time frame: On the third night after exposure to terrestrial altitude.
Changes in endothelial capacity to flow-mediated dilation (FMD)
A pneumatic cuff is positioned distal to the ultrasound probe in order to avoid ischemia of the artery studied. Radial artery diameter is measured at rest, during inflation of the distal cuff to suprasystolic pressure (5 min) and for the 5 min following deflation. The subsequent decrease in local blood flow in response to ischemia causes a progressive decrease in the radial artery diameter until a plateau (L-FMC). Upon cuff deflation, the increased blood flow causes radial artery dilatation. L-FMC is calculated as the percentage decrease in arterial diameter in the last 30 s of cuff occlusion as compared with resting diameter. FMD is calculated as the maximum percentage increase in arterial diameter following cuff deflation.
Time frame: 24 hours after exposure to normoxia and hypobaric hypoxia.
Changes in orthostatic tolerance
Orthostatic tolerance will be assessed by measuring heart rate variability. This will involve an app-validated 10-min protocol, which will use a chest-band to monitor heart rate changes from 5 minutes of supine position followed by 5 minutes of standing.
Time frame: At 6am on every trial day (upon waking).
Changes in oxidative stress markers in the blood
Oxidative stress markers concentration will be measured on collected venous blood sample.
Time frame: Blood samples will be collected at 6am (upon waking).
Change in salivary cortisol concentration
Cortisol concentration will be measured on collected saliva samples.
Time frame: Saliva samples will be collected at 6am (upon waking).
Change in hydration status
Urine samples will be assessed using urine specific gravity.
Time frame: Urine samples will be collected at 6am (upon waking).
Change in cerebral blood flow in the internal carotid artery
Cerebral blood flow in the internal will be assessed every morning by doppler ultrasound.
Time frame: Cerebral blood flow will be measured at 10am.
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