Intermittent Exogenous Ketosis (IEK) at High Altitude

Summary

Altitude-related hypoxia decreases human functional capacity, especially during exercise. Even with prolonged acclimatization, the physiological adaptations are insufficient to preserve exercise capacity, especially at higher altitudes completely. Consequently, there has been an ongoing search for various interventions to mitigate the negative effects of hypoxia on human performance and functional capacity. Interestingly, early data in rodents and humans indicate that intermittent exogenous ketosis (IEK) by ketone ester intake improves hypoxic tolerance, i.e.by facilitating muscular and neuronal energy homeostasis and reducing oxidative stress. Furthermore, there is evidence to indicate that hypoxia elevates the contribution of ketone bodies to adenosine-triphosphate (ATP) generation, substituting glucose and becoming a priority fuel for the brain. Nevertheless, it is reasonable to postulate that ketone bodies might also facilitate long-term acclimation to hypoxia by upregulation of both hypoxia-inducible factor-1α and stimulation of erythropoietin production.

The present project aims to comprehensively investigate the effects of intermittent exogenous ketosis on physiological, cognitive, and functional responses to acute and sub-acute exposure to altitude/hypoxia during rest, exercise, and sleep in healthy adults. Specifically, we aim to elucidate 1) the effects of acute exogenous ketosis during submaximal and maximal intensity exercise in hypoxia, 2) the effects of exogenous ketosis on sleep architecture and quality in hypoxia, and 3) the effects of exogenous ketosis on hypoxic tolerance and sub-acute high-altitude adaptation. For this purpose, a placebo-controlled clinical trial (CT) in hypobaric hypoxia (real high altitude) corresponding to 3375 m a.s.l. (Rifugio Torino, Courmayeur, Italy) will be performed with healthy individuals to investigate both the functional effects of the tested interventions and elucidate the exact physiological, cellular, and molecular mechanisms involved in acute and chronic adaptation to hypoxia. The generated output will not only provide novel insight into the role of ketone bodies under hypoxic conditions but will also be of applied value for mountaineers and athletes competing at altitude as well as for multiple clinical diseases associated with hypoxia.

Conditions

• Ketosis
• Hypoxia

Interventions

DIETARY_SUPPLEMENT

Ketone ester

Ketone ester: A total of 300g ketone ester supplementation will be provided in one of the 72h experimental sessions in order to establish intermittent exogenous ketosis. Sucralose (5% w/w) is added to the ketone ester (R)-3-hydroxybutyl (R)-3-hydroxybutyrate Hypobaric hypoxia: 72 hours experimental protocol conducted at terrestrial altitude

DIETARY_SUPPLEMENT

Placebo

Placebo: Water, 5% sucralose (w/w), octaacetate (1 mM) Hypobaric hypoxia: 72 hours experimental protocol conducted at terrestrial altitude

Sponsors & Collaborators

• KU Leuven

  collaborator OTHER

• University of Lausanne

  collaborator OTHER

• Jozef Stefan Institute

  lead OTHER

Study Design

Allocation

RANDOMIZED

Purpose

PREVENTION

Masking

DOUBLE

Model

PARALLEL

Eligibility

Min Age

18 Years

Max Age

35 Years

Sex

ALL

Healthy Volunteers

Yes

Timeline & Regulatory

Start

2023-09-18

Primary Completion

2023-10-30

Completion

2024-06-30

Countries

• Belgium
• Slovenia

Study Locations