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01-07-2005 | Review Article

Physiological and Metabolic Aspects of Very Prolonged Exercise with Particular Reference to Hill Walking

Authors: Philip N. Ainslie, Iain T. Campbell, Janet P. Lambert, Donald P. M. MacLaren, Thomas Reilly

Published in: Sports Medicine | Issue 7/2005

Abstract

Hill walking is a popular recreational activity in the developed world, yet it has the potential to impose severe stress simultaneously upon several regulatory systems. Information regarding the physiological strain imposed by prolonged walking outdoors in adverse climatic conditions was reported almost four decades ago and recent research has extended some of this work. These data indicate that once the walker fatigues and starts to slow or stops walking altogether, the rate of heat production falls dramatically. This decrease alone predisposes to the development of hypothermia. These processes, in adverse weather conditions and/or during periods when the level of exertion is low (with low heat production), will be accelerated. Since the majority of walkers pursue this activity in groups, the less fit walkers may be more susceptible to fatigue when exercising at a higher relative intensity compared with their fitter counterparts.

The best physiological offset for hypothermia is to maintain heat production by means of exercise, and so fatigue becomes a critical predisposing factor; it is as important to facilitate heat loss, especially during periods of high exertion, as it is to maintain heat production and preserve insulation. This can be partly achieved by clothing adjustments and consideration of the intensity of exercise. Failure to provide adequate energy intake during hill walking activities has been associated with decreased performance (particularly with respect to balance) and impaired thermoregulation. Such impairments may increase susceptibly to both fatigue and injury whilst pursuing this form of activity outdoors. The prolonged low to moderate intensity of activity experienced during a typical hill walk elicits marked changes in the metabolic and hormonal milieu.

Available data suggest that during hill walking, even during periods of acute negative energy balance, blood glucose concentrations are maintained. The maintenance of blood glucose concentrations seems to reflect the presence of an alternative fuel source, a hormonally induced increase in fat mobilisation. Such enhancement of fat mobilisation should make it easier to maintain blood glucose by decreasing carbohydrate oxidation and promoting gluconeogenesis, thus sparing glucose utilisation by active muscle. During strenuous hill walking, older age walkers may be particularly prone to dehydration and decreased physical and mental performance, when compared with their younger counterparts. In summary, high rates of energy expenditure and hypohydration are likely to be closely linked to the activity. Periods of adverse weather, low energy intake, lowered fitness or increased age, can all increase the participants’ susceptibility to injury, fatigue and hypothermia in the mountainous environment.

Physical activity level is calculated by the 24-hour energy expenditure divided by resting metabolic rate.

Theoretical calculations of the energy supply from the body’s CHO stores in a typical healthy male: the total amount of CHO stored in the muscle, liver and blood is assumed to be 0.4, 0.08 and 0.01kg, respectively. The energy value of 1g CHO is equal to ~15.6kJ. Therefore: 490g of CHO (total CHO store) × 15.6 = 7644kJ. The energy demands of specific exercise are estimated to be 90 kJ/min. The total energy supply from the body’s CHO is: 7644/80 = 84.9 minutes.

Theoretical calculations of the energy supply from the body’s fat stores in a typical healthy male: the total amount of fat stored (from adipose tissue, intramuscular triglyceride, plasma triglyceride and plasma free fatty acids) is assumed to be 12.5kg. The energy value of 1g fat is equal to ~39.4kJ. Therefore: 12500g of fat × 39.4 = 492 500kJ. The energy demands of specific exercise are estimated to be 90 kJ/min. The total energy supply from the body’s fat are: 492 500/90 = 5472 minutes (91 hours).

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Title: Physiological and Metabolic Aspects of Very Prolonged Exercise with Particular Reference to Hill Walking
Authors: Philip N. Ainslie
Iain T. Campbell
Janet P. Lambert
Donald P. M. MacLaren
Thomas Reilly
Publication date: 01-07-2005
Publisher: Springer International Publishing
Published in: Sports Medicine / Issue 7/2005
Print ISSN: 0112-1642
Electronic ISSN: 1179-2035
DOI: https://doi.org/10.2165/00007256-200535070-00006

At a glance: The STEP trials

Springer Medicine

Physiological and Metabolic Aspects of Very Prolonged Exercise with Particular Reference to Hill Walking

Abstract

At a glance: The STEP trials

Springer Medicine

Abstract

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