PHYSIOLOGICAL BASICS FOR ATHLETIC TRAINING Olavi Pajala
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Transcript of PHYSIOLOGICAL BASICS FOR ATHLETIC TRAINING Olavi Pajala
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PHYSIOLOGICAL BASICS FOR ATHLETIC TRAINING
Olavi Pajala
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C H A P T E R 12
TRAINING FOR SPORT
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Did You Know…?
A person’s rate of adaptation and response to training depends on that individual. He or she cannot be forced beyond his or her body’s capacity for development. Thus, training programs must take these individual differences into account.
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OPTIMIZING TRAINING—A MODEL
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PERIODIZED TRAINING, MACROCYCLE
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PERIODIZED TRAINING, MESOCYCLE
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PERIODIZED TRAINING, MICROCYCLE
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Optimal Training Load
Progressive overload—progressive increase in training load as body adapts
Training volume—duration and frequency
Training intensity—force of muscle action and stress on the muscular and cardiovascular systems
Resistance training (high intensity and low volume)
Aerobic training (high volume and lower intensity)
Rest periods—without them, muscles become chronically fatigued and depleted of stored energy
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EXCESSIVE TRAINING—BLOOD LACTATE AND HR
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TRAINING VOLUME vs IMPROVEMENT
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Key Points
Excessive training refers to training with an unnecessarily high volume or intensity.
Excessive training does not lead to additional gains in performance and can lead to chronic fatigue and decreased performance.
Training Demands
Increase the duration or frequency of training to increase training volume.
(continued)
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Key Points
Training Demands
Training intensity can determine specific adaptations to training.
High-intensity, low-volume training increases muscle strength and speed.
High-volume, low-intensity training (50% to 90% VO2max) increases aerobic capacity.
.
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Did You Know…?
Long daily workouts may not be the best training method for some sports. It appears that training volume could be reduced by as much as one half in some sports, without reducing the training benefits and with less risk of overtraining the athlete to the point of decreased performance.
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Effects of Training Too Much
Excessive training—well above what is needed for peak performance, but does not strictly meet the criteria for overreaching or overtraining. It can lead to chronic fatigue and decrements in performance.
Overreaching—a brief period of heavy overload without adequate recovery, thus exceeding the athlete’s adaptive capacity. There is a performance decrement, but it is relatively short-term, lasting several days to several weeks
Overtraining—that point at which an athlete starts to experience physiological maladaptations and chronic performance decrements, lasting weeks, months or longer.
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Overtraining
Continued training beyond the point that would be optimal; can be related to intensity, duration, frequency, or any combination of these three
Staleness is a related concept
The key is to design a training program that provides the optimal level of stress but does not overstress the athlete
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Symptoms of Overtraining Syndrome
Decline in physical performance with continued training
Loss in muscular strength, coordination, and maximal working capacity
General fatigue
Change in appetite and body weight loss
Sleep disturbances
Irritable, restless, excitable, anxious
Loss of motivation
Lack of mental concentration
Feelings of depression
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OVERREACHING vs OVERTRAINING
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Possible Causes of Overtraining
Periods of excessive training and/or emotional stress
Abnormal responses in the autonomic nervous system—sympathetic and parasympathetic
Disturbances in endocrine function
Depressed immune function
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HORMONAL RESPONSES TO OVERTRAINING
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HYPOTHALAMUS, SAM, and HPA WITH OVERTRAINING
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BRAIN-IMMUNE SYSTEM INTERACTIONS
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EXERCISE AND IMMUNE FUNCTION
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Predicting Overtraining
Increase in oxygen consumption for the same rate of work (though impractical for coach to measure)
Increased heart rate response to the same rate of work
Declines in performance
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VO2 IN EARLY AND LATE SEASON.
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HEART RATE RESPONSES TO TRAINING
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Treatment of Overtraining
Reduce training intensity for several days
Rest completely for several days or weeks if symptoms don’t improve
Seek counseling
Prevent overtraining by alternating easy, moderate, and hard training
Eat sufficient carbohydrate to prevent glycogen depletion
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Key Points
Overreaching and overtraining lead to decreased performance capacity.
Symptoms of overreaching or overtraining may occur briefly with regular training.
