Abstract
The first aim of this dissertation was to monitor both rat and
human responses to short-term perturbations in energy balance
brought about through food energy restriction and refeeding,
exercise training and the cessation of exercise training or
surgical lipectomy. The second aim of this dissertation was
to identify factors which might explain differences in food
energy intake in weight-matched, weight-stable "large and
small eaters". The final aim of this dissertation was to
identify factors which might explain differences in resting
energy expenditure in a large sample of weight-stable men and
women, including exercising and non-exercising persons, and
including persons who may be regarded as "restrained eaters".
In the first study, Long-Evans rats underwent pre-weaning
litter size manipulation and were exposed to either a standard
chow diet or a diet comparatively high in fat during the
initial 18 weeks following weaning. Additionally, some of
the rats were housed as pairs, and others were housed singly
during the post-weaning period. Metabolic efficiency was
quantified by calculating feeding efficiency, changes in body
size, and body fat accretion. In this study, there was no
persistent effect of pre-weaning nutrition on post-weaning
growth and feeding efficiency.
In the second study of this dissertation, Long-Evans rats,
which were habituated to spontaneous running activity in
specially designed wheel cages trained for 8 weeks, after
which randomly-selected rats were placed in ordinary cages
without wheels for 2 weeks. The metabolic responses to shortterm
detraining were quantified by measuring feeding
efficiency, body mass, body fat accretion, and changes in
adipose tissue lipogenic enzyme activity in trained, detrained
and untrained rats. Rats which had stopped training
demonstrated an increased feeding effiency, a two- to threefold
increase in adipose tissue lipogenic activity, and
increased fat cell size and fat pad mass, when compared to
trained or sedentary counterparts.
The metabolic responses to stopping training were studied
further in human athletes. Resting and glucose-stimulated
Lambert, E (2021). Factors Affecting Energy Expenditure And The Efficiency Of Fuel Utilization: Feeding And Exercise Models. Afribary. Retrieved from https://afribary.com/works/factors-affecting-energy-expenditure-and-the-efficiency-of-fuel-utilization-feeding-and-exercise-models
Lambert, Estelle "Factors Affecting Energy Expenditure And The Efficiency Of Fuel Utilization: Feeding And Exercise Models" Afribary. Afribary, 15 May. 2021, https://afribary.com/works/factors-affecting-energy-expenditure-and-the-efficiency-of-fuel-utilization-feeding-and-exercise-models. Accessed 25 Nov. 2024.
Lambert, Estelle . "Factors Affecting Energy Expenditure And The Efficiency Of Fuel Utilization: Feeding And Exercise Models". Afribary, Afribary, 15 May. 2021. Web. 25 Nov. 2024. < https://afribary.com/works/factors-affecting-energy-expenditure-and-the-efficiency-of-fuel-utilization-feeding-and-exercise-models >.
Lambert, Estelle . "Factors Affecting Energy Expenditure And The Efficiency Of Fuel Utilization: Feeding And Exercise Models" Afribary (2021). Accessed November 25, 2024. https://afribary.com/works/factors-affecting-energy-expenditure-and-the-efficiency-of-fuel-utilization-feeding-and-exercise-models