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Nutrition and Physical Activity Topic 37
Module 37.3
Nutrition for Endurance and Strength Sports
Nada Rotovnik Kozjek, MD, PhD
anaesthesiologist
Institute of Oncology, Ljubljana, 1000, Slovenia
Slovenian Olympic Committee, Ljubljana, 1000, Slovenia
Anja Carlsohn, PhD
professor for nutrition and home economics
University of Applied Sciences Hamburg, Germany
Peter Soeters, MD, PhD
emeritus professor of surgery
Maastricht University Medical Center, Maastricht,
6200, The Netherlands
Learning Objectives
To present basic terminology in sports clinical nutrition;
To understand that the key goal of training is to enable the body to develop metabolic
efficiency and flexibility, while specific nutritional strategies for competition are aimed
at providing adequate substrates to support energy demands and cognitive function;
To understand that nutritional goals for active adults and competitive athletes are not
static and they require a complex knowledge of sports physiology, metabolism and
nutrition to create a nutritional strategy for training and competition;
To understand how to apply existing sports nutritional recommendations for planning
specific nutritional strategies in sports nutrition;
To understand negative clinical and performance effects of Relative Energy Deficiency
Syndrome (RED-S).
Contents
1. Introduction
2. Terminology and basic considerations in sports clinical nutrition
2.1. Terminology
2.2. Aerobic and anaerobic (non-oxidative) metabolism
2.3. Physique and energy demands of different athletes
2.4. Periodization of nutritional strategy
3. Nutritional support in sports
3.1. Energy requirements
3.2. Nutrient intake recommendations
3.2.1. Carbohydrate intake
3.2.2. Protein intake
3.2.3. Fat intake
3.3. Nutritional strategies to optimize recovery
4. Clinical issues concerning the nutrition of athletes
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4.1. Weight management, female athlete triad and eating disorders
4.2. Gastrointestinal distress
4.3. Iron deficiency and iron deficiency anaemia
5. Summary
6. References
Key Messages
• Exercise is a major challenge to whole-body homeostasis;
• Physiological and metabolic responses to exercise are similar to the general stress
response and provoke widespread perturbations in numerous cells, tissues, and
organs, as a response to the increased metabolic activity of contracting skeletal
muscles;
• To meet the exercise challenge, multiple integrated and often otherwise redundant
responses operate to diminish the homeostatic stress;
• The metabolic response to exercise is dictated by energy demand and duration of
physical activity and substantially influences the ability to produce muscle power;
• The intake of energy and macronutrients must be personalized according to athletes’
training plans as well as to individual responses to specific training stimuli and
characteristics;
• Ensuring strategic energy and nutrient availability at critical training points is not only
important for optimal training, regeneration and competitive performance but also for
immune system protection, and prevention of injuries, overreaching and overtraining;
• Energy availability, which considers energy intake in relation to the energy cost of
exercise, sets an important foundation for health and success of sports nutrition
strategy.
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1. Introduction
Nutritional strategies for active adults and competitive athletes are based on scientific
findings regarding the underlying mechanisms of various physiological phenomena induced
by exercise, including the recovery process. Optimal interaction of diet and exercise
provides a powerful tool to enhance metabolic health and sports performance.
The metabolic demands of exercise are dictated by the energy demands and the duration
of physical activity as well as by numerous issues relating to the speed, force, duration,
and intensity of muscle contractions. In addition, the total muscle mass engaged in the
activity must also be considered for a complete understanding of the physiological
responses to exercise. The resulting metabolic demands have to be met within a limited
disruption of homeostasis.
In recent years, knowledge in the field of sports sciences has grown immensely and created
a vibrant environment of applied research in sports nutrition. The integration of scientific
findings with the insights from the field of applied nutrition on how to cover individual
metabolic needs of exercise has led to an increasingly sophisticated practice of sports
nutrition. The times of recommending a “sports diet” or using fixed amounts of nutrients
in any sports or exercise activities are over. Nutritional support should be adjusted to the
specific demands of every athlete. The strategically adjusted consumption of key nutrients,
depending on the specific needs of an individual, aims at enhancing athletic performance
and regeneration, thus allowing an athlete to reach his or her full genetic potential and
benefit from physical activities which vary in duration and intensity (1).
Currently, an appropriate strategy for nutritional support is based on evidence provided by
general scientific recommendations and then applied to various forms of endurance and
dynamic voluntary exercise as well as to specific forms of power and strength sports.
Therefore, the guidelines for clinical sports nutrition represent various general
recommendations for energy intake, amounts and composition of nutrients and fluid
intake, and also specific recommendations for the type of sport and/or exercise activity
and for different phases in the training process (Fig. 1).
However, the most important part of sports nutrition is to enable an athlete to turn his or
her nutritional goals into practical use of foods, fluids, and sport nutrition supplements. As
the dietary intake of food has immediate as well as long-term effects on the athlete’s well-
being, health, and athletic performance, the nutritional strategy should be tailored also in
accordance with other factors that could potentially influence food choices and composition.
These issues are influenced by the athletes’ lifestyle, food preferences, personality and
their social and cultural circumstances. In addition, the culture of a specific sport,
interactions between athletes and opinions of coaches and trainers may influence
nutritional beliefs and attitudes towards food. Therefore, the content and the way of
delivering sports nutritional education must be tailored to individual athletes but in the
context of their specific group.
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Fig. 1 Personalized sports nutritional strategy
2. Terminology and Basic Considerations in Sports Clinical
Nutrition
2.1 Terminology
The term exercise is defined as any activity involving force and power production by
voluntary coordinated activation of the appropriate skeletal muscles (2). However,
voluntary exercise is more than just an orchestrated assembly of muscle contractions;
whole-body, voluntary exercise induces a range of additional physiological responses that
are critical for muscle performance enhancement and development of movement skills.
Importantly, many effects observed in animals and isolated systems frequently differ from
those seen in humans in vivo, so care should be taken when extrapolating responses from
one set of conditions or a given experimental model to another (3).
Endurance exercise represents a spectrum of rhythmic exercises like walking, running,
cycling, swimming, triathlon, skiing, and others. Within these sports, there are different
disciplines. During sustained rhythmic exercise like cycling or running, the contraction
times are short, there is little disruption of muscle blood flow and minimal perturbations in
blood pressure (BP).
Intense exercise events that require high power outputs of relatively shorter duration for
success are considered as power sports (4). Typical power sports are medium-distance
running, track cycling, Olympic rowing, canoeing/kayaking, and swimming (4). An
isometric or static contractions of high force but short duration may compress blood vessels
within the contracting musculature and limit blood flow and oxygen delivery to those
muscles while simultaneously increasing BP.
Power is defined as the amount of work performed per unit of time (2). It reflects the
ability to exert maximum muscular contraction instantly or in an explosive burst of
movements. The two components of power are strength and speed (e.g. jumping or a
sprint start). From the energetic, and also nutritional, point of view, it is important to
understand that power is the rate at which work can be performed or the rate of the
transformation of metabolic potential energy to work and/or heat.
Power in sport can be determined for a single body movement, a series of movements, or
a large number of repetitive movements. It can be determined instantaneously at any point
in a movement, or averaged for any portion of a movement or bout of exercise (3). In
complex human motions, the maximum output of mechanical power is reached with
approximately 50% of the maximum force and velocity of a given athlete (5).
Optimal power output demands effective muscle coordination and mechanical efficiency of
limb movement, meaning that optimal sports performance requires the consideration of
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