Substrate utilization in the brain and skeletal muscle during environmental and energetic stress in humans

Department of Nutrition, Exercise and Sports

Research output: Book/Report › Ph.D. thesis › Research

Standard

Substrate utilization in the brain and skeletal muscle during environmental and energetic stress in humans. / Caldwell, Hannah Grace.

Department of Nutrition, Exercise and Sports, Faculty of Science, University of Copenhagen, 2023. 250 p.

Research output: Book/Report › Ph.D. thesis › Research

Harvard

Caldwell, HG 2023, Substrate utilization in the brain and skeletal muscle during environmental and energetic stress in humans. Department of Nutrition, Exercise and Sports, Faculty of Science, University of Copenhagen.

APA

Caldwell, H. G. (2023). Substrate utilization in the brain and skeletal muscle during environmental and energetic stress in humans. Department of Nutrition, Exercise and Sports, Faculty of Science, University of Copenhagen.

Vancouver

Caldwell HG. Substrate utilization in the brain and skeletal muscle during environmental and energetic stress in humans. Department of Nutrition, Exercise and Sports, Faculty of Science, University of Copenhagen, 2023. 250 p.

Author

Caldwell, Hannah Grace. / Substrate utilization in the brain and skeletal muscle during environmental and energetic stress in humans. Department of Nutrition, Exercise and Sports, Faculty of Science, University of Copenhagen, 2023. 250 p.

Bibtex

@phdthesis{f177f24ac91849b3a86b2cc34aa1e727,

title = "Substrate utilization in the brain and skeletal muscle during environmental and energetic stress in humans",

abstract = "Metabolism describes the sum of biochemical reactions that take place within a living organism which provide energy for vital processes; this can be studied at the whole-body, organ specific, or cellular level. Energy availability, which is determined by the difference between energy intake and exercise energy expenditure, is affected by selected environmental and energetic stresses (e.g., high-altitude, exercise, diet/nutrition). Systemic energy deficits have implications for the regulation of organ-specific metabolism. This thesis provides novel insights for integrative brain, skeletal muscle, and systemic substrate oxidation and relative fuel utilization in the context of environmental and energetic stress (e.g., high-altitude, exercise, nutritional caloric deficits). Experiments included: metabolism in the brain in response to CO2; the brain{\textquoteright}s inflammatory response to maximal exercise following 6-8 days of acclimatization at 3,800 m; and a diet intervention in females involving 14-days of effectively 50% caloric restriction while maintaining 8 hours of endurance training per week.",

author = "Caldwell, {Hannah Grace}",

year = "2023",

language = "English",

publisher = "Department of Nutrition, Exercise and Sports, Faculty of Science, University of Copenhagen",

}

RIS

TY - BOOK

T1 - Substrate utilization in the brain and skeletal muscle during environmental and energetic stress in humans

AU - Caldwell, Hannah Grace

PY - 2023

Y1 - 2023

N2 - Metabolism describes the sum of biochemical reactions that take place within a living organism which provide energy for vital processes; this can be studied at the whole-body, organ specific, or cellular level. Energy availability, which is determined by the difference between energy intake and exercise energy expenditure, is affected by selected environmental and energetic stresses (e.g., high-altitude, exercise, diet/nutrition). Systemic energy deficits have implications for the regulation of organ-specific metabolism. This thesis provides novel insights for integrative brain, skeletal muscle, and systemic substrate oxidation and relative fuel utilization in the context of environmental and energetic stress (e.g., high-altitude, exercise, nutritional caloric deficits). Experiments included: metabolism in the brain in response to CO2; the brain’s inflammatory response to maximal exercise following 6-8 days of acclimatization at 3,800 m; and a diet intervention in females involving 14-days of effectively 50% caloric restriction while maintaining 8 hours of endurance training per week.

AB - Metabolism describes the sum of biochemical reactions that take place within a living organism which provide energy for vital processes; this can be studied at the whole-body, organ specific, or cellular level. Energy availability, which is determined by the difference between energy intake and exercise energy expenditure, is affected by selected environmental and energetic stresses (e.g., high-altitude, exercise, diet/nutrition). Systemic energy deficits have implications for the regulation of organ-specific metabolism. This thesis provides novel insights for integrative brain, skeletal muscle, and systemic substrate oxidation and relative fuel utilization in the context of environmental and energetic stress (e.g., high-altitude, exercise, nutritional caloric deficits). Experiments included: metabolism in the brain in response to CO2; the brain’s inflammatory response to maximal exercise following 6-8 days of acclimatization at 3,800 m; and a diet intervention in females involving 14-days of effectively 50% caloric restriction while maintaining 8 hours of endurance training per week.

M3 - Ph.D. thesis

BT - Substrate utilization in the brain and skeletal muscle during environmental and energetic stress in humans

PB - Department of Nutrition, Exercise and Sports, Faculty of Science, University of Copenhagen

ER -

ID: 379646427