Hypoxia Clinical Trial
Official title:
Planetary Habitat Simulation: An Investigation Into the Effects of Hypoxia and / or Bedrest on Fuel Metabolism and Appetite (WP5)
A loss of body weight has been documented in lowland-living individuals when exposed to hypoxic environments, such as at high altitude, or under laboratory conditions. A reduction in appetite and energy intake has also been reported during conditions of microgravity, such as during space flight. Fourteen normal or over-weight men, who are otherwise healthy, will undergo 3x 21-day interventions; normobaric normoxic bed rest (NBR; FiO2=21%), normobaric hypoxic ambulatory confinement (HAMB; FiO2=14%; ~4000 m simulated altitude), and normobaric hypoxic bed rest (HBR; FiO2=14%). The effects of hypoxia and bedrest on appetite and its hormonal control will be assessed before and at day 17 of each intervention using a mixed meal tolerance test.
A loss of body weight has been documented in lowland-living individuals when exposed to
hypoxic environments, such as at high altitudes, or under laboratory conditions. This weight
loss has been attributed both to a reduced appetite (and subsequent fall in dietary energy
intake), and to an increase in resting energy expenditure. Interestingly, a reduction in
appetite and energy intake has also been reported during space flight, although the mechanism
for this has not been explained. As the gas inside future planetary habitats is likely to
have lower partial pressure of oxygen than in Earth's atmospheric air, hypoxia induced
appetite reduction could pose a challenge for individuals in these environments. For example,
persistent under-eating could compromise long term health due to inadequate intake of
essential micronutrients, especially in the presence of altered nutrient metabolism and
requirements seen during space flight. Moreover, inadequate macronutrient intake could
exacerbate the loss of lean body tissue which occurs in situations (such as microgravity,
inactivity and bed rest) where muscles are unloaded. Indeed, a protein intake greater than
normal could be required in situations where there is muscle inactivity, to achieve the same
postprandial anabolic effect of amino acids seen in ambulatory individuals.
The mechanism for the reduction in appetite observed in hypoxia is not well established.
Several incretin hormones and adipokines have been implicated in the control of appetite and
may be candidates for inducing this alteration in appetite observed in hypoxia. However,
reports in the literature present contradictory findings, perhaps due to the use of different
experimental paradigms (hypobaric and normobaric hypoxia, active and resting subjects,
variability in the degree and duration of hypoxia).
The protocol of the current study standardises physical activity, ambient temperature,
hypoxic stimulus and nutritional composition of the diet, and aims to extend our knowledge of
the effects of hypoxia and bedrest on appetite and its hormonal control.
In order to discern the separate and combined effects of microgravity and hypoxia, fourteen
normal or over-weight men, who are otherwise healthy, will be recruited following medical and
psychological screening. They will be invited to attend the Olympic Sport Centre, Planica,
Slovenia on 3 occasions, with each visit being 31 days in duration and separated by 5 months.
Each 31-day visit ('campaign') includes a baseline recording period (5 days), 21 days of
intervention and a recovery period (5 days), with the 3 interventions allocated in a
randomized, cross over design: i) Normobaric normoxic bed rest (NBR; FiO2=21%), ii)
Normobaric hypoxic ambulatory confinement (HAMB; FiO2=14%; ~4000 m simulated altitude), and
iii) Normobaric hypoxic bed rest (HBR; FiO2=14%). A standardized, repeating, 14-day dietary
menu, comprised of foods commonly consumed in the Slovenian diet, will be applied during all
campaigns, the targeted energy intakes being calculated individually using a modified
Benedict-Harris formula with physical activity factor multipliers of 1.2 for the HBR and NBR
campaigns and 1.4 for the HAMB campaign. Food will be provided in weighed portions and
subjects will be encouraged to eat all food supplied. However, any food not eaten will be
weighed and actual amount consumed recorded in a diet analysis programme. Body mass will be
assessed daily during the campaigns using a gurney incorporating load cells, and whole body
composition will be determined before and immediately after each intervention using fan beam
dual-emission X-ray absorptiometry.
Participants will undergo a mixed meal tolerance test before and on day 17 of each
intervention period, in the morning, after a 12 hour fast, with the time of assessment
replicated on each study day at every campaign. On arrival, participants will rest supine on
a hospital bed and place their hand in a heated hand warming unit (air temperature 50-55oC).
An intravenous cannula will then be inserted retrograde into a dorsal hand vein for
arterialised-venous blood sampling. After 15mins rest, a baseline, fasting blood sample will
be taken for determination of serum insulin, total cholesterol, high density lipoprotein
(HDL) cholesterol, low density lipoprotein (LDL) cholesterol, adiponectin and leptin, whole
blood glucose and lactate, and plasma catecholamines, ghrelin, PeptideYY (PYY), glucagon-like
peptide-1(GLP-1), triglycerides, and non-esterified fatty acid concentration. An expired
breath sample will be collected into evacuated tubes for 13 labelled carbon dioxide (13CO2)
determination, and a 20min baseline measurement of resting energy expenditure (REE) and
respiratory exchange ratio (RER) will be then made using indirect calorimetry, with subjects
wearing a mask, and both inspired and expired air being measured on every breath. Appetite
assessment will be made by asking subjects to rate their hunger, desire to eat, fullness, and
their prospective food intake, by placing a vertical mark on a 0-100mm linear scale. This
visual analogue scale will be measured from left to right, with 0 indicating no experience of
the variable (e.g. not hungry, unable to eat anything) and 100 indicating the most of each
variable that they can imagine experiencing (e.g. intense desire to eat, or completely full).
Values for these 4 variables will be combined to calculate a combined appetite score (CAS).
Once baseline measurements have been completed, subjects will consume a mixed nutrient
milkshake (Ensure Plus, Abbott Nutrition) at 5ml/kg body weight, which will be supplemented
(at 1% of carbohydrate content) with 13-Carbon labelled (13C) Glucose. Arterialised venous
blood samples will subsequently be taken every 10min for glucose and lactate assessment, and
every 20min for assessment of serum insulin and incretin hormones. A measurement of REE and
RER will be performed in the last 15min of every 30min period for the following 2 hours to
assess fuel oxidation and metabolic rate, and an expired breath sample will be collected into
evacuated tubes for 13CO2 determination at a later date. Subjective appetite will be assessed
every 15minutes throughout using visual analogue scales, as described above, and at the end
of the 2hr postprandial period subjects will be given an ad libitum pasta-based test meal and
will be instructed to eat until they feel comfortably full. This meal will be comprised of
cooked dried white pasta, commercially available tomato-based pasta sauce, olive oil and
grated hard cheese, with a composition of 37% of total energy derived from fat, 48%
carbohydrate, and 16% protein. The amount eaten will be recorded and related to subjective
appetite ratings.
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