Overreaching and Overtraining
Overtraining may be caused by abnormal responses in the autonomic nervous and endocrine systems and suppressed immune function.
Heart rate response appears to be the most reliable warning of overtraining.
Overtraining syndrome is treated most effectively with rest and proper nutrition.
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Did You Know…?
Tapering for competition involves a reduction in training intensity and volume. This rest allows your body to repair itself and restore its energy reserves to prepare you for your best performance.
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Effects of Properly Tapering
Muscular strength increases
Energy reserves are restored
Performance increases
No loss of VO2max occurs.
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EFFECTS OF A 7-DAY TAPER IN RUNNERS
a b
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TAPERING AND VO2SUBMAX.
c
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Detraining
Partial or complete loss of training-induced adaptations in response to either the cessation of training or to a substantial decrement in the training load
Loss of muscle size, strength, and power
Decrease in muscular and cardiorespiratory endurance
Loss of speed, agility, and flexibility
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Loss of Muscle Strength With Detraining
Muscle atrophy accounts for a loss in development of maximal muscle fiber tension.
Normal fiber recruitment is disrupted; some fibers are unable to be recruited.
Muscle requires minimal stimulation (training once every 10 to 14 days) to retain training gains.
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BIOKINETIC SWIM BENCH AND STRENGTH CHANGES WITH DETRAINING
a b
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Loss of Muscular Endurance With Detraining
Decreased performance may be related to losses in cardiorespiratory endurance.
Oxidative enzyme activity in muscles decreases.
Glycolytic enzymes remain unchanged with up to 84 days of detraining.
Muscle glycogen content (and thus storage capacity) decreases.
Acid-base balance becomes disturbed.
Muscle capillary supply and fiber type may change.
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DETRAINING, VO2MAX, AND OXIDATIVE ENZYMES
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DETRAINING AND MUSCLE GLYCOGEN
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Blood Lactate, pH, and Bicarbonate (HCO3) in Eight Collegiate Swimmers Undergoing Detraining
–
Lactate (mmol/L) 4.2 6.3 6.8 9.7c
pH 7.259 7.237 7.236 7.183c
HCO3 (mmol/L) 21.1 19.5c 16.1c 16.3c
Swim time (s) 130.6 130.1 130.5 130.0
Measurement 0a 1b 2 4
Weeks of detraining
–
Note. Measurements were taken immediately after a fixed-pace swim.
aThe values at week 0 represent the measurements taken at the end of 5 months of training. bThe values for weeks 1, 2, and 4 are the results obtained after 1, 2, and 4 weeks of detraining, respectively. cSignificant difference from the value at the end of training.
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Loss of Cardiorespiratory Endurance
Losses are greatest in highly trained individuals.
Plasma volume decreases
Stroke volume decreases
Endurance performance decreases
VO2max decreases.
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Did You Know…?
You can prevent rapid losses to your cardiorespiratory endurance with a minimum of three training sessions per week at an intensity of at least 70% VO2max.
.
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CHANGES IN VO2MAX WITH BED REST.
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Effects of Detraining and Blood Volume Expansion
Blood volume (ml) 5,177 4,692b 5,412
Stroke volume (ml/beat)a 166 146b 164
VO2max (L/min) 4.42 4.16b 4.28
Exercise time to exhaustion (min) 9.13 8.44 8.06c
Parameter Trained Detrained Detrained
Normal Expanded blood blood
volume volume
aStroke volume measured during submaximal exercise. bDenotes a significant difference from the trained (normal blood volume) and detrained (expanded blood volume) values. cDenotes a significant difference from the trained (normal blood volume) value.
.
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Retraining
Recovery of conditioning after a period of inactivity.
Affected by fitness level and the length and extent of inactivity.
If a cast allows some range of movement, retraining time can be reduced.
Electrical stimulation of muscles can prevent muscle fiber atrophy.
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Key Points
Detraining is the cessation of regular physical training
Retraining is resuming training after a period of inactivity.
Detraining and Retraining
The greater the training gains achieved, the greater the losses with detraining.
Detraining results in losses of muscle size, strength, power, and endurance; speed, agility, and flexibility; and cardiorespiratory endurance.
Detraining effects can be minimized by training three times a week at 70% VO2max..